Islands and plants: preservation and understanding of lora on Mediterranean islands 1 Islands and plants: preservation and understanding of lora on Mediterranean islands 2 Islands and plants: preservation and understanding of lora on Mediterranean islands 2nd Botanical Conference in Menorca Proceedings and abstracts Islands and plants: preservation and understanding of lora on Mediterranean islands 3 Islands and plants: preservation and understanding of lora on Mediterranean islands 4 Islands and plants: preservation and understanding of lora on Mediterranean islands 2nd Botanical Conference in Menorca Proceedings and abstracts Islands and plants: preservation and understanding of lora on Mediterranean islands Eva Cardona Pons Irene Estaún Clarisó Mireia Comas Casademont Pere Fraga i Arguimbau (editors) Menorca, 2013 5 Islands and plants: preservation and understanding of lora on Mediterranean islands 2nd Botanical Conference in Menorca. Proceedings and abstracts. Islands and plants: preservation and understanding of lora on Mediterranean Islands / Eva Cardona Pons [et al.]. – Maó : Institut Menorquí d’Estudis : Consell Insular de Menorca, 2013. – 412 p. : il.; 24 cm. – (Recerca ; 20) I. Cardona Pons, Eva, ed. II. Estaún Clarisó, Irene, ed. III. Comas Casademont, Mireia, ed. IV.Fraga i Arguimbau, Pere, ed. V. Institut Menorquí d’Estudis. VI. Consell Insular de Menorca. 1. Botànica – Congressos 2. Flora – Mediterrània, Regió -- Congressos 582(262) Crèdits: © del text: els autors, 2013 © de les imatges: els autors, 2013 © de les il·lustracions: els autors, 2013 © de l’edició: Consell Insular de Menorca Portada: Paeonia cambessedesii (Wilk.) Wilk. Idea original: Modelgraic SL Disseny i maquetació: Modelgraic SL Assessorament lingüístic: Irene Cardona i Eva Cardona Edició: Consell Insular de Menorca. Plaça de la Biosfera, 5. 07703 Maó (Menorca) España. Institut Menorquí d’Estudis. Camí des Castell, 28. 07702 Maó (Menorca) España. Producció i impressió: Modelgraic SL. C/ Curniola, 48. 07714 Maó (Menorca) España. Dipòsit legal: ME 596-2013 ISBN 978-84-95718-95-2 Imprès en paper ecològic 6 Islands and plants: preservation and understanding of lora on Mediterranean islands THE SECOND BOTANICAL CONFERENCE IN MENORCA he 2nd Botanical Conference in Menorca was held in Es Mercadal from the 26th to the 30th of April 2011. Conferences sealed mainly with lora preservation on Mediterranean islands. Mediterranean basin, considered a biodiversity hot spot, shelters island systems to be highlighted for their biogeographical interest, as they constitute lands where features such as geographical isolation and special environmental conditions have fostered speciation processes and favoured the presence of many endemic taxa. In the Mediterranean scope, the islands share main threats and drawbacks related to lora preservation. herefore, we, the organisers of the Conference, are convinced that one of the best ways to widen our knowledge and improve initiatives of preservation is the exchange and learning of experiences and outcomes obtained in other regions with similar situations. Since 2009 the Island Council of Menorca has been developing the LIFE+ RENEIX project (http://lifereneix.cime.es), designed to recover areas on the island where lora is threatened. Given the relevance of several LIFE NATURA projects that have already devoted their eforts to the lora preservation, one of the points to be highlighted throughout this event is the networking scheduled in LIFE projects with similar goals, as well as the conception of future projects that can work together following the same line. Conference organisation: Island Council of Menorca (CIMe) Menorcan Institute of Studies (IME) University of the Balearic Islands (UIB) Organising Committee: Pere Fraga i Arguimbau (CIMe) Irene Estaún Clarisó (CIMe) Eva Cardona Pons (CIMe) David Carreras Martí (IME-OBSAM) Clemen Garcia Cruz (IME) Guillem Xavier Pons Buades (UIB) Scientiic committee: Dr. Jacques Blondel (C.N.R.S., France) Eva Cardona (CIMe - LIFE+RENEIX) David Carreras Martí (IME-OBSAM) Irene Estaún Clarisó (CIMe - LIFE+RENEIX) Pere Fraga i Arguimbau (IME, CIMe - LIFE+RENEIX) Òscar Garcia Febrero (IME) Dr. José María Iriondo Alegría (Rey Juan Carlos University) 7 Islands and plants: preservation and understanding of lora on Mediterranean islands Dr. Emili Laguna Lumbreras (Government of València) Cristòfol Mascaró Sintes (GOB Menorca, IME) Dr. Frédéric Médail (Paul Cézanne University - Aix-Marseille) Dr. Guillem Xavier Pons Buades (Balearic Islands University) Dr. Joan Rita Larrucea (Balearic Islands University) Dr. Josep Antoni Rosselló (València University) Miquel Truyol Olives (IME) Supporting bodies: Government of the Balearic Islands – Education, Culture and University Ministry City Council of Es Mercadal GOB Menorca Acknowledgements Organising and conducting a conference like this is not easy. In fact, apart from a lot of work, it needs a great deal of hopeful anticipation and disinterested devotion to a process that usually starts months or even years before the venue takes place. he driving force and spirit of the irst botanical conference (2006) have been the Botanical Commission members (GOB Menorca – IME), to whom we need to pay the irst acknowledgements: Cristòfol Mascaró Sintes, David Carreras Martí, Òscar Garcia Febrero, Xec Pallicer Allès, Martí Pons Gomila, Magda Seoane Barber and Miquel Truyol Olives. In particular, we also would like to show gratitude to the members of the Scientiic Committee at this conference and to all its presenters, speakers as well as the people in attendance. Most of the conference’s organisation and logistics could not have been possible without the excellent job done by the IME staf: Clemen García Cruz, Conchi Carreras Pons, Sonia Sintes Cucalón, Cristina Gomila Santa Maria and our beloved late Josep Miquel Vidal Hernández. Likewise we cannot leave out other people who generously helped in this project: Carme Garriga, Joan Juaneda, Guillem X. Pons, Ricardo Oliveira, Agnès Canals, Sònia Estradé, Maria González, Josep Guardia, Àlex Franquesa and Fina Salord. And last but not least, we also would like to thank the entities that in one way or another made all this possible: the IME (Menorcan Institute of Studies), the LIFE program of the European Commission, the UIB (University of the Balearic Islands), the Island Government of Menorca, GOB Menorca and the City Council of Es Mercadal. his conference could not have taken place without the full collaboration and contribution of all these people, especially the publication of the book, which you are now holding in your hands. 8 Islands and plants: preservation and understanding of lora on Mediterranean islands CONTENTS Foreword . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15 I Proceedings Josep A. Rosselló A perspective of plant microevolution in the Western Mediterranean islands as assessed by molecular markers . . . . . 21 Jacques Blondel Humans, landscapes and biodiversity in the Mediterranean region. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 37 Bertrand de Montmollin IUCN plant conservation programmes in the Mediterranean . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 51 Felipe Domínguez Lozano Plant conservation inventories, what we have now and what we need for the future . . . . . . . . . . . . . . . . . . . . . . 63 Llorenç Sáez, Pere Fraga & Javier López-Alvarado he lora of the Balearic Islands . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 91 Eva Moragues & Joan Mayol Managing threatened plants on islands: Tasks & priorities . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 105 Pere Fraga, Irene Estaún, Eva Cardona, Mireia Comas, Maria González & Carme Garriga LIFE+ RENEIX project . . . . . . . . . . . . . . 123 Angelino Carta, Gianni Bedini, Tommaso Guidi & Bruno Foggi Tuscan Archipelago lora: from genesis to conservation . . . . . . . . . . . . . . . . . . 157 Cristian Brullo, Salvatore Brullo & Gianpietro Giusso del Galdo Considerations on the endemic lora of Sicily . . . . . . . . . . . . . . . . . . . . . . . . . . . 177 Tommaso La Mantia & Salvatore Pasta Species richness, biogeographic and conservation interest of the vascular lora of the satellite islands of Sicily: patterns, driving forces and threats . . . . . . . . . 201 9 Islands and plants: preservation and understanding of lora on Mediterranean islands Maria Panitsa & Eleni Iliadou Flora and phytogeography of the Ionian islands (Greece) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 243 Sandro Lanfranco, Edwin Lanfranco, Rowina Westermeier, Mark-Anthony Zammit, Marie-Antoinette Mifsud & Joelene Xiberras he vascular lora of the Maltese Islands . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 261 Errol Véla Flora of Habibas Islands (N-W Algeria): richness, persistence and taxonomy . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 271 Henri Michaud Flora of the Hyères Islands highlights: originality and threats. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 289 Carlos Fabregat & Emili Laguna From ire to nature: evolution, restoration and conservation of the Columbretes Islands lora . . . . . . . . . . . . . 297 Joan Rita & Gabriel Bibiloni he lora of the islets of the Balearic Islands . . . 309 Frédéric Médail he unique nature of Mediterranean island loras and the future of plant conservation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 325 II Part: Abstracts Gerardo de Vicente Tectonic evolution of the Mediterranean during the Cenozoic . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 353 G. Bacchetta, G. Fenu & E. Mattana he exclusive vascular lora of Sardinia: update and conservation actions . . . . . . . . . . . . . . . . . . . . . . . . . . 354 Costas A. hanos & Christina Fournaraki Conservation and management of the lora and vegetation of Crete . . . . . . . . . . . . . . . . . . . . 355 Costas Kadis he lora of Cyprus: diversity, threats and conservation . . . . . . 357 Toni Nikolić Flora of the Adriatic islands . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 358 Pinelopi Delipetrou Aegean island lora and endemisms . . . . . . . . . . . . . . . . 359 10 Islands and plants: preservation and understanding of lora on Mediterranean islands Miriam Aixart & David Bertrán Balearic and Tyrrhenian lora at the Botanical Garden of Barcelona . . . . . . . . . . . . . . . . . . 361 Eva Cardona, Mireia Comas, Pere Fraga, Irene Estaún, Carme Garriga, M. Josepa González, Josep Guardia Environmental restoration activities in the SCIS of Binimel·là and ets Alocs within the LIFE+ Reneix project . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 362 Eva Cardona, Irene Estaún, Pere Fraga & Mireia Comas he LIFE+ Reneix project and social awareness about the preservation of biodiversity in Menorca . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 363 Mireia Comas, Pere Fraga, Eva Cardona, Irene Estaún, Carme Garriga, Josep Guàrdia, Maria González he recovery of the Pas d’en Revull under the LIFE+ Reneix project . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 364 Miquel Àngel, Maurici Mus & Josep A. Rosselló Leaf shape variation in two sympatric rupicolous species of Helichrysum (Asteraceae) from the Balearic Islands, assessed by geometric morphometry . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 365 Gianniantonio Domina & Francesco M. Raimondo he contribution of the E+M / PESI projects to the vascular lora of the Mediterranean islands . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 367 Gianniantonio Domina, Vivienne Spadaro, Giuseppe Bazan & Francesco M. Raimondo Endangered taxa of the Sicilian lora and conservation perspectives . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 368 M.C. Escribá, I. Ferrando, P.P. Ferrer, F. Albert, A. Navarro & E. Laguna Germination behaviour of ive threatened endemic plant species from Western Mediterranean islands and coastal clifs. . . . . . . . . . . . . 369 Irene Estaún, Eva Cardona, Mireia Comas, Carme Garriga & Pere Fraga Experiencies and results of the conservation of plant species through LIFE Nature projects in Menorca . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 370 11 Islands and plants: preservation and understanding of lora on Mediterranean islands Sònia Estradé, Rafel Quintana, Alexandre Franquesa, Pere Fraga, Eva Marsinyach, Catalina Pons & David Carreras Cartography of riparian vegetation and assessment of its ecological status in Menorca (Western Mediterranean, Spain) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 372 Iván Fernández, Samuel Pons, Pere Fraga, Cristòfol Mascaró, David Carreras, Òscar Garcia, Xec Pallicer, Martí Pons, Magda Seoane & Miquel Truyol he Herbarium Generale Minoricae . . . . . . . . . . . . . . . . . . . . . 374 Pere Fraga, Irene Estaún, Eva Cardona, Mireia Comas & Carmen Garriga Management of endangered plant species within the LIFE+ Reneix project . . 375 Pere Fraga & Josep A. Rosselló New plant species recently described in the lora of Menorca: the importance of neglected habitats . . . . . . . . . . . . . 376 Alexandre Franquesa, David Carreras, Agnès Canals & Miquel Truyol Forest habitat map of Menorca 2007. A tool for forest management and biodiversity preservation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 377 Lorenzo Gianguzzi, Dario Cusimano, Pasquale Cuttonaro & Vincenzo Ilardi. Endangered plant species of Marettimo island (Sicily, Italy) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 378 Lorenzo Gianguzzi, Dario Cusimano, Pasquale Cuttonaro & Salvatore Romano Investigations into the distribution of loristic emergencies of Pantelleria island (Channel of Sicily, Italy) . . . . . . . . . . . . . . . . 380 M. Guara, M.J. Ciurana, E. Laguna, A. Aguilella, F. Boisset, R. Currás, P.P. Ferrer, A. Marzo, J. Pedrola, M.F. Puche & I. Mateu-Andrés Phylogeography of Quercus coccifera s.l. in the Mediterranean basin . . . . . . 382 Vincenzo Ilardi, Dario Cusimano, Lorenzo Gianguzzi & Salvatore Romano In situ conservation strategies of a threatened species: the case of Carex panormitana Guss. in Sicily . . . . . . . . . . . . . . . . . . . . . . . . . . 383 12 Islands and plants: preservation and understanding of lora on Mediterranean islands Costas Kadis, Christina Pantazi, Takis Tsintides, Charalampos Christodoulou, Minas Papadopoulos, Costas A. hanos, Kyriacos Georghiou, Constantinos Kounnamas, Constantinos Constantinou, Marios Andreou & Nicolas-George Eliades Establishment of a plant micro-reserve network in Cyprus for the conservation of priority species and habitats . . . . . 385 Tamara Kirin, Marco Cosimo Simeone, Sandro Bogdanović & Bartolomeo Schirone Endemic taxa of Asperula L. Sect. Cynanchicae (D.C.) Boiss. on the Mediterranean islands . . . . . . . . . . . . . . . . 386 E. Laguna, D. Rivera, C. Obón & F. Alcaraz Wild Phoenix in the Mediterranean: paleontological and archaeobotanical evidence . . . . . . . . . . . 388 Miquel Mir-Gual & Guillem X. Pons Psammophyte vegetation on the dune front of Es Comú de Muro (Mallorca, Balearic Islands). From conservation status to the need for management . . . . . . . . . . . . . . . . . . . 389 Rafel Quintana, Sònia Estradé, Alexandre Franquesa & David Carreras Ecological quality of riparian habitat assessment by means of QBR index (Munné et al., 2003) in ephemeral streams of Menorca (Western Mediterranean, Spain) . . . . . . . . . . . . . . . . . . . . 391 Cristina Rosique, Albert Ferré, Jordi Carreras & Pere Fraga Detailed mapping of the distribution of the plant species of interest to the project LIFE+ Reneix in Menorca (Phase I) . . . . . . . . . . . . . . . . . . . . . . 393 Llorenç Sáez, Joan Rita, Gabriel Bibiloni, Cristina Roquet, Xavier Rotllan & Javier López Systematics of the narrow endemic species Brimeura duvigneaudii (Hyacinthaceae) . . . . . . . . . . . . . . . . . . . . . . . 394 Malvina Urbani he hymelaea tartonraira (L.) All. variation in Sardinia (Italy) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 395 L. Viegi, A. Tava, R. Cecotti & R. Vangelisti Essential oil composition of some Centaurea sp. (Asteraceae), from diferent Italian islands . . . . . . . . . 396 13 Islands and plants: preservation and understanding of lora on Mediterranean islands Attendants (Contact list) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 399 Author index . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 407 14 Islands and plants: preservation and understanding of lora on Mediterranean islands FOREWORD Two years ago the team lead by Pere Fraga organized the very successful meeting Islands & Plants: preservation and understanding of lora on Mediterranean islands (April 26-30, 2011), supported by the Consell Insular de Menorca, Institut Menorquí d’Estudis and Universitat de les Illes Balears and sponsored by a number of GO (from local to European) an NGOs. he hospitality and meeting possibilities ofered by the Minorcan team of botanists and institutions resulted in a number of interchanges, new projects and rich development of new ideas. But perhaps the major contribution of the Islands & Plants meeting has been a new and signiicant advance of scientiic knowledge on plant diversity as well as on modern and useful management and conservation tools in a 21st-century style: putting together, face to face (or side by side), scientiic researchers and managers to work in collaboration (this is not the current and expected style, at least not in the Mediterranean countries!). he result is shown in the current book as providential so as not to lose the consistent contributions presented by the participants. On the contrary, I am convinced that this book will be soon considered as a stepping stone in the study of islands’ biodiversity at international level. Among the main values of this volume, readers should note the truly wide coverage of geographic origin of authors, employed methodologies, institution proiles as well as scientiic and technical points of view. Biological diversity studied from truly human diversity open to debate (far from monolithic school and self-satisied meetings). his is also a merit of the organizing team to have obtained the participation of scientists of such excellence. he current state of knowledge of plant diversity of Mediterranean islands is summarized by contributing authors in the chapters of this book, but it is also, in part, the result of more than two centuries of botanical exploration. I am convinced that our predecessors deserve our sincere homage. Among tens of honorable names, let me personalize Pius Font Quer (1988-1964), an outstanding Catalan botanist who began his irst botanical expedition to Minorca in Spring 1911, exactly 100 years before the Minorca meeting in Es Mercadal (in Spring 2011), just now, when we commemorate the 50th anniversary of his death. Font Quer is considered the modern promoter of botanical exploration of the W. Mediterranean Islands (Menorca, Eivissa, Formentera and 15 Islands and plants: preservation and understanding of lora on Mediterranean islands surrounding islets, cf. Font Quer 1916, 1918 and many other contributions). He and his collaborators are authors of noticeable chorological indings and contributed greatly to the modern concepts of Balearic Biogeography, and laid the foundation for the future progress of botanical study of Mediterranean islands. But, as demonstrated by the participants, the botanical knowledge of these islands is far from complete: new species are still being discovered each year (both ater new extensive and intensive ield exploration and ater new experimental research), thus underlining the need to continue supporting plant research in the region. In addition to the intrinsic value of the island’s biodiversity, they constitute, as a whole, a precious and irreplaceable biological laboratory, where signiicant new contributions to science are to be expected. Diversity is also the physical characteristic of the territories studied, especially in size: thousands of islands, from the biggest (Sicily >25.000 km2) to the small islets (< 5 ha), but also diversity of the deep biological sense of what happened and is still happening in wildlife in the Mediterranean islands. One of the main ideas emerging from the introductory paper by Prof. J.A. Rosselló and from many of the collected scientiic contributions is the extremely complex combination of both biogeographic isolation and communication events, giving to islands and islets both the role of refuge and of passing corridor, depending on each one: particular biogeographic history, topography, geology, climate events, sea level luctuations, long distance dispersal, locally co-evolved mutualisms, microhabitat diversity or genetic mutations occurrence. Long episodes of colonizations/extinctions, introgressions favoring local populations against wide distribution ancestors, as well as local island extinctions due to invasions of foreign genotypes. Hybridization and new ploidy levels in progressive series but also in regressive reverse lines. All this very rich and complex network of ecological and genetic interactions has led to the present day’s ecological, phylogenetic, taxonomic, and genetic diversity of Mediterranean island plants, with a very high number of endemic species and subspecies which substantially contributed to the Mediterranean Hotspot of Biodiversity. But, as exposed in the paper by Prof. F. Médail, the future of the biotic originality of Mediterranean islands is now closely dependent on human population pressures. Centuries of human occupation modelled landscapes, plant communities and populations’ genetic structure and spatial distribution, mainly by traditional, slow-pace, building, agriculture and livestock pressures, resulting in balanced bio-diverse units, built and preserved at human size. 16 Islands and plants: preservation and understanding of lora on Mediterranean islands However, in the present a set of threats afecting Mediterranean islands plant diversity are repeatedly (and worryingly) reported, at increasingly fast rates. Several contributions of this book coincide with the identiication of disproportionate tourism and development-derived pressures (road and building construction, overpopulation, etc. ) as the main threat at present, irrespective of the political/administrative adscription of each island, whereas western, central or eastern Mediterranean, small islet or big island. Decline or loss of habitat quantity or quality is the main driver of increased fragility of our island’s lora as IUCN established criteria clearly stated. New research on Conservation Biology and commitment to reinforce Protection tools (in situ and ex situ) are urgently needed. hese threats are curiously widely shared by all the Mediterranean Islands and contribute to make them as a whole, also in this ield, a true unit. A set of fragile biological pearls constituting a precious and unique collar. But Mediterranean islands are, even more, an important ensemble of men and women, populations, cultures, languages, also the result of the fortunate combination of isolation and communication for centuries. In words of our poet and singer Miquel Martí i Pol and Lluís Llach, these islands (and by extension, Mediterranean countries) are united by “a bridge of blue sea” (“un pont de mar blava”) through which both plant and human diversity have been passing during millennia. Now it’s our turn to be engaged in their preservation for the next generations. Cesar Blanché Universitat de Barcelona Font Quer, P. 1916. Sobre la Clematis cirrhosa L. de Menorca. Butlletí de la Institució Catalana d’Història Natural, 16: 87-90 Font Quer, P. 1918. Exploració botànica d’Eivissa i Formentera. Butlletí de la Institució Catalana d’Història Natural, 18: 101 BioC-GReB, Equip de Recerca en Biologia de la Conservació de plantes de l’Institut de Recerca de la Biodiversitat (IRBio) de la Universitat de Barcelona. Laboratori de Botànica, Facultat de Farmàcia. Av. Joan XXIII s/n, E-08028, Catalonia. e-mail: cesarblanche@ub.edu 17 Islands and plants: preservation and understanding of lora on Mediterranean islands 18 I Proceedings Islands and plants: preservation and understanding of lora on Mediterranean islands 19 Islands and plants: preservation and understanding of lora on Mediterranean islands 20 Islands and plants: preservation and understanding of lora on Mediterranean islands A PERSPECTIVE OF PLANT MICROEVOLUTION IN THE WESTERN MEDITERRANEAN ISLANDS AS ASSESSED BY MOLECULAR MARKERS Josep A. Rosselló Jardí Botànic, Universitat de València, c/ Quart 80, E-46008, Valencia, Spain Marimurtra Bot. Garden, Carl Faust Fdn., PO Box 112, E-17300 Blanes, Catalonia, Spain. rossello@uv.es Abstract Insular systems provide a series of natural laboratories where general hypotheses on evolution, biogeography, ecology and conservation can be conceived and assessed. However, a general hypothesis exploring to what extent the diferent contrasts between continental and oceanic islands have let signiicant footprints at various levels of the molecular and genetic structure of phylogenetically related plant endemics remains to be assessed. In particular, there is a need to use model systems to undertake a comparative study of the genetic mechanisms underlying the processes that give rise to plant endemics in oceanic and continental islands. In the Mediterranean basin, the general prediction that island endemic plants oten have a reduced genetic variation relative to common, widely distributed species does not seem consistent with current results. At odds with expectations, particularly the Balearic Islands (and possibly continental islands in general), apparently contain a preserve of both nuclear and organellar genetic diversity, not only in the species widely distributed in the Mediterranean but also in narrowly distributed ones. On the whole, these results might be relecting complex evolutionary histories, in contrast to the hypotheses of insular colonization assuming demographic and genetic bottlenecks due to founder events, which are frequently suggested to explain the origin and evolution of many oceanic island plants. Keywords: continental islands, microevolution, genetic diversity, cpDNA, Balearic Islands BIOLOGICAL TYPES OF ISLANDS Even though islands represent only ca. 5% of the earth’s surface, they are considered one of the most important ecosystems of the world; indeed, they host a signiicant proportion of global biodiversity, amounting to between 21 A perspective of plant microevolution in the Western Mediterranean islands 1/6 and 1/4 of total vascular plant species known on earth (Suda et al., 2003; Kret et al., 2008; Kier et al., 2009). Furthermore, islands and archipelagos are outstanding biological systems because many of the species they harbour have narrow distributions and high endemicity levels (Whittaker and FernándezPalacios, 2007). Vascular plant endemic richness has been inferred to be ca. 9.5 times higher on islands than on mainland areas (Kier et al., 2009), and 20 of the 34 biodiversity hotspots deined by Myers et al. (2000) [and updates in http://www.biodiversityhotspots.org] are islands or have a remarkable insular component. Far from being a by-product of only stochastic events, the special features of insular biodiversity apportionment are largely a consequence of the twofold evolutionary role undertaken by non-exclusive processes favouring that some islands have become both (i) refugia (fostering the accumulation of paleoendemics) and (ii) active speciation grounds (triggering the generation of neoendemics). As discrete, internally quantiiable, numerous, and biologically very diverse geographical units, insular systems constitute a series of natural laboratories where hypotheses of general importance in evolution, biogeography, ecology and conservation can be developed, and corroborated or falsiied. All these research areas have beneited from the application of molecular markers to (i) circumscribe the origins of the ancestors of insular organisms, (ii) estimate the minimum number of colonisations required, (iii) infer both the inter-insular post-colonizing dispersal patterns, and the withinisland evolution/dispersal dynamics, and (iv) identify back-colonisations of the mainland from insular propagules (for instance, among many other references, Baldwin et al., 1990; Sang et al., 1994; Sheely & Meagher, 1996; Kim et al., 1996; Stuessy & Ono, 1998). However, various important aspects on evolutionary biology related to patterns and processes of plant divergence and micro-speciation on islands (see below) have not been addressed previously within a comparative and conceptually unifying framework including study cases from both oceanic and continental islands. he contrasts between diferentiation and evolutionary processes in both island types is of paramount importance to ind out whether the evolutionary paradigms that have usually been derived from oceanic island organisms (though also applied to continental islands) have followed similar paths or, on the contrary, there are diferential components contingent upon the biological type of the considered island or archipelago. he diferent geological origins of islands have important biological consequences. For instance, continental islands derive from the tectonic 22 Islands and plants: preservation and understanding of lora on Mediterranean islands fragmentation of continental plates; therefore, they present a subset of the lora that already existed when the separation took place, whereas the component derived from long distance dispersal is not known. By contrast, oceanic islands are the product of volcanic activity; originally devoid of life, they become populated by long-distance dispersal through oceanic barriers (Stuessy, 2007; Whittaker & Fernández-Palacios, 2007; Grant, 1998; Crawford & Stuessy, 1997). Traditionally, continental islands have been considered living museums, where the remnants of ancestral loristic elements that represent the autochthonous lora of the mainland to which they were once attached have thrived. By contrast, oceanic islands are viewed as paradigmatic centres of origin of new biodiversity, as they ofer a high abundance of niches available for colonization ater their emergence (Losos & Ricklefs, 2009; Mansion et al., 2008; Whittaker et al., 2008; Whittaker & Fernández-Palacios, 2007). CONTINENTAL ISLANDS They have been attached to the continents at some past stage of their genesis. In the Western Mediterranean, most major islands have not had contact with the mainland since the end of the Messinian (5.3 Ma) Marine transgressions and regressions have largely conditioned the geographic distribution of biodiversity. They are less rugged geographically, and therefore we might expect a higher inter-population genetic cohesion Their biota are taxonomically harmonic Low ratio of species per genus Adaptive radiation processes are linked to active speciation processes. Adaptive radiation has not been compellingly documented as a phenomenon linked to insular speciation Derived woody endemic taxa are only anecdotal OCEANIC ISLANDS They have always been islands. Volcanic activity can dramatically and suddenly shift the distribution ranges of organisms, and/or provoke their extinction. They have rugged geographic features modelled by volcanism that may represent important barriers to gene flow. Their biota are taxonomically disharmonic High ratio of species per genus Adaptive radiation processes are linked to active speciation processes. High proportion of woody endemic taxa whose closest mainland congeners are predominantly herbaceous Table 1. Basic diferential characteristics between the two fundamental types of islands. 23 A perspective of plant microevolution in the Western Mediterranean islands CONTINENTAL ISLANDS IN THE WESTERN MEDITERRANEAN he Balearic Islands, Corsica and Sardinia are the largest islands in the western Mediterranean basin, and they have been classiied within the ten most biodiverse Mediterranean islands (Médail & Quézel, 1997), featuring ca. 5000 species of vascular plants that include some 360 endemics (Contandriopoulos, 1990; Mariotti, 1990; Alomar et al., 1997). Especially in the Mediterranean basin, where roughly half of the native species are endemics (Médail & Quézel, 1997; hompson, 1999), endemic plants are paramount to resolve the origins and evolution of the regional loras (Major, 1988). A high proportion of Mediterranean endemic plants occur on islands; consequently, these ecosystems play a central role on the research about spatio-temporal biodiversity dynamics in the region. Because of their high diversity, loristic and biogeographic studies abound for the Balearic- Corsican-Sardinian lora, and they have revealed loristic links with nearby mainland areas like the Pyrenees, the Alps, Provence, Liguria, Calabria-Sicily, and North Africa (Contandriopoulos, 1962; Contandriopoulos & Cardona, 1984; Mus, 1992). Mediterranean palaeogeography reveals that the current position and extension of the Balearic, Corsican and Sardinian archipelagos has undergone dramatic changes throughout their tectonic evolution. Nevertheless, the most salient features of the geological history of these territories are well-known and, therefore, they can ofer a temporal reference for framing any evolutionary study in the Western Mediterranean. Compelling evidence exists that microplates have played a fundamental role in the tectonic evolution of the Western Mediterranean, and that Corsica and Sardinia (along with other minor fragments of continental origin), shaped the core of the largest microplate in the region (Robertson & Grasso, 1995). In the late Oligocene (between 30 and 25 Mya) the Corsican-SardinianMinorcan microplate began to detach from the South of France and the NE of the Iberian Peninsula to drit eastwards ca. 30° counter clockwise, reaching its current position some 18-16 Mya (Speranza et al., 2002). During this period, the Minorcan part of the plate came into contact with the other Balearic territories (which were at the time linked to continental landmasses of the area that currently makes up the Iberian Peninsula), detaching itself from the main Corsican-Sardinian block. In the Messinian (ca. 5.96-5.33 Mya), and throughout the subsequent glacial maximal in the Pleistocene, the CorsicanSardinian archipelago was linked to the western part of the Italian Peninsula (Toscana), whilst the Balearic Islands were connected among them (Hsü et al., 24 Islands and plants: preservation and understanding of lora on Mediterranean islands 1977; Bocquet et al., 1978, Contandriopoulos, 1981, 1990; Contandriopoulos & Cardona, 1984; Robertson & Grasso, 1995). MICROEVOLUTION OF WESTERN MEDITERRANEAN INSULAR ENDEMICS he general patterns that might explain microevolutionary processes underlying plant endemization on Western Mediterranean islands have not been explored until now. Such absence of data is most surprising in an enclave where the endemicity rate on major islands far outnumbers a minimum of 10%. Only recently, a critical review about caryological evolution on the Balearic endemic component has been tackled (Rosselló & Castro, 2008), revealing that (1) the origin of the islands (continental or oceanic) is not an accurate predictor of the proportion of polyploid component in the lora, (2) there are no apparent unifying processes that explain the evolution of ploidy levels on insular endemics, and (3) the levels of autochthonous polyploidy (i.e., developed in situ) on continental islands are higher than on oceanic islands, where the percentage of polyploidy evolution on insularity conditions is comparatively low (Stuessy & Crawford, 1988). Nevertheless, other important caryotypic aspects that might be linked to the patterns and processes of insular endemization have not been analyzed as of now. On the one hand, the examination of nuclear DNA contents (1C values) in Macaronesian endemics revealed a narrow variation range (Suda et al., 2003; Suda et al., 2005), with most sampled endemics featuring very low nuclear DNA contents (under 1.40 pg), with no endemic species found to have a high 1C value (i.e., above 14.01 pg). hese results have motivated the hypothesis that genome miniaturization may carry an evolutionary advantage under the selective pressure conditions that prevail on oceanic insular systems (Suda et al., 2005). In fact, Suda et al. (2003) and Suda et al. (2005) propose that rapid speciation episodes linked to adaptive radiation are much more likely on angiosperms with minimal nuclear DNA contents. It is not known to what extent similar selective pressures have acted on the endemic component of continental islands, and its comparison with the Macaronesian endemic element eventually would allow us to establish unifying statements bearing on the general abundance of species with small genomes on insular systems. On the other hand, there is a glaring void of data on the eventual relationship of insular speciation and diferentiation with changes in deep genomic levels (i.e., in the composition and structure of repeated DNA). Among the sequences of highly repeated DNA in the eukaryotic genome, the most important ones are (i) 25 A perspective of plant microevolution in the Western Mediterranean islands tandem-repeated DNA (aka satellite DNA), and (ii) dispersedly-repeated DNA, encompassing a variety of mobile genetic elements and sequences derived from retro-transposition. hese two types of sequences are arranged in tandem on coincident regions with heterochromatin, especially in centromeric and subtelomeric zones (Ugarkovic & Plohl, 2002). Satellite DNA is characterized by an unusual and non-uniform evolution, tuned by rapid evolutionary changes and concerted evolution mechanisms among closely related species that give rise to a high within-species molecular homogeneity (Pons & Gillespie, 2004). As a result, there is great intra-population homogeneity for population-speciic mutations, but a considerable inter-population diferentiation (on the whole, mutations occur at a rate far lower than their difusion rate within the genome/ population, thereby fostering a relatively fast replacement of variants within a given satellite DNA family in a population; Ugarkovic & Plohl, 2002). Satellite DNA studies in oceanic island animals from diferent phyla have revealed the utility of this technique to characterize adaptive radiation and diversiication processes on oceanic islands (Pons et al., 2002; Pons & Gillespie, 2003; Pons & Gillespie, 2004). However, despite the fact that the evolutionary patterns of satellite DNA have been analyzed in angiosperms from complex evolutionary landscapes (but only in continents; cf. Suárez-Santiago et al., 2007), there is no previous study associating the genomic dynamics of this DNA with speciation and diversiication phenomena on insularity conditions. Furthermore, the applications of molecular techniques to the study of the evolution of insular organisms in the Mediterranean region are relatively meagre, even though island ecosystems have a recognized importance for the general diversity contents of the area. he numerous Mediterranean islands make up one of the most important centres of plant diversity in this area, with a high proportion of endemicity and being genetically isolated (Médail & Quézel, 1997; Médail & Diadema, 2009). he proportion of endemics on the major islands (the Balearic Archipelago, Sardinia, Cyprus, Corsica, Crete, Sicily) ranges between 10-12% (Médail, 2008); consequently, these ecosystems should have a central importance in the research of the space-time dynamics of this region’s biodiversity. However, molecular studies focused on plant species from Mediterranean islands are relatively scarce, though they have experienced an upward surge recently (Hurtrez-Boussès, 1996; Afre & hompson, 1997; Afre et al., 1997; Sales et al., 2001; Widén et al., 2002; Bittkau & Comes, 2005; López de Heredia et al., 2005; Edh et al., 2007; Mansion et al., 2008; Salvo et al., 2008; Falchi et al., 2009; Rosselló et al., 2009).he few currently available studies suggest that plant endemics from Mediterranean islands (1) have conspicuous 26 Islands and plants: preservation and understanding of lora on Mediterranean islands genetic diversity levels, which are also highly structured (Afre & hompson, 1997; Bittkau & Comes, 2005; López de Heredia et al., 2005; Edh et al., 2007; Falchi et al., 2009), indicating that (2) gene low is scarce, even within species with a high dispersal capacity, thereby highlighting a predominant role of drit on the observed diversity patterns (Widén et al., 2002; Bittkau & Comes, 2005; Edh et al., 2007). Wolfe et al. (1987) contend that the variation rates in the chloroplast genome are signiicantly lower than those in nuclear DNA, thereby providing polymorphism levels inadequate for micro-evolutionary intra-speciic studies in stenochorous taxa. However, the results so far available suggest otherwise, and highlight the scarce general applicability of that contention. Hence, in our study of the narrowly distributed Balearic endemic Senecio rodriguezii (Molins et al., 2009) we detected seven haplotypes, a similar number to that found in congeners like S. halleri (seven; Bettin et al., 2007) and S. leucanthemifolius var. casablancae (ive; Coleman & Abbott, 2003) or in related species widely distributed throughout the Mediterranean basin, such as S. gallicus, S. glaucus, and S. leucanthemifolius (ive; Comes & Abbott, 1999). Analogously, the results obtained in the Balearic-Corsican-Sardinian endemic hymus herba-barona (Molins et al., 2011) also indicate remarkably high genetic diversity levels, either at the species or population-level. he number of cpDNA haplotypes detected (17) is similar to those found in species widely distributed in the Mediterranean, like Cistus creticus in Corsica and Sardinia (16 haplotypes; Falchi et al., 2009). herefore, the general prediction that island endemic plants oten have a reduced genetic variation relative to common, widely distributed species (Frankham, 1997) does not seem consistent in the light of our results. In addition, similar results of cpDNA genetic diversity have been obtained in other species whose distribution is conined to the Western Balearic islands (Molins, Mayol & Rosselló, unpubl. data), and in other species from continental islands (Taiwan; Chiang and Schaal, 2006; and references therein). At odds with expectations, particularly the Balearic Islands (and possibly continental islands in general), apparently contain a preserve of both nuclear and organellar genetic diversity, not only in the species widely distributed in the Mediterranean (Quercus sp. pl.; Lopez de Heredia et al., 2005), but also in narrowly distributed ones (our results, and also Sales et al., 2001). On the whole, these results might be relecting complex evolutionary histories, in contrast to the hypotheses of insular colonization assuming demographic and genetic bottlenecks due to founder events, which are frequently suggested to explain the origin and evolution of many oceanic island plants. 27 A perspective of plant microevolution in the Western Mediterranean islands hese previous results coincide with expectations for populations of species in southern glacial refugia, where prolonged isolation in a scenario of small enclaves adequate for survival would have brought about low levels of interpopulation gene low (Hewitt, 2001; Petit et al., 2003; Hampe & Petit, 2005; hompson, 2005), thereby giving rise to exceptionally high levels of genetic diversity at the regional level. Signiicant genetic structuring has been reported for other Mediterranean island endemics, such as Brassica cretica (Fst =0.628 and 1.000; nuclear and chloroplastic microsatellites, respectively; Edh et al., 2007), Brassica insularis (Gst=0.107; allozymes; Hurtrez-Boussès, 1996), Cyclamen creticum (Gst=0.170; allozymes; Afre & hompson, 1997), the Nigella arvensis complex (Fst=0.814; cpDNA; Bittkau & Comes, 2005), or Centaurea horrida (Rst=0.158; nuclear microsatellites; Mameli et al., 2008). heoretical predictions suggest that signiicant population divergence should be expected in species with isolated populations and restricted dispersal capacity, as these features lead to reduced inter-population gene low, thereby fostering a predominance of drit. Indeed, diverse empirical studies on insular species from the Aegean do suggest that genetic drit would be one of the main evolutionary forces to explain the high plant diversity in this area (Widén et al., 2002; Bittkau & Comes, 2005; Edh et al., 2007). Our results are consistent with this hypothesis, as the genetic diferentiation values are signiicantly high, indicating the absence of overall genetic diversity patterns and structuring at the considered scale. Besides, many of the haplotypes found were restricted to a single population or a narrow geographical area, suggesting low (if any) gene low levels, even at an extremely local scale. On the whole, the levels of variability and diferentiation detected bolster the overlap of diverse historical events (both more and less recent) is conducive to a progressive fragmentation of the distribution areas of insular species, in some cases since the Oligocene (some 25-30 Mya). 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Proceedings of the National Academy of Sciences USA, 84: 9054-9058. 34 1: General aspects Islands and plants: preservation and understanding of lora on Mediterranean islands 35 Humans, landscapes and biodiversity in the Mediterranean region 36 Islands and plants: preservation and understanding of lora on Mediterranean islands HUMANS, LANDSCAPES AND BIODIVERSITY IN THE MEDITERRANEAN REGION Jacques Blondel Centre d’Ecologie Fonctionnelle & Evolutive - Centre National de la Recherche Scientiique, 34293 Montpellier cedex 5, France. jacques.blondel@cefe.cnrs.fr INTRODUCTION he French historicist Fernand Braudel wrote: “What is the Mediterranean? One thousand things at a time. Not just one landscape but innumerable landscapes. Not just one sea, but a succession of seas. Not just one civilization, but many civilizations stacked on top of one another. he Mediterranean is a very old crossroads. For millennia, everything has converged upon it” (Braudel, 1985). his quotation explains why deciphering the relationships between humans and landscapes is altogether a diicult and fascinating endeavor due to the fact that the Mediterranean Basin has always been a crossroads for not only human societies, but also for wildlife, which makes it exceptionally rich and diverse (Blondel, 2006; Blondel et al., 2010). he long human history in the Mediterranean resulted in a mosaic of cultural landscapes, each of which added or superimposed its biological and cultural characteristics to the efects of previous ones. hese societies have impacted biota and ecosystems everywhere in the basin for so long that it has been occasionally claimed that some kind of ‘coevolution’ has shaped the interactions between these ecosystems and humans (di Castri, 1981). If human impact has, on average, been far from beneicial to biodiversity, at times it resulted in a signiicant improvement of biological diversity at various scales from populations to landscapes. THE ESTABLISHMENT OF TRADITIONAL LAND USE SYSTEMS: WHAT EFFECTS ARE HAD ON BIODIVERSITY? he irst prerequisite for humans to establish themselves as sustainable populations is to manage a friendly living space. To do so, innumerable systems have been devised everywhere in the basin for capturing and managing resources. Some of the systems which had the most prominent efects on ecosystems include forest management (wood-cutting and coppicing, charcoal processing), controlled burning, plant and animal domestication, livestock husbandry, water management and terracing. Wood cutting and the use of ire have been among the most important forces shaping Mediterranean landscapes over the course of the last ten millennia. Fires have always been a key disturbance 37 Humans, landscapes and biodiversity in the Mediterranean region event in the Mediterranean (Naveh, 1974; Dubar et al., 1995) but rural peoples carefully attended to and controlled them so that they greatly contributed to the maintenance of a high turnover of habitats and their associated plant and animal communities and ecosystems (Vazquez et al., 2006). he struggle for water has been a vital theme in the history of all Mediterranean peoples, and ingenious systems for collecting and storing rainwater went unchanged for millennia. A great many of them, some dating back to at least the Chalcolithic period 4,500 to 5,000 years ago, were designed to carry water diverted from loods to ill city and farm reservoirs and for irrigating cultivated ields. Terracing is among the most widespread and sometimes spectacular achievements of rural societies. his has always been a time-consuming and tedious but necessary activity in the mountainous areas of the Mediterranean Basin. Cultivated terraces were both a means of ighting erosion and water-saving devices for preventing run-of. Hand-built stone terraces permitted cultivation on slopes that ranged in inclination from 20–75% (Lepart & Debussche, 1992). Until the early twentieth century, terrace cultivation remained a hallmark that indelibly shaped Mediterranean landscapes, from mountainsides to valley bottoms. On these terraces, a wide range of legumes were cultivated, along with several Mediterranean trees such as olive trees and carob trees which were once planted extensively as a forage and fodder tree in association with various sylvo-pastoral systems. he nature and intensity of landscape design by peoples of the Mediterranean Basin varied considerably from one region to the next, and from one historical period to the next, particularly with demographic and socioeconomic conditions, so that any generalization is quite diicult. Landscape management resulted in the shaping of agro-sylvo-pastoral cultural landscapes among which the two most well-known are the Sylva-saltus-ager triad and the dehesamontado system in the Iberian peninsula and some Mediterranean islands. In the dehesa (in Spain) and montado (in Portugal) systems, as well as in similar systems called Pascolo arbolato practiced in Sardinia and other Mediterranean islands, many of the same basic advantages were provided, but the systems difered in the spatial organization of three main activities—cultivation, grazing, and harvesting of forest products. he design of the two systems resulted in a quite diferent distribution of habitat patches within landscapes: he Sylva-saltus-ager triad typically produced coarse-grained patchwork with clear-cut habitat patches, whereas a ine-grained patchwork was produced by the dehesa-montado system with diferent consequences to the distribution of various components of biological diversity (see Blondel et al., 2010). 38 Islands and plants: preservation and understanding of lora on Mediterranean islands Besides but in association with landscape management, the domestication of plant and animal species had many consequences on biological diversity. Domestication began about 10,000 years ago in the eastern part of the Mediterranean Basin and around two millennia later in the western part. he Mediterranean plant world linked to agricultural practices was divided by Zohary (1973) into two parts, the ‘segetal’ (anthropogenic) and the ‘nonsegetal’ (“primary plants”). With many plant species that were domesticated, adaptive intraspeciic variation occurred over millennia as a response to human-induced selection and with habitat changes. his process resulted in the diferentiation of many local ecotypes with region-speciic characters. A great variety of plant ecotypes have been selected over the centuries. Examples include hundreds of varieties of olive, almond, wheat, and grape, which have been selected intensively by humans. All these varieties have also added to the biological diversity of the Mediterranean. As argued by Diamond (2002), human inluence on populations undoubtedly constituted a signiicant selective factor in their evolution through the process of domestication. For example, the olive tree, the most emblematic plant species across Mediterranean cultures, currently constitutes a complex of many wild forms (Olea oleaster), as well as weedy types and many cultivars classiied as O. europaea var. europaea (Terral et al., 2004). Today, more than 600 local cultivars of the olive tree occur in the basin (Breton et al., 2006). he remarkable combination of protein-rich pulses and cereals that were domesticated in Neolithic farming villages of the Fertile Crescent in the Near East, along with domesticated sheep, goats, cattle and pigs, have certainly facilitated the rapid spread of herding and farming economies (Diamond & Bellwood, 2003). Races of wild cattle have been domesticated from Pleistocene aurochs (Bos primigenius) since more than 6,000 years ago (Pfefer, 1973). Other domesticated mammals of importance were horses (Equus ferus/caballus) and donkeys, although the domesticated animals of paramount importance for Mediterranean peoples, and which have had the most widespread impact on Mediterranean ecosystems through grazing and browsing, are sheep and goats. On the whole, a large number of gene pools have been selected in domesticated animals over millennia by traditional pastoralists, with region-speciic characteristics that adapted them to local environmental conditions. he longterm human-induced selection processes have resulted in the development of more than 145 varieties of domesticated bovids and 49 varieties of sheep (Georgoudis, 1995). 39 Humans, landscapes and biodiversity in the Mediterranean region HUMAN-RELATED UPS AND DOWNS IN BIODIVERSITY It would be out of the scope of this chapter to describe in detail the historical rise and fall in biodiversity on the scale of the Mediterranean Basin (see. e.g. Blondel & Médail, 2007) but some trends are worth mentioning. Two contrasting theories, one pessimistic and the other optimistic, have been proposed to interpret the relationships between humans and ecosystems in the Mediterranean Basin. he ‘Ruined Landscape’ or ‘Lost Eden theory,’ argues that human-caused deforestation and overgrazing resulted in an endless degradation and desertiication of Mediterranean landscapes and their associated wildlife. Advocates of this theory (e.g. Attenborough, 1987; McNeil, 1992; Naveh & Dan, 1973; hirgood, 1981) argue that ten millennia or so of forest destruction and resource depletion best explain the interaction of humans and Mediterranean forests. A second school of thought challenges this view and argues that an imaginary past does not acknowledge real human contribution to the maintenance, diversity, and even the improvement of Mediterranean landscapes since the last glacial period (e.g. Grove & Rackham, 2001). here is certainly some truth in these two viewpoints, but the point of interest is trying to investigate how Mediterranean systems responded to human-induced disturbance events and what their patterns of resilience might be, understood as the amount of time required for a total recovery of the system following a disturbance event. he problem is to understand how living systems have accommodated both the intrinsic variability of Mediterranean bioclimates and the long-term inluences of human activity. he continuous redesign of landscapes and habitats has had profound consequences on the distribution, dynamics, and turnover of species and communities. Diversity losses in the distant past Human impact has exerted sustained direct efects on Mediterranean ecosystems for a very long time, possibly as many as 50,000 years ago or so. he irst signiicant impact of humans, well before the Neolithic revolution and the establishment of permanent settlements, was their probable role in the extinction of a number of large mammals at the end of glacial times, including on islands. Indeed, the number of large mammals that occurred in most of Western Europe dropped from 37 species to 18 between the late Pleistocene and the present (Petit-Maire & Vrielynck, 2005). Even if the overkill hypothesis suggested by Martin (1984) to explain the sudden disappearance of so many species of large mammals in the Northern Hemisphere at the end of the Pleistocene is still in debate (e.g., Owen-Smith, 1987; Brook & Bowman, 2004), 40 Islands and plants: preservation and understanding of lora on Mediterranean islands there is much evidence of the direct responsibility of humans in the extinction of the ‘megafauna’ of Mediterranean islands (e.g. Alcover et al., 1981). hese insular mammal faunas, which included strange mammal assemblages with dwarf hippos and elephants the size of pigs, as well as many endemic species, were doomed to extinction in the course of the past millennia as a result of direct and indirect human impact. One well documented example is that of Myotragus in Menorca (Bover, & Alcover, 2003). A true ‘revolution’ in the relationships between humans and biodiversity began about 10,000 years ago, when hunters in the Near and Middle East began to produce their own food supply, thus laying the foundations for the domestication of plants and animals (Vavilov, 1992; Zeder, 2008). hen human pressure became more and more severe, resulting in massive forest destruction, as demonstrated by many palaeobotanical, archaeological, and historical records. Quézel & Médail (2003) estimated that no more than 15% of the ‘potential’ Mediterranean forest vegetation remains today. Indeed, pollen diagrams show that large-scale Neolithic deforestation in many parts of the Mediterranean basin coincided with the steady expansion of grain culture as a result of human demographic expansion (Triat-Laval, 1979). hen, from the middle ages and until the end of the eighteenth century, the deciduous downy oak (Quercus humilis) and the evergreen holm oak (Q. ilex) were intensively used to make charcoal for glassworks and metallurgy. Since the Iron Age, charcoal has been the main source of energy in the Mediterranean area, as testiied by the great abundance of ancient charcoal production sites, up to 40 sites per hectare, that are still visible in many woodlands. Human-related variation of biodiversity in historical times All habitats and landscapes in the Mediterranean region, except some remote mountainous and steep clif areas, have been to various extent managed and transformed by humans. Although some of these tremendous changes have sometimes had beneicial consequences on biodiversity as already mentioned, most of them have resulted in serious threats and decline of biological diversity. Forests, wetlands, and coastal habitats together with their associated wildlife have been and continue to be most afected by human impact. Changes of anthropogenic origin have had many impacts on the distribution and abundance of populations, making a large number of them decline while some others are in fact increasing. However, for many plants, some groups of vertebrates, 41 Humans, landscapes and biodiversity in the Mediterranean region and most groups of invertebrates, micro-organisms and fungi, there is much uncertainty regarding their status. It is very diicult to have a precise idea of the number of plants that are threatened in the Mediterranean but some trends are quite obvious. For example, in countries of the southern shores of the sea there is still a process of ongoing degradation with as much as 25% of the lora being considered as threatened. he unique lora of Mediterranean islands is on the whole seriously threatened, especially the endemic species: on large islands, the percentage of taxa that are threatened ranges from 2% in Corsica to 11% in Crete (Delanoë et al., 1996). Many other examples of decline of biodiversity could be cited (see e.g., Blondel & Médail, 2009). Ater the mass extinction of the large mammal megafauna at the end of glacial times discussed above, the combination of habitat changes and direct persecution has doomed to extinction many other species of large mammals, especially in North Africa. Freshwater ish are perhaps the most interesting group of Mediterranean vertebrates, but also one of the less known and the most threatened with more than 500 species, 50% of them being endemic. As much as 40% of all ish species and 60% of the endemic species in the Mediterranean are vulnerable to extinction and at least eleven of them are already extinct (Smith & Darwall, 2006). Most threats stem from the degradation of water, both in quality (pollution, eutrophication), and quantity (huge amounts of freshwater are pumped for domestic use and irrigation). Reptiles and amphibians have not sufered serious extinction events in recent times but most populations of amphibians and many populations of reptiles are declining everywhere in the Mediterranean. For birds, the main problem is not so much extinction per se, but many changes in the composition and structure of bird assemblages. Many species that were formerly widespread everywhere in the basin are now limited to small, localized populations, many of them threatened, mostly as a consequence of habitat loss, pollution, and decrease of genetic diversity. For example, most large insectivorous birds such as the lesser kestrel and most species of shrikes are strongly declining as a result of food shortage resulting from intensiication of agriculture and urban sprawl. However, for many groups of Mediterranean plants and animals, the main consequences of human-induced large scale deforestation, wetland drainage and traditional landscape design and management have not been so much a decrease in overall species richness at a regional scale as in creating a tremendous 42 Islands and plants: preservation and understanding of lora on Mediterranean islands proportional advantage for species adapted to open habitats, drylands and shrublands at the expense of forest dwelling species (Blondel et al. 2010). he current trends of habitat changes as a result of human impact vary markedly across the regions of the basin (Mazzoleni et al., 2004). On the northern bank of the sea, the ongoing collapse of most traditional land-use systems and rural depopulation completely destructured traditional cultural landscapes as they were replaced by industrial-style agriculture and modern activities such as mass tourism. hese changes have had many consequences on several components of biodiversity at the landscape scale (Blondel & Médail, 2007). In contrast, in North Africa and most of the eastern part of the Mediterranean, pressures on natural habitats by humans and livestock are still strongly on the increase, destroying soils and ecosystems and resulting in intense erosion. he impact of on-going woodland clearance, followed by overgrazing in these countries results in high rates of soil erosion and in an increasing clearing of arid steppe rangeland, which is a major cause of desertiication in North Africa and the Near East. On the other hand, changes in the distribution of species and local extinction events were partly compensated for by intraspeciic and interspeciic adaptive diferentiation in response to human induced habitat changes (Zohary & Feinbrun, 1966-86). WHY AND HOW ARE MEDITERRANEAN ECOSYSTEMS RESISTANT TO DISTURBANCE AND RESILIENT? Variation in biodiversity in relation to human societies is not necessarily synonymous with degradation. here is some evidence, including comments by Roman writers such as Polinus and Virgilus, that landscape management has oten been achieved using empirical knowledge and observation with the intent of making it more resistant and resilient to human-induced disturbance events. Wise management of ields for sustainable services was maintained through a variety of cultural institutions, as indicated by Roman authors, who repeatedly mentioned the need for regular fertilization through application of wood ash, animal manure, or green manure to ields (Dupouey et al., 2002). he ine balance achieved by humans among woodlots, pastoral grasslands, scrublands, and open spaces reserved for cultivation resulted in a mosaic that greatly contributed to the biological diversity of Mediterranean landscapes. Grazing, even heavy grazing, is not necessarily a monolithic threat 43 Humans, landscapes and biodiversity in the Mediterranean region to biodiversity in Mediterranean habitats. he high degree of resilience of Mediterranean matorral shrublands, especially in the presence of a balanced load of grazers and browsers, domesticated or wild, can result in a dynamic coexistence of living systems that are characterized by stability, diversity, and productivity (Etienne et al., 1989). For example, comparing two small islands of the large island of Crete, one heavily grazed by the Cretan wild goat (Capra aegagrus cretica) and the other ungrazed, Papageorgiou (1979) demonstrated that plant species diversity was much higher in the former than in the latter. Other experiments have shown that population densities of gazelles in Israel with ca. 15 individuals/km² not only allowed for optimal harvesting of animals each year but also resulted in a signiicant increase in plant species diversity of the grazed rangelands (Kaplan, 1992). he main conclusion of these studies is that moderate grazing intensity has the potential to maximize species diversity and optimize ecosystem productivity. Seligman and Perevolotsky (1994) obtained similar results in their review of both sheep and cattle grazing systems in the eastern Mediterranean, where pastures have been grazed by domestic ruminants continuously for more than 5,000 years. What are the mechanisms underlying the surprisingly high resilience and resistance of Mediterranean ecosystems to long-lasting human pressure? Is it possible to demonstrate some kind of “coevolution” between humans and natural systems that could result in sustainable ecosystem function and a balance between extinction and immigration or diferentiation of biota? It has been suggested that the high resistance of Mediterranean ecosystems to invaders and their resilience ater disturbance could be a result of the long history of close interactions between humans and ecosystems (Blondel et al., 2010; di Castri, 1990; hompson, 2005). Indeed, this situation contrasts sharply with those of most other regions in the world, including the other Mediterraneantype ecosystems of California, Chile, South Africa and Australia. One possible explanation for this property of Mediterranean ecosystems is that they have already been subjected to continuous disturbance of luctuating regimes and intensity over many millennia. housands of spontaneous colonization events may have made the ecosystems of the basin progressively more resistant, with ‘old invaders’ preventing or slowing the entry of potential ‘new invaders’ (Drake et al., 1989). Information from archaeological and historical records, as well as observations of modern habitat responses to disturbance events such as range ires, indicate that Mediterranean ecosystems resist heavy human impacts well in the sense that they regenerate quickly ater abandonment or degradation. 44 Islands and plants: preservation and understanding of lora on Mediterranean islands CONCLUSION In the long run, one cannot dismiss the heavy and long lasting tribute paid by several components of biodiversity to the many aspects of human action everywhere in the Mediterranean basin. However, the endless redesign of Mediterranean landscapes through traditional land use systems probably beneited several components of biological diversity. Gomez-Campo (1985), Pons & Quézel (1985), and Seligman & Perevolotsky (1994), among others, have argued that the highest species diversities in the Mediterranean Basin are found in areas that have experienced frequent but moderate disturbance, giving support to the diversity-disturbance hypothesis advocated by Huston (1994). Understanding the persistence of biological diversity and sustainable ecosystem function across so many centuries, without irreparable damage, would necessitate considering the feedback mechanisms that keep ecosystems running. Positive and negative feedback cycles involving humans and operating for long periods at local or regional levels do indeed operate in the Mediterranean (see, e.g. Blondel et al. 2010). he highest biological diversity in Mediterranean ecosystems probably never occurred in woodlands, even in the pristine ones, but rather in the various agro-sylvopastoral systems. As human pressures on Mediterranean landscapes intensiied in later periods, especially when disturbance regimes such as burning, wood-cutting, and tilling reached some threshold values, diversity declined and ecosystems followed new trajectories, leading to alternative stable states that are characterized either by highly productive industrial-style agriculture or heavily degraded ecosystems such as badlands. Ater more than 10,000 years of cohabitation between humans and nature, most Mediterranean ecosystems are so inextricably linked to human interventions that the future of biological diversity cannot be disconnected from that of human afairs. he greatest challenge for the decades to come is to promote sustainable development through the development of appropriate tools for integrating environmental issues and development. 45 Humans, landscapes and biodiversity in the Mediterranean region REFERENCES molecular markers to understand olive phylogeography. In: Zeder, M.A., Bradley, D.G., Emshwiller, E. & Smith, B.D. (eds.). Documenting domestication: new genetic and archaeological paradigms. University of California Press, Berkeley. p. 143-152. Alcover, J. A., Moya-Sola, S. & PonsMoya, J. 1981. Les quimeres del passat. Els vertebras fossils del Plio-Quaternari de les Baleares i Pitiuses. Palma de Mallorca. Attenborough, D. 1987. he First Eden. he Mediterranean World and Man. 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International Journal of Wildland Fires, 15: 397-405. 49 Humans, landscapes and biodiversity in the Mediterranean region 50 Islands and plants: preservation and understanding of lora on Mediterranean islands IUCN PLANT CONSERVATION PROGRAMMES IN THE MEDITERRANEAN Bertrand de Montmollin IUCN-SSC, c/o biol conseils s.a., Rue de la Serre 5, CH-2000 Neuchâtel. montmollin@ biolconseils.ch Abstract he Mediterranean Basin is one of the world’s richest places in terms of animal and plant diversity. he Mediterranean is particularly noted for the diversity of its plants – about 25,000 species are native to the region and more than half of these are endemic. his has led to the Mediterranean being recognized as one of the Global Biodiversity Hotspots (Mittermeier et al., 2004). he IUCN Species Survival Commission has identiied plant conservation and red listing as a regional priority for action and has already assessed the conservation status of 200 endemic plant species and 500 freshwater plant species. IUCN’s ongoing work on plant conservation in the Mediterranean includes the following projects: · he IUCN Mediterranean Biodiversity assessment initiative · he Mediterranean Plant Red List: Assessing the status of steno-endemic plants · Important plant areas of the south and east Mediterranean region · In situ conservation projects Keywords: IUCN, Red List, plant, conservation, IPA IUCN – SSC he Species Survival Commission (SSC) was established by the IUCN, International Union for Conservation of Nature, in 1949. Since that time, the SSC has grown into a global, science-based network of thousands of volunteer experts, working together towards achieving the vision of “A just world that values and conserves nature through positive action to reduce the loss of diversity of life on earth”. he major role of the SSC is to: · Provide information to the IUCN and the rest of the world on the conservation of species and on the inherent value of species in terms of 51 IUCN plant conservation programmes in the Mediterranean ecosystem health and functioning, the provision of ecosystem services and the provision of support to human livelihood. · Promote the conservation of species, thereby leading to measurable reductions in the loss of biodiversity. Collectively, SSC members form a highly-regarded and inluential network of species experts that is able to inluence conservation outcomes at all levels, particularly international, through engaging with each other and collaborating in both the IUCN’s and SSC’s name. he SSC undertakes assessments of the status of species, develops species conservation action plans and strategies, prepares technical guidelines and formulates IUCN policy statements. he Commission delivers and promotes this technical knowledge, advice and policy guidance to those who can inluence the implementation of conservation action around the world. he strength behind the SSC is a worldwide network of volunteer experts who ofer their time and expertise to build a scientiic and practical foundation for the efective delivery of conservation. he thousands of volunteer experts are organized into Specialist Groups (SGs), Red List Authorities (RLAs) and Task Forces (TFs) arranged taxonomically, thematically and/or regionally, and convened by the SSC in response to pressing conservation issues. he overriding goal of the Commission is: “he species extinction crisis and massive loss of biodiversity are universally adopted as a shared responsibility and addressed by all sectors of society taking positive conservation action and avoiding negative impacts worldwide”. Main strategic objectives: 1. Assessing and monitoring biodiversity. To assess and monitor biodiversity and inform the world about the status and trends of biodiversity, especially at the species level, thus providing measures for the health of our one and only biosphere; 2. Analyzing the threats to biodiversity. To analyze and communicate the threats to biodiversity and disseminate information on appropriate global conservation actions; 3. Facilitating and undertaking conservation action. To facilitate and undertake actions for providing biodiversity-based solutions for halting biodiversity decline and catalyze measures to manage biodiversity sustainably and prevent species’ extinctions both in terms of policy changes and actions on the ground; 4. Convening expertise for biodiversity conservation. To provide a forum 52 Islands and plants: preservation and understanding of lora on Mediterranean islands for gathering and integrating the knowledge and experience of the world’s leading experts on species science and management, and promoting the active involvement of subsequent generations of species conservationists. he Mediterranean Islands Plant Specialist Group is one of the 25 SSC’s Plant Specialist Groups. It was formed in 1995 and it currently includes some thirty members. Its objectives are: · To evaluate and monitor changes in Mediterranean island plant diversity; · To establish, co-ordinate and implement conservation Action Plans; · To promote sustainable conservation of plants and their habitats among decision makers and the public. IUCN CENTER FOR MEDITERRANEAN COOPERATION he IUCN Center for Mediterranean Cooperation was established in Malaga in October 2001. he objectives, which relect the signiicant areas of work that the IUCN Center for Mediterranean Cooperation will fulill in order to achieve its goal, are: 1. Making knowledge, information and experience available regarding the conservation and management of Mediterranean biodiversity and natural resources for sustainable-use and rehabilitation eforts. 2. Strengthening and supporting IUCN members and Commissions in the region to mainstream social, economic and environmental dimensions in policy-making, management, and the conservation of biodiversity and natural resources. 3. Promoting, both globally and regionally, Mediterranean policies on conservation and sustainable development, and supporting mechanisms for their implementation. THE IUCN MEDITERRANEAN BIODIVERSITY ASSESSMENT INITIATIVE Background Knowledge of the Mediterranean region biodiversity is heterogeneous at a national level, sometimes restricted to species lists, occasionally also including spatial distribution. Data is dispersed, and there is no regional summary, nor internationally recognized baseline for easily assessing which plants listed as endemic or on national red lists are in fact truly threatened. Taxonomic expertise is oten lacking, and there may be disagreements on nomenclature and classiication, especially for the lower taxonomic groups. Protection measures 53 IUCN plant conservation programmes in the Mediterranean for large mammals and birds tend to be adequate, but where biodiversity hotspots for lora, and other groups, have been identiied there is as yet little explicit linkage to regional and national policies, beyond the limited species lists under the Habitats Directive and Barcelona Convention. Action he IUCN Mediterranean Biodiversity Assessment Initiative aims to produce an analysis of a wide range of species at a regional level. In addition, occurrence of threatened species is a key criterion in the identiication of key biodiversity areas through combining spatial data on all vertebrate and plant species, hence moving away from “Important Bird Areas” or “Important Plant Areas” towards a more holistic approach to biodiversity conservation. IUCN’s role IUCN has already begun the assessment of Mediterranean reptile, amphibian, shark and freshwater ish species. his has demonstrated not only the willingness of the scientiic community, the vast majority of whom act in this process as volunteers, to contribute to the assessments, but the degree to which the conservation community considers a Regional Red List as an essential regional tool for guiding and assessing nature conservation priorities and progress. he initiative seeks to mobilize existing knowledge on species status that may be dispersed or unpublished, and ensure that it is made available for conservation purposes. he key role of IUCN is to coordinate the process ensuring full participation of all appropriate experts, validate the quality of the information, ensuring results of the highest scientiic quality, and free of potential individual interests of participating scientists. Objectives 1. Assess regional species status for the major taxonomic groups 2. Support the assessment process and the production of national Red Lists to guide conservation decision-making and monitoring at a national level. he objective is to compile the data and the species assessments that form the basis of the Mediterranean Red List for the major taxonomic groups. he IUCN will manage the work being done among the diferent Specialist Groups and coordinate the incoming data to ensure that assessments are completed to standard and within the timeframe. Once a preliminary assessment has been completed and compiled, a workshop will be organized to validate the results. Finally the coordinator (assisted by a consultant, appropriate Red List Authority or Commission specialist group chair) will go through each of the assessments made and the feedback from the workshop to derive a inal compilation of 54 Islands and plants: preservation and understanding of lora on Mediterranean islands assessments that will provide the inal outputs of the assessment process and the basis for the reports and information dissemination. Results of Phase I of the project hirteen taxonomic groups (amphibians, cetaceans, crabs, crayish, dragonlies, mammals, molluscs, aquatic plants, freshwater ish, marine ish, sharks and rays, reptiles, marine vegetation), have been evaluated. Goals of Phase II of the project he speciic outputs of Phase II are: · Conservation status of 1,500 priority plant species assessed · Conservation status of 400 Mediterranean butterlies assessed · Conservation status of 450 Mediterranean saproxylic beetles assessed · Conservation status of 70 Mediterranean dung beetles assessed · Conservation status of ca. 200 Mediterranean anthozoan species assessed · Important Freshwater Areas (IFWA) in the Mediterranean region identiied, priorities deined and site-based pilot projects identiied · Information made available to decision-makers and stakeholders MEDITERRANEAN PLANT RED LIST: ASSESSING THE STATUS OF STENO-ENDEMIC PLANTS Project objectives and outputs he Mediterranean region is home to around 25,000 plant species; approximately half of them are endemic to this biogeographic region. he endemic species are mainly – but not exclusively – concentrated on islands, peninsulas, rocky clifs and mountains. To date, very few plant species have been assessed using the IUCN Red List categories. A great efort has to be made to have a better idea on their vulnerability, the threats they are facing and the conservation actions that should be undertaken to protect them. he most vulnerable endemic plants are the restricted-range endemics (steno-endemics), as their area of occupancy is small and they might be pushed to extinction by any major disturbance. In addition, when the number of individuals in a population falls below a certain threshold, the species loses genetic diversity which reduces its ability to adapt to change (for instance climate change) and therefore further increases its extinction risk. he project will therefore consider them a priority. Even with a focus on only steno-endemics, the task is considerable. he initial list of possibly threatened Mediterranean plants to be assessed will probably contain 3,000 to 4,000 species. his preliminary list must irst be established 55 IUCN plant conservation programmes in the Mediterranean and then will need further prioritization before Red List assessments can begin. Priority will be given to high altitude plants and to selected low altitude groups of taxa. he main objective of this project is to assess the conservation status of about 1,500 restricted-range endemic plants, selected among the most likely to be threatened. he production of Red Lists is not a goal per se, but they can be used to deine conservation priorities, for example: lists of legally protected species, a basis for species recovery action plans, helping to deine Important Plant Areas and protected areas. Where possible, provisions will be made within this project to encourage, support and provide training for scientists within those countries where the development of national red lists for plants is priority. Methodology Geographical scope of the project he Mediterranean region and the plant species associated with it are notoriously diicult to deine in an absolute fashion. For the purposes of this project, a working deinition of the Mediterranean biogeographic region will be used to provide a starting point. he deinition chosen is that of Médail & Quezel (1997); it includes all the strictly Mediterranean mountains that have a Mediterranean bioclimate (e.g. the Atlas and Taurus mountains) but only the Mediterranean part of the northernmost sub-Mediterranean mountains (Maritime Alps, Pyrenees, Balkan mountains, Rhodopes). Collecting the already Red List assessed taxa Many Mediterranean plants have already been assessed, using diferent methodologies. Few of them fulill the standards of the IUCN Red List assessments and are therefore not included in the IUCN Red List database. In many cases, the assessments were made using out of date or national/local criteria, but the species already considered as “threatened” in these lists, and being steno-endemics, should be reassessed using the IUCN Red List criteria (IUCN, 2001). he list of already assessed taxa will be established on the basis of: · he IUCN Red List database · Existing national or sub-national red lists (excluding non-Mediterranean taxa) · Scientiic publications he outcome will be a list of: 56 Islands and plants: preservation and understanding of lora on Mediterranean islands · Already assessed Mediterranean taxa (corresponding to the IUCN Red List standards) · Potentially threatened (or rare) taxa that should be reassessed using IUCN Red List standards) Production of a Mediterranean steno-endemics list he taxonomic information available on Mediterranean plant taxa is rather good, but dispersed in many loras and publications. It is therefore not possible to issue a list of Mediterranean steno-endemics without signiicant bibliographical work and without consulting experts. At a irst stage, an agreed and quantitative deinition of what is a steno-endemic has to be agreed upon by compiling bibliographical information and consultation of experts. he outcome will be a list of Mediterranean steno-endemics. Production of a list of steno-endemics to be RL assessed he preliminary list of steno-endemics will be cross-referenced with the lists of already assessed Mediterranean taxa and potentially threatened taxa. he outcome will be a list of steno-endemics that have to be RL assessed. Preliminary assessment All the listed steno-endemic taxa will be assessed using a “RapidList” procedure. his simple initial classiication will allow selecting all taxa that are “possibly threatened”. his preliminary assessment will be done with national and regional experts, in sub-regional workshops. he exact geography of the sub-regional workshops will depend on the species being assessed. For each taxon considered as “possibly threatened” the need for data collection in the ield will be evaluated. Outcome: A list of possibly threatened steno-endemic taxa, with indication of the ecosystems in which they grow and their altitudinal range Full IUCN assessment All taxa considered as possibly threatened and belonging to high-altitude or lowland selected groups will have a full IUCN assessment. he number of taxa to be assessed is estimated to be about 1,500. he information needed for the Red List assessment could be estimated as follows: · For 500 taxa, the information needed is suicient to make the assessment on a desk-based procedure. In many cases, the basis will be an existing assessment, 57 IUCN plant conservation programmes in the Mediterranean but not in English (cf Red Books for Cyprus and Greece). · For 500 taxa, there is a need to collect additional information or to update it in the ield. · For 500 taxa, there is almost no information and therefore the need for an in-depth survey in the ield. his assessment will be made by national experts. · Training will be provided by the IUCN. Much of the plant population data that will be used to make assessments will be held at national level. · During training, the process of allocating the assessment of regional (multicountry) Mediterranean endemics will be discussed and completed. · Single country endemics should be assessed at a national level, by convening national workshops or meetings. he assessments will be validated by the scientiic advisor of the sub-project and inally the Red List regional authority. Outcomes: A full Red List assessment of 1,500 Mediterranean high altitude endemics. Analysis and inal report he data collected during the assessments will be analyzed and will be included in a inal report: · Analysis of the main threats · Analysis of the habitat types with threatened steno-endemics · Analysis of the already taken conservation measures (protected areas, ex situ and in situ conservation measures) · Mapping of sites with threatened plants · Recommendations for conservation actions IMPORTANT PLANT AREAS OF THE SOUTH AND EAST MEDITERRANEAN REGION his project, involving the IUCN, Plantlife and WWF and supported by the French Development Agency was conceived to support the creation of an Ecosystem Proile for the Mediterranean region by the Critical Ecosystem Partnership Fund (CEPF). he Goal was to ensure that plant priorities were included in the Proile document which outlines biodiversity priorities in the region. Important Plant Areas (IPA) are internationally important sites for wild plants and fungi, identiied at a national level using standard criteria (Plantlife International, 2004). Initially developed to address the lack of focus on 58 Islands and plants: preservation and understanding of lora on Mediterranean islands conserving plant diversity, IPAs provide a framework to assess the efectiveness of conservation activities for plants and target sites for future action. hey support existing conservation programs such as protected area networks and the CBD Global Strategy for Plant Conservation. he Mediterranean is an undisputed global biodiversity hotspot solely because of its huge plant diversity. Around 10% of the world’s vascular plants (25,000) are found in the Mediterranean Basin on less than 2% of the Earth’s surface and half of these species are found nowhere else on Earth. However, precise data on the distribution and status of plants are frequently insuicient, out of date or absent, particularly in the south and east of the region. his fact potentially results in the haphazard application of conservation action. his project describes a rapid assessment of Important Plant Areas in the south and east Mediterranean; a project designed to provide the ‘wild plant perspective’ for the regional investment strategy of the Critical Ecosystem Partnership Fund. he project has involved botanical teams from Algeria, Egypt, Israel, Jordan, Lebanon, Libya, Morocco, Palestine, Tunisia, Syria and Albania. 207 IPAs have been identiied in the project countries bringing the total IPAs in the region to 888. hreatened and restricted species and habitats present on these sites have been recorded along with the threats afecting them. All Mediterranean habitats are represented: forest, maquis, garrigue, pasture, wetland, coastal and the transition to the desert zone. 40% of IPAs identiied coincide with key biodiversity areas in the region; sites important for other taxa (mammals, birds, freshwater ish and amphibians). 75% of IPAs contain locally endemic species found only within one country; 60% contain very restricted species. ‘Mega endemic sites’ containing over 20 very restricted species can be found in Algeria, Morocco, Lebanon, Syria and Libya. Overgrazing of pastoral lands is the most signiicant threat to the IPAs afecting 67% of sites. Deforestation (largely due to collecting irewood), tourism development, intensiication of arable farming and unsustainable collection of plants afect over one third of the analyzed IPAs. he level of oicial protection for IPAs varies across the project countries from 0 to 80%. hough oicial protection of sites can be a helpful measure of conservation, evidence of management plans leading to biodiversity friendly land management is a better measure. Evidence of management plans for IPAs in the region is minimal. A unique product of this project is the irst preliminary list of restricted range plant species for North Africa and the Middle East, which found that 59 IUCN plant conservation programmes in the Mediterranean 1,195 species occur within less than 5,000 km2 and around 50% of these occur over less than 100 km2. Understanding the level of threat to these species will help target actions against biodiversity loss. IPAs are not an optional extra and neither is their conservation. hey support the livelihoods of many people and provide undervalued services such as water and lood control, carbon capture, the prevention of desertiication and a reservoir of genetic species and diversity; all critically important for the Mediterranean region. 10 recommendations have been developed to help direct the conservation of wild plants in the Mediterranean: IPA conservation Recognize Important Plant Areas as internationally signiicant priority sites for conservation in local, national and regional environmental policies and plans. Target Important Plant Areas as priority sites for conservation action in the Mediterranean region. his will ensure that direct conservation action on priority plant sites can begin now, alongside the continued eforts to improve data. Incorporate IPAs (where appropriate) into protected area networks. Update management plans for protected areas that contain IPAs to take account of new plant data and ensure efective implementation. To develop and implement management plans for IPAs where they do not exist (starting with top priority sites). Ensure that Environment Impact Assessments are undertaken on development projects that afect IPAs and ensure that their recommendations are enforced and monitored. Target IPAs for the implementation of sustainable forest management and agri-environment schemes and projects. Encourage communities whose livelihoods depend on plant resources to participate in IPA conservation planning activities (e.g. medicinal plant collectors, promoters of nature tourism, hunters, mountain guides). IPA data ‘Ground–truth’ the plant species and habitat data associated with IPAs through ieldwork (starting with priority IPAs named in this report) and ensure that IPA plant features are properly mapped. Invest in the provision of comprehensive and updated information on plant and habitats species in the south and east Mediterranean, building on the work 60 Islands and plants: preservation and understanding of lora on Mediterranean islands carried out in this project. his should include: · A deinitive list of restricted range, endemic plant taxa for the Mediterranean with accurate data on their distribution, size and importance to the local community. · A regional IUCN Red List for the Mediterranean (begin by focusing on restricted range species that are endemic to the region). · National IUCN Red Lists for vascular plants for all south and east Mediterranean countries. · A list of Mediterranean habitats and threatened habitats. Enable the data associated with IPAs to be iled electronically (such as on the IPA database) so it can be easily updated via the web. Successful implementation of all this, in the second part of the project, will secure a sustainable future for the environment and inhabitants of this unique region; failure will result in both to a loss of natural resources and little or no resilience when faced with profound changes in climate. IN SITU CONSERVATION PROJECTS he Mediterranean Islands Plant Specialist Group is working on several in situ conservation projects related to threatened taxa listed in he Top 50 Mediterranean Island Plants (Montmollin and Strahm, 2005). In Corsica, on Biscutella rotgesii Foucaud, with the Conservatoire botanique de Corse, l’Université de Corse and l’Oice de l’environnement de Corse. his species is threatened by road building, invasive species, ire and overgrazing. he conservation measures taken are: legal protection, microreserves, ex situ conservation. On the Balearic Islands, on Naufraga balearica Constance & Cannon, with the Universitat de les Illes Balears and the Jardi Botanic de Soller. his species is threatened by drought, competition with other plants and overgrazing. he conservation measures taken are: management of goat herds, microreserves and ex situ conservation. Also on the Baleraric Islands, on Apium bermejoi l. L. Llorens, with the same partners and the Consell Insular de Menorca. his species is threatened by drought, competition with other plants and caterpillars. he conservation measures taken are: reintroduction in new sites, watering, microreserves and ex situ conservation. In Sicily, on Calendula maritima Guss., with the Botanical Institute of Palermo, the Instituto di genetica vegetale of Palermo, the Conservatoire 61 IUCN plant conservation programmes in the Mediterranean botanique national de Brest, with the support of the Institut Klorane. his species is threatened by development and waste disposal. he conservation measures taken are: microreserves, ex situ conservation and population reinforcement. Also in Sicily, on Pleurotus nebrodensis (Inzenga) Quélet, with the Botanical Institute of Palermo, the Park of Mts Madonie and the Community of Mts Madonie. his species is threatened by overcollection. he conservation measures taken are: legal protection and cultivation in order to alleviate collection in the wild. REFERENCES IUCN, 2001. IUCN Red List Categories and Criteria: Version 3.1. IUCN Species Survival Commission, IUCN, Gland, Switzerland. Médail, F., Quézel, P. 1997. Hot-spots analysis for conservation of plant biodiversity in the Mediterranean Basin. Annals of the Missouri Botanical Garden, 84: 112-127 Plantlife International 2004. Identifying and Protecting the World’s Most Important Plant Areas. Salisbury, U.K. Mittermeyer, R.A., Robles Gil, P., Hofman, M., Pilgrim, J., Brooks, T., Goettsch Mittermeier, C., Lamoureux, J., da Fonsecca, G.A.B, 2004. Hotspots Revisited: Earth’s Biologically Richest and Most hreatened Terrestrial Ecoregions. Conservation International, Washington D.C., USA. 62 Islands and plants: preservation and understanding of lora on Mediterranean islands PLANT CONSERVATION INVENTORIES, WHAT WE HAVE NOW AND WHAT WE NEED FOR THE FUTURE Felipe Domínguez Lozano Departamento de Biología Vegetal, Facultad de Biología. Universidad Complutense de Madrid. C. José Antonio Nováis, 2. E-28040, Madrid, SPAIN. felipe.dominguez@bio.ucm.es Abstract Plant conservation inventories in Spain have experienced a paramount increase for the last three decades, not only those related to basic knowledge of endangered plants, but also on conservation tools and protection strategies. One of the key projects in this recent development is the Atlas de Flora Amenazada project (known by its Spanish acronym: AFA). Since its inception in 2000, this collaborative work among Spanish botanists has produced some important conservation tools. In the irst part of this article, we present some relevant results and give some clues to explain the success of the AFA project. As a result of AFA and several equally important regional initiatives, the amount and quality of data in relation to Spanish plant conservation is extraordinary. From our point of view, we, scientists and managers, need to step down, and rethink these inventories and try to ind how we can use them to identify present and future trends in plant biodiversity. We review some monitoring variables for this purpose in the second part of the paper. We consider some of the most popular monitoring variables (area of occupancy, threat category and population size) to identify its advantages and drawbacks in the implementation of future monitoring programs. At the end of the article, we present a list of possible general recommendations derived from these analyses. Keywords: Atlas, hollow curve, monitoring, population viability analysis, Red Data Book, Spanish plant conservation, threat analysis. INTRODUCTION he last 30 years have been the most successful period for Spanish biodiversity conservation (Morillo & Gómez-Campo, 2000). Nevertheless, during this time, threats to habitat and species populations have also been produced at an unprecedented pace and scale. In true meaning, the country 63 Plant conservation inventories, what we have now and what we need for the future can be considered a broad conservation experiment; on the one hand, inside its boundaries an important amount of European nature is maintained. Habitat diversity is at its highest in the Continent, with Spanish habitat unique to the world, and Spanish lora constitutes an original biogeographical array with high rates of endemic species, important relict species and inally, species whose Spanish populations constitute the limit of their range distribution. On the other hand, Spain has undergone a serious and rapid change in land use, economics and social awareness, all during this period. More speciically, urbanization and transport infrastructures have produced drastic changes in the landscape and altered composition and population dynamics of habitat and species. In our point of view, this melting-pot has been fundamental to nurture some very interesting and innovative plant conservation initiatives. To name just a few, an extensive network of local but comprehensive botanic gardens now covers all biogeographical zones of Andalusia territory (AA.VV., 2005). Pioneering work in Valencia has produced a large network of small protected areas speciically devoted to plant conservation, known as microreserves, now extended in several regions of Spain and other European countries (Laguna et al., 2004). he Canary Islands and Aragon are leading regions in the development of sound and useful Recovery Plans for threatened plants in their areas (Marrero Gómez et al., 2003; Alcántara et al., 2007). One example of these novelties in plant conservation action is the Spanish Atlas of hreatened Flora (hereinater called “AFA project”). Since its inception, this work has represented a continuous efort to inventory and report the conservation status of the Spanish lora. Inventories are at the core of any conservation strategy. hey inform us about the species in need and also about what we need to do to protect them. Inventory activities require large investment of time and resources at the start, becoming increasingly useful and proitable with time. As more and more areas and species are covered with these inventory activities, it is required to adapt them to new situations, improve their use, and make them more cost-efective (Lughadha et al., 2005; Baillie et al., 2008). he objectives of this work are twofold: irstly, we summarize here some results of the AFA project. Framing the project in the Spanish conservation context, we briely describe its inceptions and rationale. hen, we present some of the most relevant results derived from diferent actions contributing to the AFA project. And inally, we give some ideas about key aspects explaining its implementation and results across Spain. In the second part of the article, we 64 Islands and plants: preservation and understanding of lora on Mediterranean islands examine some of the postulates of present plant inventories and how they can be used to improve future monitoring techniques. Future monitoring programs need to rapidly and precisely report any changes in biodiversity trends, and the information and expertise derived from current inventories can be employed to save time and resources when future monitoring programs take shape. AFA PROJECT: TEN YEARS OF RESULTS In December 1995, a group of 20 conservation botanists came together in the Cordoba Botanic Garden to promote the new IUCN Spanish committee. Several issues were addressed; the creation of the lora commission within the IUCN Spanish committee, the launching of a plant conservation bulletin, etc. he meeting ended with a general understanding that a new list of threatened plant species was urgently needed in Spain (see Conservación Vegetal 1, 1996). he last list had been published 11 years earlier, in 1984, so there was a need to update information contained in this antiquated list. Moreover, certain results derived from several plant conservation inventory projects from diferent parts of Spain made this task urgent. Eventually a Spanish lora commission within the IUCN Spanish committee was formally set up and the irst meeting of the new Flora Commission was held in L’Albufera de Valencia in July 1999 under the auspices of the Government of Valencia. From this meeting a steering committee was formed with one objective: to produce the new Spanish plant Red list (see Conservación Vegetal 5, 2000). By that time, the Biodiversity agency of the Spanish Ministry of Environment was ready to help and promote plant inventories because they were also launching a new general Spanish biodiversity inventory, involving vertebrates, invertebrates and plants. his inventory was also a requirement from the implementation of a new Spanish biodiversity conservation legal framework, and closely related to the development of some of the protocols of the Convention of Biological Diversity (CBD). Spain was part of the CBD by ratiication since the end of 1993. It was not surprising that the Flora Commission of Spanish UICN committee and the Biodiversity agency of the Spanish Environmental Ministry found common grounds, and the latter organized in February 2000 another meeting in Miralores (Madrid). he inal drat of the new list was approved, and a few months later the 2000 Red List of Spanish Vascular Flora was published (AA.VV., 2000). In addition, the Spanish Ministry took the opportunity in Miralores to present to the botanist community the need for a larger project involving ield conservation inventories and the production of 65 Plant conservation inventories, what we have now and what we need for the future red data books. Rapidly, botanists and managers agreed on the advantage of the upcoming new plant red lists to develop a more ambitious project. his way, the foundations of the AFA project were laid. During the following years an extensive survey involving many of the most threatened plants in Spain was carried out. Results came aterwards, and three years later, in 2003, the irst red data book containing 478 taxa was published (Bañares et al., 2003; Bañares et al., 2004). hose plants were amongst the top list priorities in Spanish plant conservation, comprising mostly Critically Endangered and Endangered plants according to UICN categories. In 2007 a new volume with 35 new taxa came to light, and those taxa were studied during a two-year (2005 and 2006) campaign (Bañares et al., 2007). A new volume with 53 taxa appeared in 2008, corresponding to plants studied during the previous year (Bañares et al., 2008). he last one has been published recently, and it includes 57 plants surveyed in 2008 and 2009 (Bañares et al., 2010). THE AFA PROJECT AS A MODEL INVENTORY Several conservation works came to light under the umbrella of the AFA project, most importantly, but not exclusively, red data books. he four mentioned red data books were structured following standards widely used in conservation inventories. herefore, a red data sheet for each plant showed short depictions about current taxonomy, biology and habitats preferences, demography (including data about life span, recruitment, reproduction, etc.), reported on potential threats and inally conservation measures (active or passive). However, it was the population approach that made this work more innovative. So, for the irst time in Spanish plant conservation, the unit of inventory was the population and not the species. Accordingly, populations were mapped and size recorded explicitly for the project. In addition, main threats were reported for each of them. All the information, associated with both species and population, has been recorded in an extended database. he precise survey methods for the AFA project have been described elsewhere (see for example Moreno et al., 2003). As of May 2011, AFA database contains 609 ield reports covering 623 taxa, the diference consisting in extinct plants in Spain with no current location. here are 4649 areas surveyed and 3179 populations conirmed, the diference is made up of populations with more than one location and problematic locations (not found populations, misplaced references, mistaken areas, etc.). he inventory includes 32,966 referenced UTM 1x1 square km, with 5,812 of them representing a conirmed presence of a species. 66 Islands and plants: preservation and understanding of lora on Mediterranean islands Before red data books, a ield handbook was elaborated for the ield data gathering of AFA project (Iriondo, 2011). hus, since the beginning of the project, a group of botanists from diferent disciplines (loristic, taxonomist, plant ecologist, plant conservation managers) worked together to elaborate an operation manual or basic ield work protocol. his handbook set the guidelines to perform censuses and tallies, mapping, demography and threat analyses and ield forms and database management. A drat was presented and approved for all AFA participants before the irst ield campaigns and the inal document was ready to use by all regional teams at the time of ield prospecting. We may also consider red data listing as a dire product of the AFA project. We have shown already that the elaboration of the 2000 red data list was closely related to it. he 2000 red data list provided a well-accepted threatened plant ranking among the plant conservationist community, useful to provide the plant selection for work in ield survey. 100 botanists coming from universities, botanic gardens, national parks, regional conservation agencies, freelance professionals, etc. produced the list in less than six months. 1,800 Spanish taxa were evaluated with the 1994 UICN criteria (Mace, 1994) and 1,414 appeared in the inal approved list (Laguna & Moreno, 2000). he next list will be published 8 years later, in 2008 (Moreno, 2008). We may think of two main reasons for the production of this new IUCN threat classiication. On the one hand, not only the AFA project but several active conservation projects promoted by regional governments in Spain had produced quality data for several plants since the 2000 list. On the other hand, a new UICN cataloging system appeared in 2001. his involved not only new categories, but also changes in some thresholds in the IUCN criteria and subcriteria (IUCN, 2001). Consequently, in order to update data and classiication, all plants should be reassessed following new IUCN rules. In a similar procedure to the previous 2000 red data list, 71 authors and 107 collaborators elaborated a new list: the 2008 red data list. Table 1 summarizes the main results from the two lists, and changes have been signiicant. For example, 197 new species were included and 40 old species were excluded in the 2008 list from the 2000 red data list. In total, there were 654 category changes from 2000 to 2008. Finally, the AFA project produced a detailed and original survey for a group of selected plants across Spain, the so-called demographic AFA. A demographic study was set up and taxa were monitored every year for six consecutive years. In all, 37 species were selected and, 20 ield teams sampled 65 populations and more than 13,000 individuals during this 6 year period. Using demographic 67 Plant conservation inventories, what we have now and what we need for the future modeling tools (Caswell, 2001), this monitoring allowed a detailed demographic analysis (Iriondo et al., 2009). Table 1. Distribution of IUCN threat categories (according to 1994 and 2001 criteria, respectively) among taxa in 2000 Red List and 2008 Red List in Spain. AFA PROJECT: ORGANIZATION AND REASONS FOR SUCCESS he organization of such a project was a true challenge for the Spanish botanist community. Never before had anyone tried to gather and update detailed information on such a large array of species during such a short period of time. he whole Spanish territory was divided into ive zones to be able to cope with the bulk of species and deadlines of the project: Central zone, Andalusia zone, Atlantic zone, Canaries zone and Mediterranean zone. Regions were delimited following two criteria, a region should be under a similar biogeographical settings and the number of species per region should be not very diferent. he only exception was the Canary Islands region, where more species than in any other territory were selected due to its insularity. Hence, the Canary regional teams supported an extra work load. In total, 36 regional ield teams were set up. A regional coordinator was established for each region or zone (see Fig. 1). hese ive coordinators formed the scientiic steering committee of the project. In addition to them, another working group was set up to produce the above mentioned ield work handbook 68 Islands and plants: preservation and understanding of lora on Mediterranean islands and solve speciic methodological problems during ield campaigns. Finally, a management team (TRAGSA group) was also established, in charge of diverse tasks such as organization of meetings, license procedures, database design and management, data low, image and promotion, social awareness, publication editing and coordination, etc. Figure 1. Flow chart of the Spanish Atlas de Flora Amenazada project. Ten years from the start of the project may be enough, not only to describe key aspects of the organization and settings of the AFA project, but to try to shed light on some of the reasons explaining this long-running project. From our point of view, there are two factors that have contributed to the success of this monitoring project: historical and scientiic. Among the irst, perhaps the most relevant is the building up of a solid Spanish plant community during previous years, probably starting in the 1960s (Domínguez Lozano et al., 2001). Most of them derived from Academia, where plant taxonomy and loristic disciplines were still appreciated in the curricula and research skills at the moment of AFA inceptions and certainly more than they are today. 69 Plant conservation inventories, what we have now and what we need for the future Another important reason is the upheaval of a small but hard working (and brave) group of plant conservation managers in Spain. heir inluence areas were located in some regional conservation agencies across Spain. We should to be grateful that Spain is a member of the EU in order to explain why those plant conservation managers were so important. EU provided some legal and funding help during the 90s to start up a whole new conservation structure in Spain. As a result, a powerful network of regional conservation agencies was established, which in turn gave way to the arrival of new professionals (young botanists were among them) to the Spanish conservation arena (Moreno Saiz et al., 2003). Completing this picture was the embracing of the Spanish government of wider International conservation initiatives, the most important being the Convention of Biological Diversity. As a consequence, a sound and modern Spanish plant conservation legal framework was ready to be implemented at the start of the AFA project. We can envisage some scientiic or methodological reasons as well with regard to AFA development. hus, one key aspect is the production of a wellaccepted, easy to use ield work methodology (see above). It was not an easy task if we consider the amount of plants and people involved in the AFA project. Relevant to the work was the availability of a plethora of diferent kinds of loristic works produced during the previous years. In this way, local and regional loristic catalogues, databases and phytosociological eforts covering extended areas in Spain had been produced in former decades. he detailed information provided was of paramount importance for the rapid implementation of the project. Certainly without this base knowledge the compilation for AFA project would have been very diferent and the results never the same. Finally, the expertise and skill provided by some basic reference taxonomic works also contributed to the success of the project. he role of Flora Europea irst, and most importantly the continued efort of Flora iberica should be stressed. Several regional loras also contributed directly to provide basic taxonomic and loristic information for the project. Taxonomy work should be at the front line of the conservation strategy and from this point of view those projects produce, as with Flora Iberica, a comprehensive taxonomical work that with healthy tensions are translated to the conservation world. THEORETICAL UNDERPINNINGS OF BIODIVERSITY INVENTORIES AFA project may be considered an example of classic inventories: it gathers in a particular time frame as much information of a pool of species 70 Islands and plants: preservation and understanding of lora on Mediterranean islands as possible. However, can all these eforts and resources inform us about key biodiversity aspects? As we have shown, AFA project has been operating for ten years, and usually inventories may extent for longer periods of time. So, at least theoretically, they contain information about the evolution in time of biodiversity. But it is not clear how all this information can show us simple patterns in biodiversity. In other words, are inventories really capable of measuring biodiversity losses and gains? Another important aspect is to know if inventories or surveys are useful to assess how efective in halting biodiversity losses present conservation strategies really are. Sooner or later, conservation measures will produce results, but it is not clear how future inventories will record them. Finally, and particularly relevant, is to know if inventories will be sensitive enough to the several impacts and threats to plant biodiversity. Can we use present inventory techniques as early warning systems of future changes? In order to shed light on these questions, we need to explore the quality and the quantity of data that a standard inventory usually produces. We may think of at least three main variables that most of the present biodiversity inventories usually consider: - Overall, they record the presence of the species, most commonly measuring the area of occupancy. he way this variable is measured varies, but it usually employs a cartographic grid with a speciic scale closely related to the survey efort. Atlases frequently employ a 10x10 square km grid (UTMs in Europe) on a regular basis, but more recently a reduced scale has been used: 1x1 square km grid. - Inventories ofer data related to not only the presence but the abundance of the plant. he way this information is collected is even more diverse. It usually consists of very simple information: a plant is rare, common, etc., it can use cover indexes as well, and in some particular cases, more oten performed for animals, census data are also recorded. - Finally, conservation status is an important piece of information. Inventories report threats and conservation measures for populations or species, and it is also frequent that a threat category is assigned based on this information. AREA OF OCCUPANCY Frequently, area of occupancy, or range size, has been one of the most and primarily recorded variable for plants. Early in the last century, Willis and Jule (1922) showed one consistent biogeography pattern related to this variable. 71 Plant conservation inventories, what we have now and what we need for the future he frequency of rare species is always larger than the frequency of common species for a particular biota. In other words, it is easier to ind rare plants than common ones in any performed inventory no matter scale or species involved. Willis gave a name to this frequency shape curve: hollow curve (Willis, 1922). he hollow curve is similar to the normal curve but with an asymmetry towards the let side, approaching to a lognormal function. So, we say that it is skewed to the let. Skewness is then a measure of the asymmetry of a curve, or its departure for a normal towards a lognormal curve. One of its consequences is that the mean and median no longer coincide (Fig. 2). Figure 2. Hollow curve of the area frequency distribution in a model inventory. X axis represents the size of the area occupied. It is usually expressed using a grid system, for example km2, UTMs or other. Y axis refers to the number of species in each area size class. In essence, the curve represents a histogram of the area size. herefore, it seems appropriate to explore how this curve behaves for some readily available examples of threatened plant inventories. We have been using data from three known inventories for this in a recent study (Domínguez et al., 2012). hese are the Protea Atlas in South Africa, the California Natural Diversity Database (CNDDB) of rare plants and the already described AFA project. Protea Atlas reports the presence of all South African taxa in the Proteaceae family as it is the result of extensive campaigns of ield prospecting involving volunteering and staf capabilities. he sample unit is a 1x1 minute grid (approximately 1.5 X 1.8 km2, Rebelo, 1991). In the case of CNDDB, rare plant data are collected by volunteers, environmental agencies and plant research facilities across California. hey record population areas in diferent 72 Islands and plants: preservation and understanding of lora on Mediterranean islands formats, but eventually a speciic area polygon can be assigned to each reported population. As we have seen, AFA project records plant populations, but in this case using a 1 km2 grid (UTM system). Fig. 3 presents area frequency distributions (or hollow curves) for the three inventories. As expected, the curve shape is similar for all, but particular diferences exist. he value of skewness is one of them for South African distribution, which indicates the most let skewed distribution of all, followed by California and then Spanish data. Another result is range, or data span, being also larger in Proteas, then Spain and inally CNDDB, which possesses the narrowest data range. Ater these results, in the same study we performed a minimum sample analysis to ind out how diferences among the three selected inventories may efect a future monitoring program using just a portion of each biota. Results reported that, proportionally, we need less sample efort for CNDDB, then Spain and inally, for Proteas. Range and inventory size were important parameters related to precision in the analyzed inventories. CNDDB inventory has a small range (because only rare plants are surveyed) but the size is fairly large (more than 1,100 taxa). Both characteristics make this survey the most suitable to start a monitoring program. AFA project is derived from a small range as well (only considering the most threatened plants), but, on the contrary, this survey possesses fewer total records: 250 plants, producing more variation, therefore losing some precision. Protea Atlas represent inventories diicult to monitor because of the large range covered (common and rare proteas) and again its relative small size (only Proteacae species, 422 in total). Lessons learned From this study we can conclude that skewness, or in other words, the shape of the relation between area of occupancy and species numbers, is related to scope and scale of the inventory (which plants and how much and where they are surveyed). But skewness per se does not afect the precision of the future monitoring program. Precision is associated to sources of variation. Large inventories, in terms of species numbers and time span of the survey, produce more precise outputs because some sources of variation are reduced. So, they seem better qualiied to start a monitoring program able to report biodiversity changes as soon as they occur. However, we should be aware of the fact that more absolute eforts will be needed when monitoring, because large inventories involve more species or populations. 73 Plant conservation inventories, what we have now and what we need for the future Sources of variation are several. For example they can come from the nature of the inventory itself (type of taxonomical group or scope). hus, variation arises in wide spectrum inventories (including narrow and wide spread taxa) or inventories that consider a broad array of habitat types or include diverse locations. Finally, other sources of variation arise when inventory is poorly performed (less personnel) or not fully implemented (low surveying time per population or species). Figure 3. Area frequency distribution for (a) South Africa protea species, (b) for rare plants in California and (c) for Spanish AFA endangered plants. X axis represents an area of minute by minute cells (approx. 1.7 km2) of species range distribution for South African proteas, km2 of range area for Californian plants, and UTMs squares of 1 km2 for Spanish species. Figures modiied from Domínguez et al. (2012). 74 Islands and plants: preservation and understanding of lora on Mediterranean islands MONITORING THREAT CATEGORY CHANGES IUCN categories have been in force since the seventies (Holdgate, 1999). Several works have shown the need to use the conservation information provided by these powerful systems (Possingham et al., 2002; Keith et al., 2004; Rodrigues et al., 2006). But in spite of this plea, and some methodological drawbacks, few examples of threat category monitoring exist (Butchart et al., 2004). Plants have been targeted recently to study threat category changes in Iberian Spain and Western Australia (Domínguez et al., 2013). We may focus on some examples of this study, to describe the main causes of threat category change and in which direction and at what pace those changes occur. For example, Tetratheca paynterae (Tremendraceae family) has changed from EN category in 2000 to CR in 2008 in Western Australia. he reason for this upgrading is related to conservation concern because of increasing decline in their area, extent and quality of habitat due to a particular threat: mining. Another example considering a Spanish case; Androsace halleri (Primulaceae) has been downgrading from EN to VU during the same period of time. his downgrading has been related to increasing knowledge derived from better survey eforts that have produced new population indings and an overall better information of the population sizes and limits. Fig. 4 shows results for both territories in relation to causes of category changes. Both charts depict similar proportions in the underlying cause of category movement. So, a threat category change along this time is not frequent in both territories. It is even more noticeable that low proportion of true conservation changes across both sets of threatened plants occurred during these 8 years. Only 12 species out of 432 in Western Australia (2.8%) and 89 out of 1,040 Spanish endangered plants (8.5%) have moved from one category of threat to another that relects genuine changes in their conservation status. hey also maintain similar proportions in two other classes. hus, shares of species that have experienced no change, and species with changes due to knowledge were also alike. Nevertheless, the proportion of WA taxa of ‘no-change’ species during this period represents up to 65% of the 432 total threatened species considered; whereas in Spain, with more species under the IUCN system, a slightly more dynamic assessment has been developed (just 43.4% species experienced no change). 75 Plant conservation inventories, what we have now and what we need for the future WA threatened plants Spanish threatened plants Taxonomy; 41 Taxonomy; 12 New; 17 Conservation; 12 Conservation; 89 New; 19 Criteria; 0 Criteria; 68 No change; 452 Knowledge; 106 No change; 283 Knowledge; 374 Figure 4. Spanish and Western Australia threatened plants distribution according to reasons for change in IUCN categories since 2000. Data from Domínguez et al. (2012). In relation to pace of movement in categories, the same paper showed again similar trends in both regions; during this period upgrading was dominant among species that had moved through the category ranking (Table 2). Most of the reasons produce positive movement and only changes due to criteria revision in Spain and taxonomic revisions in Australia (mainly due to redetermination of herbarium specimens and new assignments to hybrids or previously thought independent species) produce negative or downgrading movements. In Spain we are fortunate because red list comparison can move further backwards in time. his is possible because red data lists exist for 1984, 2000, and 2008. Hence, considering only mainland Spain plants (excluding Canary Islands), 1,104 plants in 1984, 953 plants in 2000, and 1,116 plants in 2008 were tracked in a previous work (see Domínguez, coord., 2008), summarizing 1,892 recorded taxa. his example is useful to show that a part of the “no movement” section represents what we can call “recalcitrant species”. hose that are unable to go further in the conservation ladder have been in the uppermost category since the beginning of the assessments and and still are due to no positive conservation efect. hus during this time, 20 plants have been in the highest category across the whole period of assessment (1.06% of the total). It is needless to say that they are in the utmost need for conservation action. Derived from the same analysis, another important result is the proportion of lora with continuous upgrading (i.e. more sensitive to change): 34 taxa have been upgraded in the 76 Islands and plants: preservation and understanding of lora on Mediterranean islands three assessments. Of the plants considered, 389 (around 20%) have been common to the three lists during those years. Table 2. Average UICN movement according to reason for each territory. One unit represents a single positive movement, for example from EN to CR. Lessons learned hreat category is an important variable to use in a monitoring program, because it is very sensitive to change across time. Although changes are less numerous when short periods of time or only plants in the upper categories are considered, with regards to longer time spans, superior to 10 years and about plants in the lowest threat categories, movements are frequent. Contrary to what it may seem, it is expected that most changes would not be related to true conservation reasons. However, when real conservation reasons are responsible for explaining those changes, they will usually be related to increasing conservation awareness. hen increasing knowledge will probably be the most popular reason for changes in the status of the plants when category movements are monitored. Changes in taxonomy concepts or changes in IUCN criteria classiication are also common motives to produce movements in threatened lists. Reporting and monitoring this kind of movements is also very useful from a monitoring perspective. To some extend, the “better knowledge” output is a guarantee; it 77 Plant conservation inventories, what we have now and what we need for the future shows that monitoring is working and it is able to discover new indings in the real conservation status of surveyed plants. In addition, recording higher knowledge about plants, not only will produce better conservation assessments in the near future, but a better comprehensive plant conservation strategy in the long term, assuring that the truly most endangered plants receive the best conservation measures. Finally, the precautionary principle may explain why so few true conservation movements are produced when short comparison times are considered. hus, in spite of active measures taken to protect plants, inertia may exist not to downgrade them until very clear signs of recovery are shown. DEMOGRAPHIC VARIABLES Monitoring has been closely related to counting individuals along time, in other words, producing censuses with a repeating methodology year ater year (Hutchings, 1991; Schemske et al., 1994). Somehow, it was a general understanding that as much meticulous and time-demanding a census was, much more accurate the monitoring would be and much more information it would contain. At this moment, structured population censuses are among the most detailed of all. hey provide tools for calculating several demographic parameters, being the inite rate of increase or lambda parameter one of them (Caswell, 2001). Fig. 5 shows average lambda values and standard deviation for the above mentioned demographic AFA project. Although an overall tendency to slight negative growth may be inferred, the intra and inter year variations preclude a precise trend. So, one may conclude that there is not a clear departure for demographic stasis, and it is diicult to translate these demographic results to clear conservation recommendations. Although a short period of monitoring partially explains this lack of deinition in trend lines, this is not the only cause, as some examples of structured population monitoring during more extended periods of time also appear. Vella pseudocytisus subp. paui is an endemic and threatened species in Spain, forming part of the group of plants originally selected for the demographic AFA. It has been continuously monitored since then, and now ten years of continuous monitoring can be analyzed for two independent populations. Again, departure from stasis or no demographic change (lambda = 1) seems not to be signiicant during this time (Domínguez et al., 2011a, Fig. 6). Oscillation around equilibrium is predominant and only one population, and just for some years, departs signiicantly from stasis. As a consequence, perturbation has to be strong in order to produce a signiicant departure from standard conditions 78 Islands and plants: preservation and understanding of lora on Mediterranean islands and a clear negative demographic trend (see for more details Domínguez et al., 2011b). hese results may contribute to explain why demographic analyses (criterion E in IUCN threat classiication system) are scarcely used in IUCN assessment for plants in Spain. 10 out of 37 species with available demographic data have been qualiied using the E criterion in the demographic AFA project. Considering the whole 2008 Red Data List (with more than 1,198 plants), 11 species use criterion E. In conclusion, although demographic analysis is not usually available for UICN assessments, when it is so, there is no guarantee to produce useful results for threat category assignments. Figure 5. Average and standard deviation of inite rate of increase (lambda) values for the AFA populations per transition years. 65 populations were monitored during six consecutive years. Figure from Iriondo et al. (2009). If lambda values are equal to one, the population is stable, if lambda values are higher than one, the population experience positive demographic growth, and if lambda values are below one, the population decreases. 79 Plant conservation inventories, what we have now and what we need for the future Figure 6. Finite rate of increase for two populations of Vella pseudocytisus subsp. paui. Average and conidence interval values are derived from bootstrapping of the sampled individuals in both populations. Modiied from Domínguez et al. (2011a) Lessons learned Most of the demographic AFA plant populations experience stable demographic dynamics. hese results may include broad variation or not, but on average, dynamics do not oscillate too much from equilibrium. It is very diicult to detect departure from standard demographic conditions for plants with very stable population dynamics. It may be said that only strong perturbations seem to alter demographic dynamics enough to make a classic monitoring program useful. In our opinion, there are at least two factors playing against the extended use of demographic data for conservation assessments of plants. he diiculty to obtain such information is widely accepted to be one of them (Morris & Doak, 2002). he second factor is related to deinition of clear trends. As AFA monitoring and other works (Domínguez et al., 2011b) seem to indicate, even 80 Islands and plants: preservation and understanding of lora on Mediterranean islands when demographic data is ready to be used, there are diiculties to expose a particular conservation pattern. So, demographic variables are not recommended for a useful monitoring program, they are diicult to monitor and as we have shown, at least for some cases, they seem not to have the ability to detect changes of conservation interest. CONCLUSIONS: INVENTORIES FOR THE FUTURE In spite of the fact that more resources than ever are now dedicated to monitoring and specially surveying, with the available tools that we have at hand, it is diicult to gain a clear sign in plant biodiversity trends. Explanations to this lack of monitoring patterns are complex, and oten several factors add up to produce non-satisfactory patterns. We can list some of them: Span of monitoring programs: It is almost a general claim that monitoring times are oten too short to be informative. Some monitoring variables are not very sensitive for particular time spans but they become useful if monitoring time increases. For example, there might not be many threat category changes for 5-10 year period but they increase for longer periods, 20 or more years. In relation to demographic variables, it is important to bear in mind that plants may be a particularly resistant taxonomy group in relation to the usual periods of monitored times for this variable type. Longevity is a common trait, and there are also other biological properties contributing to this lack of dire response towards changes such as seed and corm dormancy, very low persistent seedling survival, negative growth or clone growth. herefore, other time scales, diferent than human time scales, are required to clearly ascertain demographic trends afecting plants. In general, monitoring times are in close relation to the variables chosen, and it is highly recommended that previous to any action, we should have a strong understanding of the expected time of response of those variables. Non-informative monitored variables: Some monitoring variables are not very informative or even redundant for plants; this may be the case of variables associated to certain demographic changes if our results are conirmed in the future. hey may require more time and resources, but their results can be even less signiicant than those produced by other monitoring variables with less intensive prospecting. So, in addition to exploring response time, there is a need to study how methods and techniques to collect data are used when demographic variables are selected for the monitoring program. If results are 81 Plant conservation inventories, what we have now and what we need for the future not satisfactory, switching towards other more informative variables may be a more feasible alternative. A clue to efectively identify those variables is to pay attention to factors that are closely related to what is causing plant biodiversity change. herefore, using surrogate monitoring such as those related to land use changes, over-collecting, urbanization rates, etc., oten yield a better indicator of change. Biases afecting variation: here are diferent sorts of biases producing unexpected sources of variation. We can identify bias in space derived from the fact that some territories are over-recorded. his bias may be explained due to proximity of research centers, expected promising lands to plant discovery (mountains, hot spots) or better accessibility, incrementing variation of the low prospecting sites. Bias in time responds to the efect of availability of resources and funding for monitoring surveys, and produces an accumulation of records in good years of monitoring and a scarcity in years when prospecting has been less intensive. Finally, a taxonomic bias should be mentioned. Some particular taxonomic groups are intensively surveyed whereas others are less prone to monitoring. For example Gimnosperm and Magnolidae (usually because they are trees or they are notorious) have more opportunities to be surveyed than, for example, Polygonaceae or Plumbaginaceae (groups that represent plants related to aquatic environments or particularly diicult taxonomic taxa). Identifying and reducing biases should be a prior condition for monitoring programs, and present inventories contain useful information to do both. For example, they may provide targeted areas in under-recorded territories, a solution to rapidly reduce the bias related to space. Current inventories are equally useful to detect new sources of variation. If this new variation turns out to be informative, we can always incorporate it as a new monitoring variable. For example, we may ind out that low inventory efort is a new source of variation in our program. Usually, this variation is linked to some particular habitat types: managed forests, aquatic environments, habitats related to coastal locations exposed to rapid changes due to human activities: sand dunes, maritime scrublands, etc. So, we may target these habitats to gain insight of possible new changes. In short, one possible way to cope with bias and variation is focusing on a section or part of the biota: most threatened plants, bioindicators, plants associated to habitats subject to change, etc. hey will provide a rapid assessment of the biodiversity status. To sum up, we have the ability to identify more informative habitats or plants using information gathered in present inventories. 82 Islands and plants: preservation and understanding of lora on Mediterranean islands Lack of baselines: We have not reached a clear baseline in knowledge yet. his is related to both taxonomy and survey eforts. he efect of taxonomy in biodiversity pattern is complex but clear (Agapow & Sluys, 2005; Knapp et al., 2005; Domínguez Lozano et al., 2007). It is related to species concept, taxonomists’ attitudes and taxonomic efort. In addition, increasing survey efort is still efective in producing new indings about the true status of lora; this is also true for territories theoretically well explored and with long tradition of ield surveys (Ertter, 2000). As results of these two factors, not only we can still expect new species and new population discoveries, but movements in boundaries and status of already known populations as well. Although this can be considered a real merit of good inventory campaigns, it comes as a drawback: there is a lack of clear baselines or past trends to compare with. One possible solution is to incorporate knowledge as another monitoring variable in our system, taking into account the efect of increasing knowledge in the general monitoring trend. Inventory scope: he scope of classic surveying or inventory has usually been too broad (many species) and extensive (large mapping zones). hey produce enormous sets of data, but they also have attached extra variation and bias loads. As a consequence, identiication of trends is blurred. In general, a more focused monitoring program should be recommended. Of course this does not mean that we leave out massive inventories, but produce diferent levels of future monitoring according to needs (Philippi et al., 2001; Marsh and Trenham, 2008). So in simple terms, more informative sites or species will carry a irst level, more intensive, monitoring scheme, and successive groups of plants or sites will require less, secondary level, monitoring. ACKNOWLEDGEMENT his work summarizes thoughts and ideas from many diferent sources involving people from several backgrounds and disciplines. hanks to A. Rebello, R. Bittman, M. Schwartz, J. C. Moreno, K. Atkinson, D. Guzman and F. Tapia. Special thanks to all those who contributed to the development of the Spanish AFA project. Research funding came from a CAM/UCM research project (reference: CCG10-UCM/AMB-4679). Finally the author is grateful to the organizing committee of the 2nd Botanical Conference in Menorca “Islands and Plants: preservation and understanding of lora on Mediterranean islands”, for allowing him to present his ideas on monitoring in a wonderful setting. 83 Plant conservation inventories, what we have now and what we need for the future REFERENCES Bañares, Á., Blanca, G., Güemes, J., Moreno, J.C., Ortíz, S., (Eds.) 2007. Atlas y Libro Rojo de la Flora Vascular Amenazada de España. Adenda 2006., Dirección General para la Biodiversidad-Sociedad Española de Biología de la Conservación de Plantas. AA.VV., 2000. Lista roja de lora vascular española (valoración según categorías UICN). Conservación Vegetal, 6 (extra): 11-38. AA.VV., 2005. Lista roja de la lora vascular de Andalucía. Sevilla, Consejería de Medio Ambiente, Dirección General de Gestión del Medio Natural. Junta de Andalucía. Bañares, Á., Blanca, G., Güemes, J., Moreno, J.C., Ortíz, S., (Eds.) 2008. 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Marrero Gómez, M., Bañares Baudet, A., Carqué Álamo, E., 2003. Plant resource conservation planning in protected natural areas: an example from the Canary Islands, Spain. Biological Conservation, 113: 399410. Knapp, S., Lughadha, E.N., Paton, A., 2005. Taxonomic inlation, species concepts and global species lists. Trends in Ecology & Evolution, 20(1): 7-8. Marsh, M.M., Trenham, P.C., 2008. Current trends in plant and animal population monitoring. Conservation Biology, 22(3): 647-655. Laguna Lumbreras, E., Deltoro, V.I., PerezBotella, J., Perez-Rovira, P., Serra, L., Olivares, A., Fabregat, C., 2004. he role of small reserves in plant conservation in a region of high diversity in eastern Spain. Biological Conservation, 119: 421-426. Moreno Sáiz, J.C. (Coord.) 2008. Lista Roja 2008 de la lora vascular española. Dirección General de Medio Natural y Política Forestal (Ministerio de Medio Ambiente, y Medio Rural y Marino, y Sociedad Española de Biología de la Conservación de Plantas). Laguna Lumbreras, E., Moreno Saiz, J.C., 2000. Génesis y desarrollo de la Lista Roja de Flora Vascular. Conservación Vegetal, 6(extra): 4-5. 86 Islands and plants: preservation and understanding of lora on Mediterranean islands Moreno Saiz, J.C., Domínguez Lozano, F., Sainz Ollero, H., 2003. Recent progress in conservation of threatened Spanish vascular lora: a critical review. Biological Conservation, 113: 419-431. Parker, I.M., Bishop, J.G., 1994. Evaluating approaches to the conservation of rare and endangered plants. Ecology, 75(3): 584-606. Willis J.C., Yule G.U., (1922) Some statistics of evolution and geographical distribution in plants and animals, and their signiicance. Nature, 109: 177–179. Morillo, C., Gómez-Campo, C., 2000. Conservation in Spain, 1980-2000. Biological Conservation, 95: 165-174. Willis, J.C., 1922. Age and Area. A study in geographical distribution and origin of species. Cambridge University Press. Morris, W.F., Doak, D.F., 2002. Quantitative conservation biology. heory and practice of population viability analysis. Sunderland, Massachusetts, Sinauer. Philippi, T., Collins, B., Guisti, S., Dixon, P.M., 2001. A Multistage Approach to Population Monitoring for Rare Plant Populations. Natural Areas Journal, 21(1): 111-116. Possingham, H.P., Andelman, S.J., Burgman, M.A., Medellin, R.A., Master, L.L., Keith, D.A., 2002. Limits to the use of threatened species lists. Trends in Ecology & Evolution, 17(11): 503-507. Rebelo, A.G. 1991. Protea Atlas Manual. Protea Atlas Project, Kirstenbosch. Rodrigues, A.S.L., Pilgrim, J.D., Lamoreux, J.F., Hofmann, M., Brooks, T.M., 2006. he Value of the IUCN Red List for Conservation. Trends in Ecology & Evolution, 21(2): 71-76. Schemske, D.W., Husband, B.C., Ruckelshaus, M.H., Goodwillie, C., 87 Plant conservation inventories, what we have now and what we need for the future 88 2: Western Mediterranean Islands and plants: preservation and understanding of lora on Mediterranean islands 89 he lora of the Balearic Islands 90 Islands and plants: preservation and understanding of lora on Mediterranean islands THE FLORA OF THE BALEARIC ISLANDS Llorenç Sáez1, Pere Fraga2 and Javier López-Alvarado1,3 Unitat de Botànica, Facultat de Biociències, Universitat Autònoma de Barcelona, 08193, Bellaterra, Barcelona, Spain. 2 Consell Insular de Menorca, Pça. Biosfera,5, 07703 Maó, Menorca, Spain. 3 Institut Botànic de Barcelona (CSIC-ICUB), Passeig del Migdia s.n., E-08038 Barcelona, Spain. 1 Abstract We reviewed the data on the diversity (number of native taxa) and the number of Balearic endemics published since the last check-list. Diferences may be attributed to discordant taxonomic criteria, uncertain reports, misapplication of some names, misidentiications of herbarium material and unequal loristic knowledge of the diferent main islands of the Archipelago. he native lora has 1,551 taxa, of which 140 are endemics. We shall discuss some aspects of biogeography and biology of the endemic lora. he number of threatened taxa in the Balearic Islands is 180 (11.6% of all native taxa). he greatest threats to the native lora are direct and indirect results of human activities followed by the overgrazing of goats. he list of protected species should be revised considering that 55.5% of the threatened species, and that almost half (46.1%) of the threatened endemic taxa, are not under legal protection. Keywords: Balearic Islands, native lora, endemism, Mediterranean region INTRODUCTION he Balearic Islands, located at the western part of the Mediterranean Sea, consist of 5 main islands and about 100 small islets. Despite its small size (c. 5,000 km2), the Archipelago does not present a unique lora, since the diversity of environments (salt-marshes, rock-crevices, mountain gullies, temporary ponds, woodlands, scrubs, maritime sands, small islets, etc.) and the signiicant diferences between islands makes for a quite variable composition. his Archipelago has attracted the attention of botanists for more than 4 centuries; Corresponding author: Llorenç Sáez (gymnesicum@yahoo.es) 91 he lora of the Balearic Islands however the irst serious attempts to develop loristic inventories date back from the late 19th century. Although studies on the diversity of vascular plants are numerous, at present there is not a modern and updated review of the lora of the Archipelago. he aim of our study is to update the basic information of the Balearic lora and to examine some characteristics of the endemic and the endangered taxa. MATERIAL AND METHODS he area under study encompasses the Balearic Islands. Following the criteria established by Pla et al. (1992) and Rita & Payeras (2006), we provide data for 6 islands: the Eastern Balearic Islands (Mallorca, Menorca, Cabrera and Dragonera) and the Western Balearic Islands (Eivissa and Formentera). In order to obtain a list of the Archipelago’s native taxa (vascular plants) we have used as our main source the catalogue of Pla et al. (1992). his information has been updated with the information published in recent scientiic publications. Taxa reported as present but considered doubtful, unlikely to be found on the Balearic Islands, or within a speciic island of the Archipelago, have been revised where possible. In our survey, taxa of uncertain systematic value have been excluded and the doubtful reports have been considered invalid if no corroborating voucher specimen or other proof could be found. In addition, sterile hybrids, as several nothospecies of the genus Asplenium, Ophrys, etc., were not considered for purposes of calculating parameters related to the reproductive biology or conservation status. We have considered the endemic species (or subspecies) whose populations occur entirely within the limits of the Balearic Archipelago. For chorological classiication, we have followed the criteria of Bolòs et al. (2005). he classiication of the endemic taxa according to its life form, ecological preferences, pollination mode and seed-dispersal strategy were determined on the basis of published reports, or inferred from plant, lower and fruit morphology, as well as from our ield observations. RESULTS Diversity: number of taxa In the past two decades diferent amounts regarding how many taxa were comprised in the lora of the Balearic Islands have been published (Table 1). he lowest number is about 1,300 species (Bolòs, 1997) and the highest is 2,230 (Travesset, 1999). Between these two extremes, there are diferent approaches concerning the number of taxa constituting the Balearic lora. Our data indicate a remarkable decrease in the number of native taxa regarding the most 92 Islands and plants: preservation and understanding of lora on Mediterranean islands recent studies (Table 1, 2). Diferences among these studies may be attributed to various causes, but are mainly due to: 1) discordant taxonomic criteria: he diferent catalogues of loristic works do not employ the same nomenclature or classiication system for many species (the same entity may occur in these diferent works as a species, a subspecies, a variety, or a synonym); 2) uncertain reports (usually outdated literature references) without voucher specimens; 3) misapplication of some names; 4) misidentiication of existing herbarium material and 5) unequal loristic knowledge of the diferent main islands of the Archipelago. Taxa % endemics 1,650 10.4 Rivas-Martínez et al. (1992) c. 1,500 3 Bolòs (1997) c. 1,300 3.4 Médail & Verlaque (1997) 1,500 12 Travesset (1999) 2,230 7 Rita & Payeras (2006) 1,729 10.0 c. 1,500 8.1 1,551 9.0 Pla et al. (1992)* Rosselló & Castro (2008) Present study** Table 1. Number of plant taxa and % of endemic taxa in the Balearic Islands; *sterile hybrids not included; **sterile hybrids and doubtful taxa not included. Ma Me Ca Dr Ei Fo Pla et al. (1992)* 1443 979 381 106 880 534 Rita & Payeras (2006) 1445 1157 488 335 921 593 Present study* 1302 1090 418 341 876 558 Table 2. Number of plant taxa on each speciic island (Ma: Mallorca, Me: Menorca; Ca: Cabrera; Dr: Dragonera; Ei: Eivissa; Fo: Formentera); * sterile hybrids not included. 93 he lora of the Balearic Islands A total of 440 native taxa (28.4%) from the Balearic Islands are located on any particular island (Table 3). Apart from these genera or groups with high endemicity, it is remarkable that virtually one third (32.4%) of the Balearic pteridophytes are found exclusively on the island of Mallorca, more speciically on the mountain ridge of Serra de Tramuntana. Exclusive taxa Exclusive taxa (endemic species not (endemic species included) included) Nº % Nº % -- -- 440 28.4 Mallorca 189 14.5 242 18.6 Menorca 124 11.4 137 12.6 Cabrera 3 0.7 4 0.9 Dragonera 1 0.3 1 0.3 Eivissa 39 4.4 49 5.6 Formentera 10 1.8 11 2.0 Balearic Islands Table 3. Number of taxa that occur only on a particular island of the Balearic Archipelago. Regarding the unequal loristic knowledge of the diferent main islands of the Archipelago, here we provide information on the number of publications and loristic novelties for each island since the publication of the most recent check-list (Pla et al., 1992). Floristic inventory with unequal intensity, at diferent times (Fig. 1), with diferent systematic criteria, determines some notable diferences at loristic levels between islands. 94 Islands and plants: preservation and understanding of lora on Mediterranean islands Fig. 1. New taxa for the Balearic Islands/year between 1993 and 2010. Alien, hybrids and doubtful taxa are not included. New records for a particular island that do not represent new taxa for the Archipelago are also not included. he analysis of phytogeographical composition of the Balearic lora showed that 61.9% of the species are Mediterranean plants. he Pluriregional group is represented by 32.6% of the species, which form a diverse group in terms of their geographic origin, and the Euro-Siberian component is represented by 5.4% of the taxa. his element is mainly represented on the higher mountains of Mallorca. he percentages for these three elements are very similar to those reported by Bolòs (1997) and Rita & Payeras (2006). It is well known that the percentage of Tyrrhenian taxa is higher in the Gymnesian, whereas the taxa distributed through the Eastern Iberian Peninsula and the Balearic Islands are more frequent on the Pityusic Islands (Fig. 2). 95 he lora of the Balearic Islands Fig. 2. Number of taxa endemic to the Balearic Islands (black); endemics restricted to each island (dark grey); Tyrrhenian taxa (light grey) and taxa distributed through the Eastern Iberian Peninsula and the Balearic Islands (white). Endemic taxa and their characteristics he endemic element, although subject of numerous studies and considered as relatively well known, is also subject to divergent interpretations from a quantitative point of view. hus, it is considered that the percentage of endemic taxa ranges between 3% (Rivas-Martínez et al., 1992) and 12% (Médail & Verlaque, 1997). According to our data (updated in February 2013) the endemic taxa (i.e. taxa strictly localized in the Balearic Islands) represent 9.02% of the indigenous lora of the Archipelago (Table 4). Most likely, the percentage of endemic species would increase if studies were conducted in poorly known groups; however, on the other hand, detailed systematic studies sometimes have revealed the existence of alleged endemic Balearic populations in other areas, as in the case of Allium ebusitanum Font Quer (Aedo, 2006). Hybridization is a common and important evolutionary process that can create new species (Rieseberg et al., 1995), among other biological consequences. Nevertheless, as noted above, we have not included the hybrid taxa (usually sterile and not apomictic) that do not constitute populations. Some hybrid taxa are easily morphologically characterized (hybrids between species of Ophrys, Orchis or Asplenium species, among others), and some are endemic (Viola x 96 Islands and plants: preservation and understanding of lora on Mediterranean islands balearica, Rhamnus x bermejoi, several Asplenium nothotaxa, etc.), but in many cases these plants can be fertile (Helichrysum, Teucrium, Limonium) and it is not easy to conirm their hybrid nature and are even frequent backcrosses, which makes the inventory of these hybrids extremely complex and of doubtful utility in order to compare patterns of biodiversity or establish conservation status according to IUCN (2001) criteria. Pla et al. (1992)* Rita & Payeras Present study** (2006) Nº % Nº % Nº % Balearic Islands 172 10.4 173 10.0 140 9.0 Mallorca 122 8.5 125 8.7 103 7.9 Menorca 58 5.9 60 5.2 54 4.9 Cabrera 27 7.1 30 6.1 23 5.5 Dragonera 8 7.5 29 8.7 23 6.3 Eivissa 45 5.1 44 4.8 33 3.7 Formentera 22 4.1 23 3.9 17 3.0 Table 4. Number and % of endemic taxa on the Balearic Islands; * sterile hybrids not included; ** sterile hybrids and doubtful taxa not included. he diferences in percentage of endemic species in recent studies (Tables 1 and 4) close in time may be due to several reasons: 1) discordant taxonomic criteria, 2) inclusion, in the number of endemic species, taxa of unconvincing taxonomic status, and 3) failure to clearly establish what is an endemic plant of the Balearic Islands: in most recent studies [with the exception of Rita & Payeras (2006)], generally not strictly endemic taxa (Tyrrhenian, taxa also present in the Iberian Peninsula and Southern France, or other territories) are included in the group of endemic species. he criteria adopted here is that an endemic species of the Balearic Islands is a taxon whose distribution area is restricted to this Archipelago. Some studies have included in the group of endemic plants several Tyrrhenian and Western Mediterranean elements that some authors recognize as sub-endemics. A critique to this addition is based on the fact that the boundary area to recognize when a plant is sub-endemic is 97 he lora of the Balearic Islands not unequivocally established. It seems reasonable that if we wish to recognize this heterogeneous and difuse group of sub-endemics, it is necessary to specify objective (and reviewable) criteria to identify them positively, as has been suggested in other nearby continental areas (Sáez et al. 2010). Until we reach a consensus on this issue, it seems that the most consistent objective and least problematic solution is to restrict the concept of endemism to those plants actually endemic to the Balearic Islands. he ive families with the largest number of endemic taxa are the same as indicated by Rita & Payeras (2006): Plumbaginaceae, Leguminosae, Compositae, Labiatae, and Umbelliferae. he endemic taxa of these families represent more than half (51.1%) of the endemic taxa. 81 endemic taxa (57.8% of all the Balearic endemics) are restricted to a single island. he number of endemic species restricted to an island could be higher (87 taxa, 63.0%), if we do not recognize the island of Sa Dragonera as independent, since it could be considered an extension of the Serra de Tramuntana in Mallorca. In fact, if Sa Dragonera is recognized as an independent island in order to establish patterns of distribution and endemism, perhaps it would also be desirable to include islands of major biogeographic singularity like Es Vedrà (of of southwestern Eivissa). Possibly the best solution is to limit this type of analysis in the future to the ive major islands of the Archipelago. In the Balearic Islands, the endemic species occur in rocky areas, clifs and screes (35.5% --excluding maritime rock-crevices--), shrubby habitats and forest edges (28.2%), coastal ecosystems (24.0%), grasslands and open habitats (10.1%) and wet areas (2.2%). Almost half of the endemic species (44.9%) are located in mountain communities, most of which (58.1%) colonize rocky habitats. he diferences between the Eastern Balearic Islands and the Pityusic Islands regarding the composition, diversity and relationships of their endemic loras have been highlighted by diferent authors (Bolòs, 1997; hompson, 2005). he Eastern Balearic Islands have a signiicantly more diverse endemic lora: 120 endemic taxa (105 of which are exclusive), whereas in the Pityusic Islands there are 35 endemic taxa, 20 of which are restricted to this subarchipelago. Endemic taxa shared between Eastern Balearic Islands and Pityusic Islands are scarce (15 taxa, 14.5%). High endemism is a feature that characterizes mountain ecosystems, especially those of islands (Steinbauer et al. 2012). In the Balearic Islands, mountain areas have the highest rates of endemism, as indicated for other Mediterranean islands (hompson, 2005). Within the Balearic Islands, the 98 Islands and plants: preservation and understanding of lora on Mediterranean islands highest level of endemism is observed on the Serra de Tramuntana: 80 taxa (57.1% of all the Balearic endemics) occur in this area that contains more endemic taxa than any other among the islands of the Archipelago. A quarter (25.0%) of the Balearic endemics are restricted to this mountainous area. In the case of the mountain areas of Mallorca, endemic taxa with Eurasiatic or non-Mediterranean ainities are limited. Whether these mountainous areas experienced an impoverishment of lora as intense as has been suggested for other high mountains of large Mediterranean islands (hompson, 2005) is a question that remains to be determined. With regard to life form, almost half of the Balearic endemic taxa are chamaephytes (44.3%), which is a high percentage but similar to other areas of the Mediterranean region. he hemicryptophytes represent about a quarter of the total endemic taxa (25.7%). It is remarkable the relatively high percentage of nanophanerophytes (11.4%), by contrast, the rate of therophytes, one of the most abundant life forms in the lora of the Mediterranean basin (Quézel, 1995) is considerably low (10.7%). he geophytes represent 7.9% of the endemic taxa. hese data are somewhat diferent from those provided by Rita & Payeras (2006), probably due to discordant taxonomic criteria regarding the endemic element (these authors admit that several taxa of doubtful taxonomic value were included), but in any case, the spectrum of life forms of the endemic lora strikingly difers from that of the whole of the Balearic lora. he information on the reproductive biology of endemic species is still scarce, both in the Balearic Islands and the rest of Mediterranean islands (Travesset, 1999). According to this author, 90% of the endemic taxa have showy lowers, suggesting biotic pollination. Our preliminary results conirm the data provided by Traveset (1999) and indicate that biotic pollination is clearly a major feature (94.2%) in endemic taxa. However, this percentage includes taxa which have been conirmed as ambophilous and others most likely to be included in this group (such as numerous species of the genus Limonium). According to Rosselló & Castro (2008), 100 of the 121 endemic taxa (82.6%) show non-apomictic reproduction (82.8%). Our results (82.9%) of the endemic taxa show non-apomictic reproduction) are very similar to those reported by these authors, who provide detailed information about the karyological evolution of the sexually-reproducing angiosperm endemic lora of the Balearic Islands. With regard to dispersal mechanisms, 86.4% of the endemic taxa use abiotic means of dispersion, with the majority of barochorous/semachorous system. On the other hand, 13.6% of the Balearic endemics present adaptations to biotic 99 he lora of the Balearic Islands dispersion, being endozoochory the most frequent in this group of zoochorous plants and represents 6.5% of all endemic taxa, a proportion somewhat lower than indicated by Travesset (1999). Most (55.6%) of these endozoochorous taxa correspond to nanophanerophytes. hreatened species Several taxa in the Balearic Islands are on the brink of extinction. heir threats have been assessed according to the criteria of the International Union for Conservation of Nature (IUCN, 2001). he number of threatened taxa (Extinct in the Wild, Regional Extinct, Critically Endangered, Endangered and Vulnerable) in the Balearic Islands is 180 (11.6 % of all native taxa). Among these endangered taxa, 32 were not included in the Red Data Book (Sáez & Rosselló, 2001). Among Balearic threatened species there are 63 taxa (35%) that are endemic to the Archipelago. It is noteworthy that although the number of taxa assigned to the Data Deicient category has declined since 2001 (Fig. 3), as a result of improved knowledge of rare and potentially threatened species, this percentage remains relatively high (10.2% of native lora). Also noteworthy is the signiicant increase in the number of Critically Endangered species, as a result of: 1) the discovery of new taxa hitherto unknown in the Balearic Islands (especially in Menorca), and 2) as a result of the reassessment of the categories assigned in 2001. Fig. 3. Number of taxa assigned to the IUCN category (2001): Regional Extinct (RE), Extinct in the Wild (EW), Critically Endangered (CR), Endangered (EN), Vulnerable (VU), Near threatened (NT), Data Deicient (DD). 100 Islands and plants: preservation and understanding of lora on Mediterranean islands We quantiied the threats facing all threatened species (180 taxa) (Fig. 4). Factors inherent to the species such as reproductive problems, limited dispersal, etc. have not been considered in this analysis. he greatest threats to the native lora result directly and indirectly from human activities. Urbanization [including infrastructures] is the most prevalent threat (32.6%), followed by overgrazing [mainly due to goats] (26.9%), human disturbance [pollution, degradation, trampling, collection, etc.] (16.8%), native species interactions [competition, hybridization, etc.] (15.2%), stochastic events [ire, drought, storms, etc.] (6.3%) and introduced species (2.2%). Figure 4. he percentage of threatened species by urbanization and infrastructures (UR), overgrazing (OV), human disturbance (HD), natural causes (NC), stochastic events (SE) or introduced species (IS). Currently, 80 species of vascular plants are legally protected in the Balearic Islands. Accordingly, the list of protected species should be revised considering our results as 55.5% of the threatened species are not under legal protection. Of these 80 protected species, 56 (70%) are actually endangered according to IUCN (2001) criteria, 42 species (52.5%) are endemic and 34 (42.5%) are threatened endemic species. his means that almost half (46.1%) of the threatened endemic taxa are not protected. he most endangered Balearic endemic species must be considered as priority taxa in conservation strategies. In the Balearic Islands, unlike other Mediterranean islands, where the mountain lora is in relatively 101 he lora of the Balearic Islands low danger (Médail & Verlaque, 1997), the most endangered Balearic endemic species are localized in a wide range of altitudes, from sea level to the highest peaks, but it is certainly on coastal areas where a high number of threatened species concentrate, mainly of the Limonium genus. As knowledge of the lora of the Balearic Islands imporoves, especially with regard to endangered species, it will be possible to update the Red List (or Red data book) in the future. hese lists, together with speciic studies to analyze population viability, will help to ill some gaps and inconsistencies in the Balearic List of Endangered Species. REFERENCES de les illes Balears. Universitat de les Illes Balears, Jardí Botànic de Sóller. Palma de Mallorca. Aedo, C. 2006. Is Allium ebusitanum (Alliaceae) an endemic species from Ibiza? Anales del Jardín Botánico de Madrid, 63(2): 121-130. Quézel, P. 1995. La lore du bassin méditerranéen: origine, mise en place, endémisme. Ecologia Mediterranea, 21: 1939. Bolòs, O. 1997. La vegetació de les illes Balears. Comunitats de Plantes. Arxius de la Secció de Ciències CXIV. Institut d’Estudis Catalans. Barcelona. Bolòs, O., Vigo, J., Masalles, R.M., Ninot, J.M. 2005. Flora Manual dels Països Catalans. Ed. 3. Edicions 62. Barcelona. Rieseberg L.H., van Fossen, C., Desrochers, A, 1995. Hybrid speciation accompanied by genomic reorganization in wild sunlowers. Nature, 375: 313-316. IUCN. 2001. IUCN Red List Categories: Version 3.1. IUCN Species Survival Commission. IUCN, Gland & Cambridge. Rita, J., Payeras, T. 2006. Biodiversidad de las plantas vasculares de las Islas Baleares. Orsis, 21: 41-58. Médail, F., Verlaque, R. 1997. Ecological characteristics and rarity of endemic plants from southeast France and Corsica: Implications for biodiversity conservation. Biological Conservation, 80: 269-281. Rivas-Martínez, S., Costa, M., Loidi, J. 1992. La vegetación de las islas de Ibiza y Formentera (Islas Baleares, España). Itinera Geobotanica, 6: 99-236. Rosselló, J.A., Castro, M. 2008. Karyological evolution of the angiosperm endemic lora of the Balearic Islands. Taxon, 57: 259-273. Pla, V., Sastre, B., Llorens, L. 1992. Aproximació al catàleg de la lora vascular 102 Islands and plants: preservation and understanding of lora on Mediterranean islands Sáez, L., Rosselló, J.A. 2001. Llibre Vermell de la lora amenaçada de les Illes Balears. Conselleria de Medi Ambient. Govern de les Illes Balears. Palma de Mallorca. Sáez, L., Aymerich, P., Blanché, C. 2010. Llibre Vermell de les plantes vasculars endèmiques i amenaçades de Catalunya. Argania editio. Barcelona. Steinbauer, M.J., Otto, R., Naranjo-Cigala, A., Beierkuhnlein, C., Fernández-Palacios. J.M. 2012. Increase of island endemism with altitude–speciation processes on oceanic Islands. Ecography, 35: 23-32. hompson, J.D. 2005. Plant Evolution in the Mediterranean. Oxford University Press. Travesset, A. 1999. El paper dels mutualismes planta-animal als ecosistemes insulars. Monograies de la Societat d’Història Natural de les Balears, 6: 9-33. 103 he lora of the Balearic Islands 104 Islands and plants: preservation and understanding of lora on Mediterranean islands MANAGING THREATENED PLANTS ON ISLANDS: TASKS & PRIORITIES Eva Moragues and Joan Mayol Government of the Balearic Islands. Ministry of Agriculture, Environment and Territory. Species Protection Service. C/ Gremi Corredors, 10 1er (Polígono de Son Rossinyol), 07009, Palma de Mallorca, Balearic Islands Abstract he geographical isolation of the Balearic Islands has facilitated the development of a singular and endemic lora unique to the islands. Part of this lora is seriously threatened in small and very fractioned populations with few individuals. he Administration has the obligation to protect, conserve and improve both their habitat and the species themselves, which requires two basic tools: legislation and management. For ive years, the Balearic Government, under the legal support of Conservation and Recovery Plans, has performed management actions to conserve species under the highest category of threat. To date, our government has approved 5 recovery plans, 2 conservation plans and 1 management plan that include the protection of a total of 23 plant species. he main conservation actions carried out are: (1) demographic monitoring of the populations, (2) exploration to discover new locations, (3) remove pressure from herbivores and provide physical protection to threatened species, (4) control of competing plant species afecting the threatened lora, (5) reinforcement / translocation of endangered plant specimens in the wild, (6) actions such as collecting seeds for botanical gardens and seed banks and (7) campaigns to raise awareness. he purpose of this paper is to present the initial results from the adoption of the irst plan in mid-2007. Keywords: Management, conservation, endangered species, habitat restoration, reinforcement. Corresponding author: Eva Moragues Botey (emoragues@dgcapea.caib.es) 105 Managing threatened plants on islands: tasks & priorities INTRODUCTION Plants are essential for living. hey are the basis of the rest of our biodiversity. he loss of plants, a substantial part of our natural heritage, must be prevented, especially when they are endemic: the disappearance of an endemic species is deinitive and irreversible. Current threats to the planet’s biodiversity are unprecedented, and they particularly imperil insular loras (Caujapé-Castells et al., 2010). he inevitable fate of all species to extinction is particularly evident on islands. his island’s vulnerability is related to the low number of populations and its small size. he Balearic Islands (4986.7 km2) are in the middle of the Western Mediterranean basin where about 1,730 native wild taxa make their home, 52% with Mediterranean distribution (Rita and Payeras, 2006). hey are the most isolated islands in the Mediterranean, both in distance to mainland and in age of isolation. he number of taxa strictly endemic to the Balearic Islands is 173 (130 excluding the genus Limonium Mill.), representing 10% of the total number of taxa. he proportion of endemic lora for Balearic native lora is found at the high end of our Mediterranean environment: 5.3% Corsica, 10% Crete, 7% Cyprus, 6.3%Sardinia and 10% Sicily (Rita and Payeras, 2006). Balearic lora is strictly protected under European, national and local laws that care for conservation and management measures. here are a total of 87 vascular species protected in diferent categories of protection depending on the degree of threat or socio-economic needs. he main standards of protection are (1) “Real Decreto 139/2011, de 4 de febrero, para el desarrollo del Listado de Especies Silvestres en Régimen de Protección Especial y del Catálogo Español de Especies Amenazadas (BOE 46, 23rd February 2011), to develop some of the contents of the law, Ley 42/2007, 13th December, del Patrimonio Natural y de la Biodiversidad and (2) “Decreto 75/2005”, 8th July, por el cual se crea el Catálogo Balear de Especies Amenazadas y de Especial Protección, las Áreas Biológicas Críticas y el Consejo Asesor de Fauna y Flora de las Islas Baleares”. BOIB 106, 16-07-2005. his legislation establishes conservation tools such as recovery plans or management instruments that identify threats, objectives and conservation actions to promote the stability or the increase of endangered species. he Balearic Government has approved ive recovery plans, two conservation plans and one management plan that include the protection of a total of 23 plant species. he purpose of this paper is to present the initial results from the adoption of the irst plan in mid-2007. 106 Islands and plants: preservation and understanding of lora on Mediterranean islands Main goal: To ensure the long-term survival of endangered species of the natural environment reducing their vulnerability, and to ensure the maintenance of biological material genetically representative ex situ, in anticipation of a possible collapse in nature. For more information you can visit our website http://especies.caib.es MANAGEMENT ACTIONS he Balearic Government has approved eight plans of lora (Table 1). his represents 53% of the listed threatened species. Although in fact, our Species Protection Service actually works, directly or indirectly, on the conservation of 47 plants under some degree of threat. Table 1. Species linked with Plan. RP: Recovery Plan; CP: Conservation Plan; MP: Management Plan. *Oicial Gazette of the Balearic Islands. All these plans involve a unique species except two of them: (1) Conservation threatened species Plan of Puig Major with 31 protected or endangered species and (2) 5 endemic Limonium Recovery Plan of Calvià (L. magalluianum Llorens, L. boirae Llorens & Tébar, L. ejulabilis Rosselló, Mus & Soler, L. inexpectans Sáez & Rosselló and L. carvalhoi Rosselló, Sáez & Carvalho). hese last two species have a very low number of individuals in their natural habitat. he conservation status of Puig Major species is unequal, but they sufer a series of threats that are common in many cases. he species in alarming danger of extinction on Puig Major are: Agrostis barceloi Sáez & Rosselló, and the “turbit” (Ligusticum huteri Porta). Both are catalogued under the maximum degree of 107 Managing threatened plants on islands: tasks & priorities protection (in danger of extinction) in the Balearic Catalogue of hreatened Species and Species of Special Interest (Decree 75/2005). he Chaenorhinum rodriguezii (Porta) Sáez & Vicens is classiied as vulnerable in the Red Book of Vascular Flora of the Balearic Islands: all three species are endemic of Majorca. And soon, in 2013, the Cotoneaster majoricensis L. Sáez & Rosselló, another endemic species, will also be classiied as in danger of extintion. In Puig Major, we also have the presence of species with a wider distribution in Europe and the Western Mediterranean that are endangered in the Balearic Islands. Some of these are included in the Red Book of Vascular Flora of the Balearic Islands: Cystopteris fragilis (L.) Bernh. subsp. fragilis, Dryopteris tyrrhena FraserJenk. & Reichst., Dryopteris ilix-mas (L.) Schott and Hieracium amplexicaule L., in the critically endangered category; and Polystichum setiferum (Forssk.) Woynar, P. aculeatum (L.) Roth, Rosa squarrosa (A. Rau) Boreau and Colchicum lusitanum Brot. in the endangered category. he Puig Major Conservation Plan is specially focused to this group of the 2 most endangered species and directly and indirectly beneits the other 19. he priority to preserve endemic species and conserve species in the periphery of their range are very diferent, but if the measures applied are the same and have an efect on both groups of plants, the debate can be concluded. Main conservation actions on threatened plants associated with recovery, conservation and management plans: (1) demographic monitoring of the populations, (2) exploration to discover new locations, (3) removal of pressure from herbivores and providing physical protection to threatened species, (4) control of competing plant species afecting the threatened lora, (5) reinforcement / translocation of endangered plant specimens in the wild, (6) actions such as collecting seeds for botanical gardens and seed banks and (7) campaigns to raise awareness. MAIN THREATS TO ENDANGERED SPECIES Destruction and loss of habitat he limiting factor for many threatened species is habitat availability. he destruction or degradation of suitable and potential habitats is one of the main threats to the survival of many species, especially with species with rare and restricted distribution. Occupation, changes in land use and alien species introduction are the main causes of changes in nature. In the Balearic Islands the most vulnerable habitats are wetlands and coastal areas, both rich in endemic and rare species. Examples of protected plants are Apium bermejoi Llorens and Euphorbia margalidiana Kuhbier & Lewej. (both coastal plants) due to a lack 108 Islands and plants: preservation and understanding of lora on Mediterranean islands of habitats, and Vicia bifoliolata J. J. Rofr. and endemic Limonium (coastal and wetland respectively) due to degraded habitats. Climate change he vegetation of Puig Major, the highest mountain in Majorca, is the most important biological heritage of our islands as a whole. We have a clear example of plants adapted to a special microclimate in those that live in the highest peaks of the Serra de Tramuntana range, especially in the Puig Major. Here, the unique and rare endemic vegetation inds refuge at the highest levels, on small ledges, in hollows, channels and issures in the clifs, where exposure to sunshine is low and therefore it is rather humid. hese species have very limited distribution with few specimens, and live in isolated, highly localized areas and in very speciic environmental conditions. hese mountains also shelter some relict trees as evidence of cooler and more humid ages, such as the common yew (Taxus baccata L.) and holly (Ilex aquifolium L.), or deciduous trees such as the maple, whitebeam (Sorbus aria L.), snowy mespilus (Amelanchier ovalis Medik.) and the Pyrenean honey suckle (Lonicera pyrenaica subsp. majoricensis (Gand.) Gand.), whose growth depends on herbivores. Puig Major is also an important refuge for mountain and northern bryophytes (mosses and liverworts), which are very rare on Mediterranean islands. his plant stronghold is seriously threatened by climate change, which could afect its survival and even lead to inexorable extinction. An increase in temperatures or a decrease in precipitation would bring about an increase in the altitude of the habitats that these extraordinary plants require to live, and there are no more islands. If the climate becomes drier, they go up, and the aridity will progressively swallow up this life and will destroy this age-old refuge, without us being able to do very much to save the lora on Puig Major. Historically, climate has not been stable, and the island has gone through periods of drought, aridity, or humidity and snow much more prolonged than today. Nevertheless these species have survived. What is currently taking place is quite noteworthy, and the Puig Major’s plan includes a detailed monitoring of species in order to create a biological and demographic database that can identify the trends of the species. Predation Climate change is not the only problem yet. he main and most serious threat is posed by the pressure of herbivores (goats and sheep) that devour shoots, leaves, lowers, fruits and tender seedlings, destroying natural regeneration and promoting the aging of the species of highest interest. 109 Managing threatened plants on islands: tasks & priorities he loristic structure and composition of the Serra de Tramuntana range is conditioned by the pressure of herbivores, which are too numerous (goat average: 0.32 individuals / hectare, with approximately, 28,000-35,000 goats living in Serra de Tramuntana). his extreme pressure, mainly exerted by goats, favors the presence and predomination of certain plant species, many of which are thorny or poisonous, and severely limits the existence of the species that serve as food. his is why the landscape would be diferent without this excess of herbivores and we would certainly be able to enjoy a lora not only more in consonance with the climate but also more plentiful and varied than at present. he plants that now live on inaccessible clifs and crevices or are well protected among thorny shrubs could establish themselves and grow in any ecologically suitable habitat. Other types of predators are also found, such as phytophagous insects (on Apium bermejoi, Vicia bifoliolata and endangered Limonium), rabbits and small rodents. But we must not forget that this happens under a scenario of excessive grazing pressure. In fact, our lora has evolved under the moderating inluence of certain native herbivores like Myotragus Bate spp., now extinct. And now these herbivores’ excess is due to the progressive abandonment of farming that has led to an uncontrolled increase of goats and even feral sheep. hat said, some degree of herbivores is tolerable and even necessary for our lora, or for some rare endangered species such as Naufraga balearica Constance & Cannon. Intrinsic factors his aspect is common in most threatened species. Low population densities, some signiicant luctuations in the number of individuals and small distribution range are determinant of vulnerability. Also the lack of knowledge on the vectors of pollination, the viability of lowers and seeds, the capacity of germination and new specimen survival, are factors to consider in management actions. he lack of new speciments or juveniles is also quite signiicant. Normally, populations of threatened species have problems with viable fruit formation or survival of seedlings is very low. Exotic plants According to the IUCN, alien species are the second leading cause of biodiversity loss, following habitat destruction. he entry of exotic species is due largely to habitat degradation and the opening of ecological niches. We not only have problems with the introduction of exotic species such as Carpobrotus N. E. Br. spp., but also with the introduction of indigenous species previously 110 Islands and plants: preservation and understanding of lora on Mediterranean islands not present in the habitat of threatened species. For example Lactuca serriola L. and Brachypodium sylvaticum (Huds.) Beauv. living with Colchicum lusitanum, a Western Mediterranean species that in the Balearic Islands only lives on top of Puig Major. Or the enormous growth of Primula acaulis subsp. balearica (Willk.) Greuter & Burdet on Agrostis barceloi, endemic and endangered to the Puig Major. he proliferation of these native plants is due to the total elimination of herbivores. he debate is open… Potential threats Plants restricted to very small areas may be at higher risk of extinction due to natural catastrophes (Caujapé-Castells et al., 2010). Devastating natural events like storms, ire, water impact, an episode of prolonged drought or other phenomena could extinguish the natural population of the species, as can changes in land use (tourism, motocross, roads and highways), and hybridization can threaten the genetic identity of the species. Coastal species like Euphorbia margalidiana is highly vulnerable to stochastic littoral events and the Limonium species to hybridization. Pinus pinaster Aiton is also vulnerable to ire, as could be seen in the summer of 2006, and the stoloniferous Apium bermejoi to prolonged drought periods. Deleterious genetic consequences related to small population size can impede population responses to sudden environmental shits including competition from invasive alien species, the inluence of population size on the genetics and reproduction of insular endemics, a major concern to conservation (Caujapé-Castells et al., 2010). MAIN RESULTS Increasing populations and individuals Increasing both the density and distribution of species is the main objective in threatened species management. When applying diferent conservation plans, we realized that this issue can be caused either by lack of initial information or by plant intrinsic characteristics or by the lack or destruction of habitat. An example of insuicient information is the case of Vicia bifoliolata. Over three years of development, its Recovery Plan has made signiicant advances in knowledge of this species in diferent areas. Possibly the most notable has been those related to their chorology and determination of its efectives. An exploration efort of the natural environment has resulted in a larger area of distribution and density of individuals in previously known areas. he number of individuals has increased from hundreds to thousands. his fact suggests a new and lower conservation status classiication. In fact, in the new national catalog this species was under the endangered label and has been reduced 111 Managing threatened plants on islands: tasks & priorities to vulnerable, a more minor category of threat. Another example of lack of information is the species Femeniasia balearica (Rodr.) Susanna. he irst action in obtaining knowledge of this species, apart from natural seed collection, is the development of a comprehensive mapping, which recently has inished. Comparing the results of the population density conducted in 2003 and 2011, two Femeniasia populations have about the same adults plants number, while the population of Mongrofa-Favàritx has experienced a considerable growth going from 390 to 1.065 plants. One of the main actions carried out to increase the number of individuals in natural areas are reinforcement and translocation (Table 2). he actions carried out with Pinus pinaster in Minorca are a clear example of an artiicial increase of individual numbers. his widely distributed pine species presents an interesting conservation issue because in 2006 a molecular study revealed population genetic diferences between the Minorcan and the Iberian populations, and its oriental ainity (Tyrrhenian islands). he original population of 12 individuals described in 2003 was completely destroyed in the summer of 2006 by a ire. hanks to a reinforcement demographic action made the year before the ire, the original population still lives on. But the results are not as positive as we would like: currently, only 37 pines out of the 197 planted still survived ater just four years in the original population. Survival values were also low in the proceedings of translocation or creation of new populations. In four years, four new populations were created, but only few specimens survived. hese new populations were very recently created and we cannot ensure their viability. In total 100 specimens were planted, 15 of which are still alive (Fig.1). his high mortality rate was due to natural growth of two pathogenic fungi (Pythiyum sp. and Diplodia) that destroyed much of the original and translocated population. Excessive rainfall and high temperatures favored the development of these fungi that attacked the pines at root and shoot. However, adding the action of reinforcement and translocations, the population of Pinus pinaster was quintupled since its discovery (Minorcan population has grown from 12 to 54 individuals). he same happened with Apium bermejoi, also endemic to Minorca. Five new populations were created and the number of individuals has been nearly quadrupled. here are 32 individuals in the original population and 102 in the ive newly created ones (Fig.1). hese conservation eforts have also been made with the Yew (Taxus baccata), whose specimen count has increased by 50% with the creation of ive new locations and the strengthening of two others (Table 2). 112 Islands and plants: preservation and understanding of lora on Mediterranean islands Species Pinus pinaster Apium bermejoi* Euphorbia margalidiana Taxus baccata Limonium barceloi Limonium inexpectans Limonium carvalhoi Num. original population 1** 1** 1 10 4 1 1 Translocation Num. of Num. new Nº of Total num. individuals populations individuals of populations 37 4 15 5 32 5 102 6 700 1 131*** 2 603 5 + 2** 395 15 7,616 1 115 5 132 0 244 1 100-150 0 244 1 Total num. of individuals 52 134 ±831 998 7,731 376 344-294 Table 2. Number of original and translocated populations and data for individuals.* Patches, not individuals. ** Reinforcement population. *** Only 15 are reproductive plants. 2013 data. Fig. 1. Demographic trends for some species during the years of study. a) Apium bermejoi: represents the number of patches, not individuals. b) Pinus pinaster: all increases are due to artiicial planting. A = Reinforcement of natural population; B = Original + new populations; C = Fire that killed all natural individuals plus some reinforcement; D = Root fungus that killed part of the original population and the 77 individuals of a new one. c) Limonium barceloi. *Number of individuals ater the artiicial lood episode that killed 68% of the population. d) Limonium inexpectans. Conservation actions began in 2008. 113 Managing threatened plants on islands: tasks & priorities Euphorbia margalidiana is a particular case of lack of habitat. It is an endemic plant of Ibiza where its population is restricted to only a small island of less than 2 hectares (Ses Margalides). It is theoretically highly vulnerable to stochastic events, despite its good condition with an excellent population size (± 900 individuals). In 2005 a process of creation of an artiicial population of this plant on a small island named Murada commenced. Its habitat is similar to the original population in Ses Margalides and located nearby. Little by little a population on the new island, Murada, has been gaining strength. Now 15 reproductive individuals and 116 seedlings survive. he Conservation Plan of Puig Major hreatened Flora is one of the most ambitious plans in terms of recovery and monitoring of both species and habitat. Among the rarest and most unusual of all the endemic species of plants in the Balearic Islands are the locally named “turbit” (Ligusticum huteri) and the grass Agrostis barceloi. hey only live at the top of the highest mountain in Majorca, the Puig Major. he most important conservation action in this area is to reduce grazing pressure on the most endangered plants. Plants have been protected with exclusion fences, or individually protected with wire fencing and barbed wire. All the specimens of Ligusticum barceloi are protected this way, as well as about 71 natural yew trees (Taxus baccata). Caves have also been protected, ledges with Agrostis barceloi, as have meadows of the utmost value at the foot of clifs and even the most important ferns. From the begining of the conservation plant our Service staf carried out the reinforcement of populations (by planting vegetative specimens), in terms of number of specimens of those incurred to date. See the Conservation Plan of Puig Major hreatened Flora main results in Table 3. Agrostis barceloi* Chaenorhinum rodriguezii Colchicum lusitanum Cystopteris fragilis subsp. fragilis Dryopteris tyrrhena** Hieracium amplexicaule Ligusticum huteri Cotoneaster tomentosus Polystichum aculeatum** Orchis cazorlensis Polystichum setiferum** Rosa squarrosa 2007 36 5(3) 3 28 plants 0(3) 64(3) 34(13) 32(15) plants 0 25(12)plants 24 2008 1255 50(20) 100 41 281 3(2) 135(2) 44(11) 230(93) 0 381(137) 34(10) Specimens 2009 2010 996 830 31(26) 93(86) 116 152 50(39) 67(54) 430(329) 408(289) 14(7) 14(4) 135(12) 209(5) 61(14) 61(15) 245(103) 290(141) 0 0 432(201) 671(465) 35(10) 45(12) 2011 1.719 128(51) 0 70(59) 411(308) 35(3) 229(13) 74(16) 304(132) 0 694(479) 49(22) 2012 383 221(56) 19 312(211) 391(287) 29(10) 221(2) 91(15) 281(122) 11 680(455) 47(15) Table 3. Puig Major’s threatened species. * Number of lowers stems. ** Number of fronds. () Reproductive individuals. he double line indicates the beginning of the conservation actions. 114 Islands and plants: preservation and understanding of lora on Mediterranean islands We also carried out several population reinforcement actions on tree species of conservation interest (Acer opalus Mill. subsp. granatense (Boiss.) Font Quer & Rothm., Ilex aquifolium and Taxus baccata) at the top of Puig Major. he status of the plants of these species is quite satisfactory. Hence, ater rapid and remarkable growth, it is expected that in the medium term there will be an important change in the physiognomy of the vegetation of this area, currently dominated by clumps of Ampelodesmos mauritanica (Poiret) T. Durand et Schinz. We also have an example of regional extinction in the environment; the male fern (Dryopteris ilix-mas), native to northern Europe and Asia, was only found in Majorca in a shaded deep issure on the Puig Major Mountain, but has not been seen for the last ten years. he cause of its disappearance remains unknown. Spores of a single male fern that lives in the Botanical Garden of Sóller were collected and germinated, thanks to the collaboration of the forest garden of Menut. We have obtained ive plants (sporophytes) that were introduced into their natural habitat, and to date only one is alive. he remains of two degraded wetlands with Limonium endemic species exist in the south of Majorca. In both habitats, we planted specimens of the more threatened Limonium near their natural populations (Table 2). he increase of individual population of Limonium inexpectans is due to the recruitment of new individuals. Most of the population consists on juveniles. Habitat restoration Some habitat restoration actions are essential to the survival of our threatened species. Ater the ire in the original population of Pinus pinaster, eforts to clear burned plants were made so as not to afect smaller reinforcement plants. Some native species competing were also removed. Currently, creating a perimeter ire protection strip is being planned. he extreme pressure of herbivores is one of the main problems for the mountain lora in Majorca. Grazing, mainly by goats, has changed the landscape increasing the heterogeneity of the environment, the degradation of the habitats and the presence of dominant species. he landscape would be diferent without this excess of herbivores and we would certainly be able to enjoy a lora, not only more in consonance with the climate, but also more plentiful and varied than at present. Most of the exceptional rare and endemic plants are congregated on the Puig Major Mountain. In this area, hunting of herbivores is 115 Managing threatened plants on islands: tasks & priorities taking place and as mentioned before, the fencing of of botanical interest areas. In 2008, 7 enclosures to protect a forest of Acer opalus subsp. granatense and promote germination and growth of juveniles were built. In 2009, 270 seedlings were germinated, but they died during the summer. Other 104 seeddings were germinated in 2010 and 141 in 2011, of which only 13 plants survive in 2012. Important activities took place at the top of the Puig Major in 2008. he Ministry of Defence, through the company Tragsa, reduced the size of the installations, carried out a project of demolition and removal of all obsolete facilities and is now actively involved in the conservation of the enormously valuable natural heritage of the Puig Major (almost €1 million budget). hese areas were subsequently restored with shrubs and herbaceous species common in the massif as well as young specimens of Taxus baccata provided by the Species Protection Service. As for the Minorcan endemic Vicia bifoliolata, despite its population increase over recent years, the fragmentation of its habitat could be a problem for the stability of the species that depends on a speciic habitat, the presence of which is currently limited to a reduced geographical area. Limonium species are adapted to highly saline soils, and wet and poorly ventilated areas. his degraded and gradually changing habitat is sending these species towards extinction. As for the species Limonium barceloi, important actions to reverse this situation are being carried out, such as the elimination of competing plants, the removal of debris and irrigation with salt water. he perception is that these actions are having positive efects and we have observed a signiicant increase in individuals (Fig. 1). On the other hand, the exploration activities have increased the number of known individuals and populations. Soil samples have been collected to characterize the habitat and try, in future, to return to original natural state of the area. In the Marina de Magaluf, a degraded wetland with 5 diferent endemic species, 454 Tamarix L. plants from adults of the same habitat were planted. hanks to a collaboration agreement with the city council, habitat restoration actions, such as debris and invasive species removal, have been carried out. Population biology monitoring his is one of the actions common to all plants related to recovery or conservation plans. Of particular interest are the cases of each of the wild specimens of Pinus pinaster and Taxus baccata. he show data regarding the geographical location, the identiication plate number, individual length and width, data on the ramiications for P. pinaster, lowering and state of conservation. 116 Islands and plants: preservation and understanding of lora on Mediterranean islands In the case of Euphorbia margalidiana, Limonium magalluianum, L. boirae and L. ejulabilis we established permanent monitoring plots where the number of germinations, evolution, and growth of reproductive plant and conservation status were registered. For the remaining threatened species, data on reproduction biology such as lowering and fruiting, survival germination and in some cases data on pollination vectors are recorded annually. Botanical experts carried out all of these actions. Deeper knowledge he systematic exploration of the upper area of the Puig Major Mountain has resulted in the discovery of many new threatened specimens. Extreme weather conditions, steep slopes, and sometimes the small size of some plants make it diicult to ind new subpopulations. Population growth in all the most endangered species of Puig Major Mountain is due, except for cases of reinforcement actions, to prospecting actions. Orchis palustris Jacq. is an orchid in the Balearic Islands that is only present in the area of the Albufera de Mallorca (Wetland). For this reason and for the insecurity and instability of their populations a Conservation Plan was conducted in 2009. his plant is an opportunistic species that grows in open ields with high soil moisture whose ecological requirements are unknown. One of the main objectives is the understanding of the ecology of this species and its basic needs. All the actions developed to get to know this plant are just emerging but, so far, they have been performed to characterize the habitat, using population censuses, records of soil moisture and salinity, interaction with other plant species, and responses to drought and changes in lood regime. he aim is to expand the distribution of plants from population centers and consolidate them. Ex situ he goal, which is common to all lora conservation plans, is to make collections of plants and seed banks in three diferent specialization centers. his action essentially began in 2010, but since 2008 we have been collecting cuttings and seeds (and fern spores) most of which were used to grow plants, subsequently planted in natural areas. hese actions are being carried out with the help of Forest Seed Bank of the Balearic Islands (Menut), Sóller Botanic Garden, Barcelona Botanic Garden and Madrid Polytechnic University. Keeping an updated database of all the stored material is another ex situ action. 117 Managing threatened plants on islands: tasks & priorities Information on species’ genetic diversity Some molecular studies on species have been conducted associated with a conservation plan. We have a study on taxonomic evolutionary relationships among 11 endemic species of Limonium, determination of variability and genetic relationships inter and intra yews (Taxus baccata) populations of Majorca, phylogenetic information and the most likely origin of the population of Minorcan Pinus pinaster, and this year we will have results on Orchis palustris’ diversity. It is important to observe that many outside researchers are conducting molecular studies on endangered species of the Balearic Islands. Disclosure and environmental education his section focuses on in situ conservation actions as one of the main points of work. Each year information sessions on the status of threatened species conservation and restoration actions (detailed information on our website, brochures, congresses, in situ posters and training courses) take place. hese actions are aimed to the general public (to raise awareness of the existence of threatened unique species) and key sectors of society that are directly or indirectly related to some endangered species and can have inluence on their conservation. Other conservation actions Species Protection Service performs other environmental conservation activities like irrigation in dry season, protection against herbivores and elimination of competing species. For example, to beneit the Colchicum lusitanum, a Western Mediterranean species in the Balearic Islands which is present only in the highest part of the Puig Major, the Service has made removal actions against competing native species such as Lactuca serriola and Carlina corymbosa L. With the fern Cystopteris fragilis it also undertook the local removal of Primula acaulis subsp. balearica. In the case of Limonium barceloi Gil and Llorens, we have competition problems with the exotic Arundo donax L. due to the lack of adequate habitat. CONSIDERATIONS / CONCLUSIONS he recovery of threatened and endangered species is complicated due to the number, severity, and tractability of the threats facing each species. he most common threats are those related to resource use, exotic species, construction, and the alteration of habitat dynamics (Lawler et al., 2002). Experience tells us that the limiting factors of our endangered species are mainly the lack or destruction of habitat, excessive pressure from herbivores and in some cases 118 Islands and plants: preservation and understanding of lora on Mediterranean islands the lack of information. In recent decades, human intervention (economic growth and abandonment of agricultural and traditional practices) has been exponentially afecting both quality and quantity of species habitats, changing the landscape and promoting the fragmentation of habitats. Trying to restore, as much as possible, the previous natural conditions that favored the establishment and development of endangered species, or achieving a minimum viable population to ensure their survival in the wild entirely independent of human management, means persistence and reproduction, and this is our struggle. Small reserves should not be seen as an alternative to large protected areas but as a complement (Laguna et.al., 2004) or as a start towards conservation. Small protected areas allow closer monitoring of plant diversity and tailored actions to the needs of particular species or vegetation types (Laguna et.al., 2004). Our endangered species have their main threat in the lack of habitat and destruction, and our goal is to keep natural space, improve and manage the species in order to achieve stable natural populations and even increase them. Is this positive? Is so much human intervention good? Are we changing natural areas with gardens? Are we ighting against nature? Or perhaps are we repairing erroneous human activities? Whatever the answer, our crucial purpose of a recovery plan is to prescribe tasks to restore species populations to viable, self-sustaining levels so they can be removed from the endangered species list (Lawler et al., 2002). he most signiicant actions with the best results for the targeted species are protection against herbivores, habitat restoration and reinforcement and translocation actions. he basic biological purpose of reintroduction is establishing new or increasing existing populations in order to increase a species’ survival prospect (Godefroid et al., 2011). Introducing rare plants in new sites to ofset efects of habitat destruction requires detailed knowledge of habitat requirements, plant demography, and management needs (Holl & Hayes, 2006). And this is how we approach our conservation work. he problem is that maintaining both existing and introduced populations of rare plants frequently requires longterm habitat management in order to maintain disturbance regimes and to minimize competition with exotic species (Holl & Hayes, 2006; Godefroid et al., 2011). For many authors, recruitment is considered the highest measure of success. he species Apium bermejoi, endemic Limonium and Euphorbia margalidiana have new individuals, and with Ligusticum huteri, Taxus baccata, and Pinus pinaster as non-annual plants, it is still early to have new individuals. 119 Managing threatened plants on islands: tasks & priorities he most likely common failure of plant conservation eforts is due to funding constraints. Money for the protection and recovery of threatened and endangered species is limited. herefore, it would be prudent to set priorities clearly so that we can optimally use the funds available (Lawler et al., 2002). We have been tracking these recovery plans for few years, but every day we are learning something new. here are many questions that arise and knowledge is constantly gained, but what really matters is that endangered species have a very positive response to the right management and, hopefully, in the years to come they will continue their road to recovery. REFERENCES Campbell, S.P., Clark, A., Crampton, L.H., Guerry, A.D., Hatch, L.T., Hosseini, P.R., Lawler, J.J., O’Connor, R.J. 2002. An assessment of monitoring eforts in endangered species recovery plans. Ecological Applications, 12(3): 674-681. J.M., Johnson, I., Dixon, B., Gordon, D., Magnanon, S., Valentin, B., Bjureke, K., Koopman, R., Vicens, M., Virevaire, M., Vanderborght, T. 2011. How successful are plant species reintroductions? Biological Conservation, 144: 672–682. Caujapé-Castells, J., Tye, A., Crawford, D.J., Santos-Guerra, A., Sakai, A., Beaver, K., Lobin, W., Florens, F.B.V., Moura, M., Jardim, R., Gómes, I., Kueferm, C. 2010. Conservation of oceanic island loras: Present and future global challenges. Perspectives in Plant Ecology, Evolution and Systematics, 12: 107–129. Holl, K.D., Hayes, G.F. 2006. Challenges to introducing and managing disturbance regimes for Holocarpha macradenia, an endangered annual grassland forb. Conservation Biology, 20(4): 1121-31. Laguna, E., Deltoro, V.I., Pèrez-Botella, J., Pèrez-Rovira, P., Serra, W., Olivares, A., Fabregat, C. 2004. he role of small reserves in plant conservation in a region of high diversity in eastern Spain. Biological Conservation, 119: 421-426. Decreto 75/2005, de 8 de julio, por el cual se crea el Catálogo Balear de Especies Amenazadas y de Especial Protección, las Áreas Biológicas Críticas y el Consejo Asesor de Fauna y Flora de las Islas Baleares. BOIB 106, 16-07-2005. Lawler, J.J., Campbell,S.P., Guerry, A.D., Kolozsvary, M.B., O’Connor, R.J., Seward, L.C.N. 2002. he scope and treatment of threats in endangered species recovery plans. Ecological Applications, 12(3): 663667. Godefroid, S., Piazza, C., Rossi, G., Buord, S., Stevens, A.D., Aguraiuja, R., Cowell, C., Weekley, C.W., Vogg, G., Iriondo, 120 Islands and plants: preservation and understanding of lora on Mediterranean islands Real Decreto 139/2011, de 4 de febrero, para el desarrollo del Listado de Especies Silvestres en Régimen de Protección Especial y del Catálogo Español de Especies Amenazadas. BOE 46, 23 -02-2011. Rita, J., Payeras, T. 2006. Biodiversidad de las plantas vasculares de las Islas Baleares. Orsis, 21: 41-58. 121 Managing threatened plants on islands: tasks & priorities 122 Islands and plants: preservation and understanding of lora on Mediterranean islands THE LIFE+ RENEIX PROJECT Pere Fraga i Arguimbau, Irene Estaún Clarisó, Eva Cardona Pons, Mireia Comas Casademont, Maria González Piris & Carme Garriga Sintes LIFE+ RENEIX Project, Departament d’Economia, Medi Ambient i Caça, Consell Insular de Menorca. Plaça de la Biosfera, 5, 07703 Maó. Spain. life.reneix@cime.es INTRODUCTION he LIFE program (http://ec.europa.eu/environment/life) of the European Union is the only direct line of funding the Commission has to subsidize proposals whose goals are related to the practical management of the environment. To date, 3,950 projects with a total overall budget of €7.2 billion have been subsidized (Camarsa & Silva, 2013). he program is made up of 3 strands or areas depending on the goals of the activity or the type of proposed action: LIFE Environment (Policy and Governance), LIFE Nature (and Biodiversity), and LIFE Information and Communication. Of these three strands, it is LIFE Nature that most directly and most practically impacts conservation of biodiversity, with clear results regarding this objective (COWI, 2009). Until the year 2006, the LIFE program funded LIFE Nature projects (COWI, 2009), the most signiicant investment in environmental conservation that has ever been made in Europe. his substantial sum has been most productive, as can be observed through the corresponding results. According to a statistical study, as many as 364 species have beneited from one of more of these projects and in 92% of the cases, measurable improvement in their state of conservation has been observed (COWI, 2009). LIFE Nature projects have continually been carried out on the Island of Menorca since the year 2001 and have become some of the most important contributions to the conservation of biodiversity (table 1). he irst of said projects was speciically aimed at the conservation of threatened lora: LIFE FLORA (LIFE2000NAT/E/7355; http://lifelora.cime.es), and became the single greatest efort ever made regarding the direct management of lora on the Island of Menorca. One successful result that stands out is the development of management plans for the seven species of lora included in the Habitats Directive and other threatened species (Fraga et al, 2004a); a proposed network of microreserves for lora (http://lifelora.cime.es/webeditor/pagines/ile/ microreservas.pdf) and especially for the control and eradication of the exotic 123 he LIFE+ RENEIX project invasive plant Carpobrotus (Fraga et al, 2005), which was a serious threat to the endemic coastal lora at that time. Acronym, names, and code LIFE FLORA Conservation of areas with threatened species of the flora on the island of Menorca LIFE2000NAT/E/7355 LIFE BASSES Management and conservation of Mediterranean temporary ponds on the island of Menorca LIFE05/NAT/ES/000058 LIFE+ RENEIX Habitats of priority species restoration on the island of Menorca LIFE07NAT/E/000756 Period Budget Objectives Accomplishments - Development of 8 management plans - Proposal of a plant microreserve network - Control and eradication of the alien invasive plant Carpobrotus - Involvement of local population in actions and objectives of the project 2001-2004 Restoration of favourable conditions for the plant species 653,662 € included in annex I of the Habitats Directive 2005-2009 Long term conservation of the priority habitat Mediterranean 1,013,549 € temporary ponds on the island of Menorca - Cataloguing temporary ponds - Improvement of the ecology of the habitat - Specific management plan for temporary ponds - Habitat restoration - Social awareness for the conservation of temporary ponds 2009-2013 Active restoration of degraded habitats home to some communities of interest and 1,574,713 € priority species of the flora of Menorca included in the Habitats Directive - Multidisciplinary characterisation and main threats in long term degraded areas - Development of new methodologies for habitat restoration - Landscape restoration to favour regeneration of multiple habitats and species - Consolidation of traditional techniques for habitat management - Multilevel social awareness of the importance of landscape conservation Table 1. LIFE Nature projects developed in Menorca, their objectives and main accomplishments. he second project, LIFE BASSES (LIFE 05/NAT/ES/000058; www.cime. es/lifebasses), broadened its objectives and directed its energy toward the conservation of an entire habitat, Mediterranean temporary ponds, considered of priority interest under the Habitats Directive of the European Union. Focus went from vegetation to a more extensive realm, not only regarding diversity of organisms, but also ecological functions and the relationship between humans and conservation of biodiversity. he proposed actions were more complex in both their techniques and execution, which were at times even considered risky. he project, its development and the results progressed from initial uncertainty to the conirmation of its objectives, in large part thanks to the direct assistance and consulting received from the Scientiic Community. he initial proposal was exceeded (Fraga et al, 2010a) and even received recognition from the European Union (Silva et al., 2011) upon receiving the Best of the Best LIFE Nature projects 2010 award. he creation of the proposal of the LIFE+ RENEIX project (http://lifereneix. cime.es) was highly relevant to experiences and results of the two previous 124 Islands and plants: preservation and understanding of lora on Mediterranean islands projects. On one hand, further work was to be carried out on threatened species of lora, considering that the most recent studies and knowledge deemed this necessary (Fraga, 2009), while at the same time it became ever more evident that efective protection of biodiversity required conservation of habitats (i. e. Groves et al, 2002; Franklin et al, 2011; Maes et al, 2012), considering those speciic measures that are limited to the protection of individuals or the control of a certain threat to be insuicient. Taking advantage of these two projects in the social sphere was also deemed invaluable. Special volunteer days were established within the LIFE FLORA project and were indispensable regarding increased social awareness. In the LIFE BASSES project, educational resources like the instructional pond, created by the project (Allès, 2010) or the use of traditional techniques to manage the habitat (Mascaró et al., 2010), brought these projects closer to the general public. It became necessary to convey this message to society: it is crucial and possible to restore or recover areas that appear deteriorated or excessively altered (Shapiro, 1995; Whittey, 1997; Young, 2000). THE HABITATS DIRECTIVE IN MENORCA he basis for the outlook and the actions of any proposal within the LIFE Nature project are those areas included in the Natura 2000 Network of the Habitats Directive. Ater the most recent additions, many resulting from the LIFE BASSES project (BOIB Núm. 145, 7-X-2010; http://boib.caib.es/pdf/2010145/ mp15.pdf), 38.7% of the surface area of the island is now included within this territory (Fig. 1; Carreras & Truyol, 2009). Beyond this quantitative assessment, what is truly signiicant is how efective it is on the conservation of biodiversity, especially with that which is speciic or characteristic of any given territory, as established as a European regulation (Jongman, 1995; Apostolopoulou & Pantis, 2009; Maes et al., 2012). Table 2 shows a list of habitats of the Habitats Directive found on the island and their relationship with the areas of action of the LIFE+ RENEIX project, which shall be discussed in the following section. he richness of habitats from the Habitats Directive found on the island is not a mere coincidence between this legal instrument and its characterization, nor is it an isolated case. Menorca, like other Mediterranean insular territories, is recognized as a focal point for biodiversity (Médail & Quézel, 1999; Médail & Diadema, 2009), which normally is linked to habitat diversity, and also oten to their heterogeneity (Benton et al., 2003). In speciic groups of organisms, such as vascular lora, the updating of inventory also conirms this biological 125 he LIFE+ RENEIX project richness (Fraga et al., 2004a, 2008). However, if we consider this list of species of lora included in the Habitats Directive and their level of endangerment or conservation (Table 3), according to recent ield studies (Fraga et al., 2010), a certain level of discrepancy may be observed. Habitats are proportionally more important, in fact, these include most taxa of vascular lora, whether endemic or not, that are found with any level of endangerment (Appendix 1). Fig 1. Current distribution of the Natura 2000 network in Menorca. his set of data conirms just how crucial the protection of these habitats is for the conservation of biodiversity (Franklin, 1993). he Habitats Directive determines that certain areas must be deined, based on speciic criteria, which require protection and management for the conservation of biodiversity, and hence determine the Natura 2000 Network for each state or region. In the case of the Balearic Islands, such delimitation was carried out using existing igures for urban protection, called natural areas of 126 Islands and plants: preservation and understanding of lora on Mediterranean islands special interest (ANEI), which originated from the need for protection of these territories from urban development destined to activities in tourism (Morillo & Gómez Campo, 2000; Carreras & Truyol, 2009). he criteria used in deining them took into account both landscape and natural values (Carreras & Truyol, 2009). In Menorca, the transposition of the ANEIs to the Natura 2000 Network was not complete as it was limited to coastal areas, excluding inland regions (Carreras & Truyol, 2009). his fact, in terms of lora, has caused the absence of certain areas of interest from within the Natura 2000 Network (Fig. 2). Fig 2. Protected areas in compliance with the law in Menorca 1/91 Natural Areas of conservation interest of the Balearic Islands. 127 he LIFE+ RENEIX project 2. Habitats of European interest found in each action area. Table 2.Table Habitats of European interest found in each action area. * Denotes priority habitat Pas d'en Ets Alocs- Binimel·làEs Murtar Revull el Pilar cala Mica Habitat (1) 1. COASTAL AND HALOPHYTIC HABITATS 11. Open sea and tidal areas 1120 * Posidonia beds (Posidonion oceanicae) X X 1130 Estuaries X X 1160 Large shallow inlets and bays X X 1150 * Coastal lagoons X 12. Sea cliffs and shingle or stony beaches 1210 Annual vegetation of drift lines X X X 1240 Vegetated sea cliffs of the Mediterranean coasts with endemic Limonium spp. X X 1310 Salicornia and other annuals colonising mud and sand X X 1410 Mediterranean salt meadows (Juncetalia maritimi) X X 1510 * Mediterranean salt steppes (Limonietalia) X X 2110 Embryonic shifting dunes X X 2130 *Fixed coastal dunes with herbaceous vegetation (grey dunes) X X 2210 Crucianellion maritimae fixed beach dunes X X 2230 Malcolmietaliadune grasslands X X X X X 13. Atlantic and continental salt marshes and salt meadows 14. Mediterranean and thermo-Atlantic saltmarshes and salt meadows 15. Salt and gypsum inland steppes 2. COASTAL SAND DUNES AND INLAND DUNES 21. Sea dunes of the Atlantic, North Sea and Baltic coasts 2120 Shifting dunes along the shoreline with Ammophila arenaria (white dunes) 22. Sea dunes of the Mediterranean coast 2220 Dunes with Euphorbia terracina X X 2240 Brachypodietalia dune grasslands with annuals 2250 * Coastal dunes with Juniperus spp. 2260 Cisto-Lavenduletalia dune sclerophyllous scrubs 2270 * Wooded dunes with Pinus pinea and/or Pinus pinaster X X X X X X X X X X X X X X 3. FRESHWATER HABITATS 31. Standing water 3120 Oligotrophic waters containing very few minerals generally on sandy soils of the West Mediterranean with Isoetes spp. X 3130 Oligotrophic to mesotrophic standing waters with vegetation of the Littorelletea uniflorae and/or IsoetoNanojuncetea X 3170 * Mediterranean temporary ponds X 3140 Aguas oligomesotróficas calcáreas con vegetación béntica de Chara spp. * Denotes priority habitat 128 X X X Islands and plants: preservation and understanding of lora on Mediterranean islands Pas d'en Ets Alocs- Binimel·làEs Murtar Revull el Pilar cala Mica Habitat (1) 32. Running water 3290 Intermittently flowing Mediterranean rivers of the Paspalo-Agrostidion X X X X 5. SCLEROPHYLLOUS SCRUB (MATORRAL) 52. Mediterranean arborescent matorral 5210 Arborescent matorral with Juniperus spp. 5230 * Arborescent matorral with Laurus nobilis X 53. Thermo-Mediterranean and pre-steppe brush 5320 Low formations of Euphorbia close to cliffs 5330 Thermo-Mediterranean and pre-desert scrub X 54. Phrygana 5430 Endemic phryganas of the Euphorbio-Verbascion 6. NATURAL AND SEMI-NATURAL GRASSLAND FORMATIONS 62. Semi-natural dry grasslands and scrubland facies 6220 * Pseudo-steppe with grasses and annuals of the Thero-Brachypodietea X 64. Semi-natural tall-herb humid meadows 6420 Mediterranean tall humid herb grasslands of the Molinio-Holoschoenion X X X X X X X X X X X X X X X 7. RAISED BOGS AND MIRES AND FENS 72. Calcareous fens 7220 * Petrifying springs with tufa formation (Cratoneurion) X 8. ROCKY HABITATS AND CAVES 82. Rocky slopes with chasmophytic vegetation 8210 Calcareous rocky slopes with chasmophytic vegetation X 8220 Siliceous rocky slopes with chasmophytic vegetation 83. Other rocky habitats 8310 Caves not open to the public X X X X X X X X X X 9. FORESTS 92. Mediterranean deciduous forests 92D0 Southern riparian galleries and thickets (NerioTamaricetea and Securinegion tinctoriae) 93. Mediterranean sclerophyllous forests 9320 Olea and Ceratonia forests X 9340 Quercus ilex and Quercus rotundifolia forests 95. Mediterranean and Macaronesian mountainous coniferous forests 9540 Mediterranean pine forests with endemic Mesogean pines X X X X (1) Habitat denomination and classification follows criteria established in the latest version of the INTERPRETATION MANUAL OF EUROPEAN UNION HABITATS (EUR 28, April 2013) (1) Habitat denomination and classiication follows criteria established in the latest version of the Interpretation Manual of European Union Habitats (EUR 28, April 2013). 129 he LIFE+ RENEIX project Taxa Conservation status Source Observations Anthyllis hystrix (Willk. ex Barc.) Cardona, Contandr. et Sierra NT Moreno (2008) Carduncellus (Femeniasia) balearicus (J.J. Rodr.) G. López VU Moreno (2008) Daphne rodriguezii Teixidor VU Moreno (2008) Helosciadium (Apium) bermejoi (L. Llorens) Popper et M.F. Watson CR Moreno (2008) Marsilea strigosa Willd. VU Sáez and Rosselló (2001) Not included in Moreno (2008) Paeonia cambessedesii (Willk.) Willk. LC Sáez and Rosselló (2001) Not included in Moreno (2008) Vicia bifoliolata J.J. Rodr. VU Classified as CR in Moreno (2008), Catàleg d'espècies amenaçades de les Illes Balears updated to VU from field studies (Fraga, 2010) Table 3. Plant species of the lora of Menorca included in the Habitats Directive (annex I) and their conservation status THE PROJECT’S AREAS OF ACTION he achievement of the proposal’s goals required the deinition of speciic areas of action moreso than simply carrying out wide-spread activities throughout the whole of the area included in the Natura 2000 Network. Hence, the very actions and their results would be more visible, as well as more easily evaluated. he selection of possible areas in which to act was based on the substantial work carried out within the LIFE FLORA project. Not only due to the management plans it developed, with its subsequent revision of sites, but also due to the vital land exploration, so as to identify new populations of threatened species or to detect the presence of the invasive Carpobrotus plant. All this, along with the experience and knowledge of the technical team regarding the island’s lora, made the development of an island map with areas of concentration of biodiversity (Fig. 3) possible, with the Sites of Community Importance (SCI) superimposed. A list that included a series of criteria that afected the viability of the proposal was then applied regarding: accessibility, concentration of threats, land ownership, property’s potential to carry out interventions, availability of social participation, possible innovative or demonstrative nature of actions to be performed, etc. Most of these criteria are already included as selected recommendations within several projects for planning habitat restoration (Collinge, 1996; Margules & Pressey, 2000; Sutherland et al., 2004; Miller & Hobbs, 2007). 130 Islands and plants: preservation and understanding of lora on Mediterranean islands Fig 3. Plan biodiversity hotspots in Menorca, as a result of preparatory actions whitin the LIFE+ RENEIX Project. his process resulted in four areas (see igure 3) that can be characterized according to the aforementioned criteria in table 4. In addition to the required criteria of being located within the Natura 2000 Network, we also see how all four areas coincide with zones of concentration of loristic diversity (Fig. 3; Table 5). In two cases (Binimel·là-Cala Mica, Es Alocs-El pilar) the level of threat of deterioration stemmed from eforts of urbanization (Fig. 4) that were of notable social debate and resulted in an overall consensus for environmental rehabilitation. he other two developed from diferent situations. In Es Murtar the state of degradation was more restricted, although elevated, and the repercussions on biodiversity were relatively high, for both habitats and species that were afected as well as for any and all social repercussions it could have. At El Pas d’en Revull, social and communication factors played a signiicant role. It is a key access point to one of the most popular wilderness settings on the island, the Algendar ravine, with considerable ethnological heritage and as part of the route of the historic “Royal Road”, which volunteers have been 131 he LIFE+ RENEIX project rehabilitating over recent years. Although the threat level was relatively low, certain circumstances coexisted that led to the restoration and protection of the habitats combined with social awareness using educational tools and the fostering of public participation. In this manner, the goal of putting into practice one of the premises considered fundamental to the ecology of restoration was set (Miles et al., 1998; Ryan et al., 2001; Aronson et al., 2010). Area of action Pas d'en Revull Es Alocs – El Pilar Binimel·là – Cala Mica Es Murtar Threat - Lack of information - Excessive visitation - Lack of social awareness - Changes in vegetation - Lack of information - Vehicle accesses - Excessive visitation - Lack of social awareness - Stages of erosion - Changes in vegetation - Lack of information - Abandoned roads - Vehicle accesses - Excessive visitation - Lack of social awareness - Stages of erosion - Changes in vegetation - Lack of information - Vehicle accesses rodats - Excessive visitation - Lack of social awareness - Stages of erosion Table 4. Areas of action and their corresponding threats 132 Islands and plants: preservation and understanding of lora on Mediterranean islands Table 5. Taxa of the vascular lora of Menorca with conservation interest found in each area of action of the LIFE+ RENEIX project. Taxon Es Murtar Anacamptis morio subsp. longicornu (Poir.) H. Kretzschmar, Eccarius et H. Dietr. Anthyllis hystrix (Willk. ex Barc.) Cardona, Contandr. et Sierra Aristolochia clematitis L. Aristolochia paucinervis Pomel • Arum pictum L. f. Asplenium balearicum Shivas • Asplenium trichomanes subsp. inexpectans Lovis Astragalus balearicus Chater Binimel·là Cala Mica El Pilar Es Alocs • • • • • Avena barbata subsp. castellana Romero Zarco • Bellium bellidioides L. Brimeura fastigiata (Viv.) Chouard • • Calicotome villosa (Poir.) Link Carduncellus balearicus (J.J. Rodr.) G. López • • • • Carlina corymbosa subsp. major (Lange) López Martínez et Devesa Chelidonium majus L. • • • • • • Carex rorulenta Porta • • Coronilla glauca L. Crepis triasii (Camb.) Nyman Cressa cretica L. Crocus cambessedesii Gay Cyclamen balearicum Willk. Cymbalaria aequitriloba (Viv.) A. Cheval. Cymbalaria fragilis J.J. Rodr. Digitalis minor L. Echinophora spinosa L. • • • • • • • • Elatine macropoda Guss. • • • • • • • • • Euphorbia maresii subsp. maresii Knoche • • • • • • • Exaculum pusillum (Lam.) Caruel Helicodiceros muscivorus (L. f.) Engl. Hippocrepis balearica Jacq. Hypericum balearicum L. Launaea cervicornis (Boiss.) Font Quer et Rothm. Leucojum aestivum subsp. pulchellum (Salisb.) Briq. 133 • • • • • • • • • Epipactis microphylla (Ehrh.) Swartz Equisetum telmateia Ehrh. • • • • Coronilla montserratii P. Fraga et Rosselló • • • Cneorum tricoccon L. Pas d’en Revull • • • • • • • • • • he LIFE+ RENEIX project Taxon Limonium companyonis (Gren. et Billot) Kuntze Limonium minoricense Erben Es Murtar Binimel·là Cala Mica El Pilar Es Alocs • • • • • Limonium minutum (L.) Chaz. Limonium saxicola Erben • Limonium tamarindanum Erben Lomelosia cretica (L.) Greuter et Burdet • Lotus tetraphyllus L. (1) Lysimachia minoricensis J.J. Rodr. • • • • • • • • • • Matthiola tricuspidata (L.) R. Br. Melissa officinalis L. Micromeria cordata (Moris ex Bertol.) Moris • • Micromeria filiformis (Aiton) Benth. Micromeria rodriguezii Freyn et Janka Ononis crispa L. • Ophrys balearica Delforge Orobanche cernua L. • Orobanche foetida Poir. Orobanche rumseiana Pujadas et P. Fraga • • • • • • Paeonia cambessedesii (Willk.) Willk. Phlomis italica L. • Polycarpon colomense Porta Polycarpon dunense P. Fraga et Rosselló Romulea assumptionis Garcias Font Santolina chamaecyparissus subsp. magonica O. Bolòs, Molin. et P. Monts. Scrophularia auriculata subsp. pseudoauriculata (Sennen) O. Bolòs et Vigo Scrophularia ramosissima Loisel. Senecio rodriguezii Willk. ex J.J. Rodr. • • • • • • • • • • • • • • Spergularia heldreichii Fouc. • • • • • • • • (1). Extinct in the wild. Plants in Pas d’en Revull originated from reintroductions. 134 • • • • • • • Teucrium asiaticum L. Teucrium capitatum subsp. majoricum (Rouy) T. Navarro et Rosúa Teucrium subspinosum Pourr. ex Willd. • • Sibthorpia africana L. Sonchus montanus (Willk.) Rosselló • • • Serapias nurrica Corrias Silene mollissima (L.) Pers. • • • Pastinaca lucida L. • • • Paronychia capitata (L.) Lam. • • • • Orobanche santolinae Loscos et J. Pardo Pas d’en Revull • • • • Islands and plants: preservation and understanding of lora on Mediterranean islands Es Murtar Taxon Thapsia gymnesica Rosselló et A. Pujadas Thymelaea velutina (Pourr. ex Cambess.) Endl. • Vicia bifoliolata J.J. Rodr. Vincetoxicum hirundinaria var. balearicum O. Bolòs et J. Vigo Viola stolonifera J.J. Rodr. Binimel·là Cala Mica • • El Pilar Es Alocs • Pas d’en Revull • • • • Fig 4. Programmed urbanistic development in the actuation area of Binimel·là, ca.1971. PLANNING OF ACTIONS: PREPARATORY ACTIONS AND IMPROVING KNOWLEDGE OF THE ENVIRONMENT he regulations of the LIFE projects declare that proposals must be developed from a starting point of previously consolidated knowledge regarding the situation of threat or the need for conservation that justify the means that shall be set forth (Brouwer et al., 2005; Kettunen et al., 2011). Still, the planning 135 he LIFE+ RENEIX project and the execution of proposed actions on the natural environment or those of communication, oten require further knowledge or perhaps further organization so as to be truly useful, both for achieving the established goals, and for the eicient execution of the entire project. he fact is, the restoration of habitats, with positive results in the middle to long term, and designed to endure, may fail if proper use is not made of the available information beforehand (White & Walker, 1997; Miller & Hobbs, 2007). In the original proposal of the project there were six preparatory actions that could be divided into three groups according to their function or expected result: - Facilitate the development of the project and the creation of interaction and cooperation with social sectors (actions A1 and A6). - Compilation and treatment of information regarding elements of interest for the project to facilitate the development of direct management actions for the natural medium (actions A2, A3, and A4). - Develop work methods and restoration techniques (actions A4 and A5). As seen above, some may have multiple orientations, and as for preparatory phases, execution oten continues beyond the initial stages, in reconsideration of the project. One example can be found in action A6, technical consulting from NGOs and owners in developing management actions for the environment, which in certain areas, like the Pas d’en Revull, has been active throughout the entire project. Another positive aspect of these preparatory actions is the information they generate and their usefulness in other projects or initiatives. he detailed cartography of species from project A2, or that of accesses and roads including detailed characteristics (A3) or the selection of species for revegetation (A4), have already been used by other actions of environmental conservation. hroughout the project, during the redesigning of actions or eforts to guarantee proper execution, other actions may be developed in the form of studies or ieldwork, which could actually be considered additional preparatory actions. Some examples of this dynamic are the geomorphological studies carried out in the Binimel·là region that have resulted in the creation of a both innovative and fundamental paper (Rodríguez et al., 2013) or the survey on social perception regarding the project and its objectives set forth by members of the Scientiic Committee. 136 Islands and plants: preservation and understanding of lora on Mediterranean islands ACTIONS OF RESTORATION: WHICH ONES AND WHY? he second group of actions, those of direct activity upon the natural medium, includes those performed in situ regarding project goals. In the initial proposal there is a predeined list of actions and techniques for investigation, but the truth is that most of them actually arise together or sequentially. One example is the construction of dry stone walls (C1), which is oten associated with the installation of other accessories such as gates and openings (C5), and normally serve to control or eliminate access points or roads (C2), and when these two actions are carried out, revegetation quite oten results (C3). Similarly, the primary objective of the construction of two bridges (C4) is the elimination of access points (C2) in the case of Es Alocs, and the control of vehicle access (C2) in Binimel·là. Table 6 shows the functions and objectives of each action within the areas of action and igure 4 shows an illustrative document that summarizes the importance of joint planning. In accordance with the established planning process for LIFE Nature proposals, these actions must be ixed on guaranteeing habitat and species conservation object of the proposal, with emphasis on the control of any identiied threats. Hence, selection and coniguration will have previously been contemplated during the process of development of a proposal. Dry stone wall constructions (action C1) are a typical ethnological element in many regions of the Mediterranean (Grove & Rackham, 2001; Pinto-Correia & Vos, 2004) and have been valued for many years, not only for their landscape value, but also for their ecological function and for proper administration of land usage (Naveh, 1994). Within the LIFE BASSES project, their useful nature in both habitat protection as well as their positive assessment on behalf of society were observed (Mascaró et al., 2010; Allés, 2010). In this project, their function as a management tool or for habitat recovery is widened using them directly as closures for access points and roads or in control of processes of erosion. In Menorca, these constructions oten go beyond simple separation or road blocks, as they commonly serve to deine and lay out areas or systems of tracks. his multi-functionality includes the related accessories or associated constructions that show a typology found on the island. In this way, yet another action (C5) is destined not only to the construction and installation of these complements to dry stone walls. he closure of accesses and roads (action C2) makes inherent reference to a threat that repeatedly appeared in all the LIFE projects developed on the island and is equally present in other regions around the world (p. ex. Wilshire 137 he LIFE+ RENEIX project et al., 1978; Rickard et al., 1994; Kutiel et al., 2000; Pickering & Hill, 2007) his action should seemingly be included within the previous one, however due to environmental and habitat diversity at the location of the project, it is not always possible to use dry stone walls as enclosing elements. Where sandy unstable soils are found (dune systems, sandy areas) these constructions could have an undesirable efect on the dynamic of morphological formation. In other situations, the closure of an access point or a road may be done using diferent techniques like decompaction of soil or the recovery of the original water supply system. he return of a habitat’s original vegetation, as it had been prior to alteration, may be a relatively slow process, as it is not always possible for it to occur more suddenly (Le Houreou, 2000; Vallejo et al., 2006). Optimal results are obtained when the succession of plant communities takes place with focus on stable vegetation (Niering, 1987). During this process, pioneer plants play a crucial role as those that are best suited to lead to more permanent plant communities (Padilla & Pugnaire, 2006). he focal point of preparatory action A4 was precisely plant species with this type of behavior, and action C3, revegetation of eroded areas, applies it in speciic points or areas of action where vegetation had virtually disappeared. his action in unison with other actions becomes even more evident. he presence of vegetation may reduce the amount of human traic in an area, and also serves to control access points (C2). Sowing or planting may require the prior decompaction of soil, yet another action that may help eliminate roads or access points (C2), or perhaps the need for construction of dry stone walls will arise (C1), resulting in stabilized soil. he construction of bridges (action C4) is an action that more clearly afects two speciic points. At Es Alocs, its purpose is the conservation of a relatively vast area that was being harmed due mainly to an access point to a cove, and separated a wet area in the process of rehabilitation into two parts. he construction of the bridge and the elimination of roads allow a series of habitats and species with a high level of conservation interest to be further protected from detected threats. One goal of the Habitats Directive is hence achieved, increased connectivity between habitats with reduced fragmentation. he Binimel·là bridge shares this goal of connectivity, although in a less direct fashion. 138 Islands and plants: preservation and understanding of lora on Mediterranean islands Table 6. Objectives and interventions carried out in areas of action Area Objective LIFE+RENEIX intervention Pas d’en Revull Improve the state of conservation of key species. Restore elements of ethnological heritage. Expand knowledge and interpretation of habitats and species present, through the creation of an interpretative botanic route. GIS cartography of unique species (2010 and 2013), GIS of vehicle accesses and map of habitats of interest.* Modification and restoration of ethnological elements. Construction and restoration of sections of dry stone walls and pavements. Planting of woody species typical of the ravine and follow up care. Installation of a botanic route and habitat signage. Four organized volunteer workdays. Guided tours for school-aged children since 2010 (30 groups). Es Alocs El Pilar Minimize effects stemming from excessive human presence. Eliminate stages of erosion and reduce the banality of the landscape. Organize vehicle access and channel pedestrian traffic to the cove. Recover the end of the torrent and the associated wetland and the habitats of interest. Recover sensitive species. Minimize effects stemming from excess of human presence. Control erosion. Recover dune systems with redevelopment, as well as associated species and communities. Create a botanic route as a tool for visitor awareness. Modify the path to access the cove using traditional techniques. Construction of dry stone wall to reorganize vehicle access. Construction of a bridge to divert access to the beach around the right side of the torrent and hence aid in the recovery of the coastal wetland. Elimination of housing development roads, via decompaction and revegetation. First volunteer workday. Installation of informative signage. Redirection of part of the Camí de Cavalls track that crossed the dune system, via an alternative existing path of less environmental impact. Installation of systems of sand retention using dry branches on the dune system to foster revegetation. Signage of a botanic route and guided tours for school children. Binimel·là Geomorphological and landscape recovery of the area. Control of free vehicle access and erosion. Recovery of habitats of community interest and populations of priority species. Minimize the effects of the presence of all-terrain vehicles. Expand knowledge and interpretation of habitats, key species, and the geological heritage of the area. Creation of a method for cultivation of the Femeniasia balearica. Geomorphological study of the massif of Binimel·là. Survey on social perception of the project. Recovery of acequia watercourses and restoration of the original drainage network. Construction of barriers with dry stone walls to stop processes of erosion. Construction of a bridge over the torrent to recover the ecological connectivity and restore the habitats of the torrent. Elimination of uncontrolled accesses to areas where Femeniasia balearica is found. Elimination of roads, decompaction, and revegetation with indigenous plants. Placement of informative signage. Pregondó Minimize effects stemming from excess of human presence. Control erosion in dune systems. Recover dune systems with redevelopment, as well as associated species and communities. Redirect human visitation of the area via the Camí de Cavalls track to reduce effects on sensitive communities and species. Redirection of the Camí de Cavalls track over the dune system and placement of systems of sand retention using dry branches. Restoration of dry stone walls and placement of fences to deter visitation to the areas with the presence of Femeniasia balearica. Es Murtar Habitat recovery (temporary ponds, fossil dune systems, coastal maquis shrublands) and associated priority species. Eliminate invasive species. Control free vehicle access. Elimination of uncontrolled roads via the restoration of dry stone walls and placement of metallic and wooden security fences to mark out roads. Decompaction and extraction of the layers of foreign materials around the football pitch for the recovery of the original layer of paleozoic material. Re-sow and plant indigenous species to encourage the natural regeneration of the habitats. Elimination of invasive species (Carpobrotus). Placement of informative signage. * his activity has been carried out in all areas of the project. 139 he LIFE+ RENEIX project Two other actions from this group initially had a more concrete objective. One of them, the recovery of the Es Murtar area (C6) was intended to eliminate an area used as a sports ield that became a focus for the generation and expansion of threats. In addition to this speciic intervention, others have been carried out that correspond to other actions: the construction of dry stone walls (C1) to close of access points (C2), decompaction of access points (C2) for their elimination so as to beneit the regeneration of vegetation or for sowing and planting for revegetation (C3). All these are further examples of complementary actions of these interventions. he goal of delimiting the wetland and the dune system of Binimel·là (C7) was similar as it was intended to act upon a series of habitats that make up one landscape and ecological unit, although some of the expected activities had already been performed during the process of evaluation of the proposal. Finally, this action has been redesigned so as to restore a speciic area where threats like excessive visitation or the proliferation of access points around sensitive habitats was causing substantial erosion to the environment. BRINGING THE PROJECT TO SOCIETY Communication and social awareness should be basic goals of the LIFE Natura projects’ proposals, and in fact most oten they are essential in achieving initiatives of habitat recovery or conservation of species for positive and constant results for an extended period of time. In areas physically divided, such as islands, it may occur that communication and social involvement are easier, but this proximity may also compel us to consider the message intended for society and the channel through which such message may arrive (Apostolopoulos & Gayle, 2002). Communicating is quite simple, and currently more so thanks to new technologies in communication and spreading of information. he LIFE Natura project proposals must include some actions with this focus: creating a web site, installation of informative panels, publishing of printed educational material and spreading of scientiic results. Other non-compulsory actions could include: the creation of a project image, the use of social networks and local newspapers so as to provide information regarding the project’s activities, etc. Nevertheless, such actions are still exclusively about communication. In limiting ourselves to these channels it is very likely that society will remain a passive subject that receives information without truly feeling involved or 140 Islands and plants: preservation and understanding of lora on Mediterranean islands identiied with the project’s goals. Hence, it is highly recommended to design actions that allow for the direct participation of society, at least for those groups who are more sensitive to the conservation of the natural environment (Pretty & Smith, 2003). his is why the LIFE+ RENEIX project communication and awarenessraising actions are so vital with regard to the diversity of actions and desired results. Apart from those above mentioned, common to virtually any proposal, other actions allowing for the involvement of society have been designed within this communication and increasing awareness package. his participation and union must come from both the most actively involved groups related to conservation of our natural environment, as well as from those who may create or increase the threats or those who in the future will be responsible for the continuity of our successes. Volunteer work and social participation sessions (action D6) have been successful in the LIFE FLORA project; focused here on the eradication of the invasive plant Carpobrotus (Fraga et al., 2005). his current project sought to be included in further actions such as the recovery of traditional tracks and roads, supportive measures for threatened lora or recovery of vegetation. he creation of botanical tours (action D7), although simply an activity of communication or dissemination, brings the characteristic habitats and species of Menorca’s lora to the general public. If we enhance them and make them more visible, it will be easier for various sectors of the community to get a better understanding of the project’s goals as well as the reasons behind them. he on-line publishing of information about the biodiversity and endemic lora concentration focuses (action D9) has a similar goal, which ventures beyond this initial idea and is extended so as to make it suitable for new communication technologies (Cots et al., 2013). he increased awareness towards groups or social sectors most directly related to some of the menaces has been achieved through speciic actions. In the case of visitors to the project’s areas of action, primarily tourists, action D4 hopes to provide information by means of informative panels in situ, about the primary natural values of the most crowded areas. For those who frequently drive motor vehicles through sensitive areas, action D5 intends to develop several interventions, although, at the beginning of this project, both the implementation and how to get to the group in an efective way caused several doubts, partly due to previous experience of a similar action in a LIFE FLORA project, and also to the information on results from other initiatives (Priskin, 141 he LIFE+ RENEIX project 2003). Finally these have been implemented in an awareness enhancement campaign directed at drivers of motor vehicles and other groups that practice outdoor activities in the natural environment. RESULTS he structuring of the project in areas of action, where actions oten develop in a sequential or simultaneous way, make results much easier to evaluate in each of these areas rather than for each particular action. Table 7 shows a summary of results for each area depending on the project actions, habitats or species involved. Pas d’en Revull. he irst interventions were carried out here. A new in situ reconsideration with town hall representatives and volunteer work groups promoting the recovery of the Camí Reial (Royal Road) and its maintenance served to directly involve these groups in the project. A day of ield work open to the public kicked of the activities: cleaning and preparing to rebuild dry stone walls, road surface and track reconditioning of the Camí Reial and protection measures for threatened plant species. Recovery of the Camí Reial track, its boundaries through the restoration of dry stone walls, improvement of the track surface, placement of sign-posts along the botanical tour and, especially, direct and constant contact with the volunteer work groups, have had two clear overall results: - Increased visitation in order to discover more about this area and walk along the botanical tour - Improvement of the habitats and populations of several species of conservational interest. he former directly links to the objectives of increased awareness and communication, although it also involves an obvious risk of excessive visitation. However, this risk has been reduced thanks to suitable sign-posting along the track and positive assessment of the groups of volunteers in charge of track maintenance. Nevertheless, some conlictive situations may occur due to vehicles parked outside of the designated areas. Es Alocs – El Pilar. Essentially, this area consists of two diferent focal points. On the eastern side, around Es Alocs cove, fencing and decompaction tasks along the roads of the failed housing development have been carried out, as well as the construction of a bridge, and the boundaries of the inal stretch of the access road to the cove were set, and inally plants were sowed to regenerate vegetation. Four main results can be highlighted: 142 Islands and plants: preservation and understanding of lora on Mediterranean islands - Signiicant decrease in the alteration level due to uncontrolled traic of all terrain vehicles. - Recovery of the native vegetation, currently herb plant pioneer communities. - Recovery of wetlands. - General improvement of the landscape value since alterations have been limited to speciic areas marked out by traditional constructions. On the western side, the area of inluence of El Pilar beach, the protection of the sandy soil habitats has been a primary focus, hence the access ways to the shore along less sensitive points have been marked out, old tracks with limited environmental impact have been recovered, in addition to other interventions mostly designed to favour the recovery of modiied habitats while also serving as a deterrent to potential excessive human presence. Also in this area volunteer work groups, mainly young people, have had certain prominence. hese are the most remarkable project results: - Efectiveness of some innovating techniques of low visual impact so as to beneit plant regeneration in dune systems. - Obvious improvement to sandy areas and dune system habitats. - Positive reaction of visitors to the regulation and marking of access points. As a negative point, an increase in visitation is causing the degradation of habitats on sandy soils in areas where no actions were envisaged. his new situation should lead to additional actions. Es Murtar. From early on, this was the area of action that seemed to require greater social consensus to develop the foreseen actions. However, there were no guarantees regarding the characteristics of the subsoil in the area covered by the sports ield. Ater several discussions and proposed interventions, work was carried out rather quickly. Decompaction and excavation of the sports area conirmed the previous existence of an old dune system or sandy area. his took place along with decompaction and closing of roads and a subsequent action of plant regeneration. he primary results are: - Conirmation of the recovery process of the sandy area’s vegetation. - Improvement of the conservation status of habitats and species of conservational interest. he priority species Vicia bifoliolata J.J. Rodr. is noteworthy, having undergone a remarkable population increase at decompacted access points. - Viability of the use of aggressive techniques (such as heavy machinery, modiication focused on regeneration) in order to achieve landscape recovery. 143 he LIFE+ RENEIX project Binimel·là – Cala Mica. his is the largest area of action, also one that has required major organisational eforts and consensus among diferent institutions and entities, both public and private. A rethinking of some project actions also diferentiated two separate focal points. On the western side, the marking of accesses and the regeneration of sandy soil environments have been carried out at the access to Pregonda beaches, similar to the El Pilar area. he results observed are very similar to those observed in this area, hence conirming the efectiveness of some innovative techniques used during the project. On the eastern side, the entire area where the construction of a housing development had been planned, actions have been rather complex and diversiied. Apart from the initial project plans, the speciications for action were based on preparatory actions: cartography and characterisation of accesses, cartography of species of interest, especially the recommendations of a geomorphological study. Actions developed have also followed a sequential process according to an accurate previous plan; recovery of the original water supply system, removal of tracks and access points via the very recovery of temporary water courses (excavation) or through the construction of dry stone walls, stabilisation of man-made slopes, decompaction in order to enhance plant regeneration, control of erosion, and sowing and planting of vegetation. As a further action, in accordance with the drating team of the revision of the Special Plan for the Camí de Cavalls horse track, a modiication of this hiking track has been made so as to increase accessibility and distance it from sensitive and dangerous areas. Some achieved results are: - he use of accurate planning and detailed knowledge of the area of action. - Traditional techniques such as construction of dry stone walls, versatile in their function and use. - Recovery of the water network, including the man-made one, as a key aspect in landscape restoration. Apart from these results for each area and those further elaborated in Table 7, an overall conclusion can be made from the LIFE+ RENEIX project, which is its main goal: the recovery or restoration of environmentally deteriorated areas is possible, both for habitats and species. his achievement oten means carrying out interventions on landscapes while developing more universal and general actions, and not those of a solely speciic or restrictive nature. 144 Area Binimel·là – Cala Mica Es Alocs – El Pilar Pas d’en Revull Removal of tracks and uncontrolled accesses Es Murtar Binimel·là – Cala Mica Es Alocs – El Pilar Pas d’en Revull Es Murtar Habitat recovery Binimel·là – Cala Mica Es Alocs – El Pilar Pas d’en Revull 145 Specification of the cultivation methodology Collaboration with local entities and associations Binimel·là – Cala Mica Es Murtar Binimel·là – Cala Mica Es Alocs – El Pilar Pas d’en Revull Es Murtar Restoration of dry stone walls Binimel·là – Cala Mica Es Alocs – El Pilar Pas d’en Revull Es Murtar Construction of new dry stone walls Binimel·là – Cala Mica Es Alocs – El Pilar Pas d’en Revull Habitats 1240 , 1410 , 1510 *, 2120, 2210, 2220 , 2230 , 2240, 2250 *, 2260, 2270 *, 3140 , 3170 *, 3290, 5210, 5320 , 5330 , 5430 , 6220 * , 6420, 8210, 8220, 92D0 , 9320 , 9340, 9540 1240 , 1410 , 1510 *, 2120, 2210, 2220 , 2230 , 2240, 2250 *, 2260, 2270 *, 3140 , 3170 *, 3290, 5210, 5320 , 5330 , 5430 , 6220 * , 6420, 8210, 8220, 92D0 , 9320 , 9340, 9540 A4. Selection of species for vegetation recovery C2. Removal of tracks and uncontrolled accesses C.3 Planting of native species to regenerate the vegetation C4. Construction of bridges on temporary Mediterranean torrents D6. Organisation of informative and civic participation sessions 1240 , 1410 , 1510 *, 2120, 2210, 2220 , 2230 , 2240, 2250 *, 2260, 2270 *, 3140 , 3170 *, 3290, 5210, 5320 , 5330 , 5430 , 6220 * , 6420, 8210, 8220, 92D0 , 9320 , 9340, 9540 A5. Explanation of the cultivation method for Femeniasia balearica 5430 A6. Technical consultation with NGOs and owners for assistance with environmental management D6. Organisation of informative and civic participation sessions 1240 , 1410 , 1510 *, 2120, 2210, 2220 , 2230 , 2240, 2250 *, 2260, 2270 *, 3140 , 3170 *, 3290, 5210, 5320 , 5330 , 5430 , 6220 * , 6420, 8210, 8220, 92D0 , 9320 , 9340, 9540 C1. Construction of dry stone walls using traditional techniques C2. Removal of tracks and uncontrolled accesses C.3 Planting of native species to regenerate the vegetation 1240 , 1410 , 1510 *, 2120, 2210, 2220 , 2230 , 2240, 2250 *, 2260, 2270 *, 3140 , 3170 *, 3290, 5210, 5320 , 5330 , 5430 , 6220 * , 6420, 8210, 8220, 92D0 , 9320 , 9340, 9540 C1. Construction of dry stone walls using traditional techniques C2. Removal of tracks and uncontrolled accesses C3. Planting of native species to regenerate the vegetation 1240 , 1410 , 1510 *, 2120, 2210, 2220 , 2230 , 2240, 2250 *, 2260, 2270 *, 3140 , 3170 *, 3290, 5210, 5320 , 5330 , 5430 , 6220 * , 6420, 8210, 8220, 92D0 , 9320 , 9340, 9540 Species Anthyllis hystrix, Aristolochia clematitis, Asplenium trichomanes subsp. inexpectans, Astragalus balearicus, Bellium bellidioides, Calicotome villosa, Carduncellus balearicus, Carlina corymbosa subsp. major, Chelidonium majus, Cneorum tricoccon, Coronilla montserratii, Crocus cambessedesii, Cyclamen balearicum, Euphorbia maresii subsp. maresii, Launaea cervicornis, Leucojum aestivum subsp. pulchellum, Limonium companyonis, Limonium minoricense, Limonium minutum, Limonium saxicola, Limonium tamarindanum, Lotus tetraphyllus, Lysimachia minoricensisMicromeria cordata, Micromeria filiformis, Micromeria rodriguezii, Ononis crispa, Orobanche cernua, Orobanche foetida, Orobanche rumseiana, Orobanche santolinae, Paeonia cambessedesii, Polycarpon colomense, Polycarpon dunense, Romulea assumptionis, Santolina chamaecyparissus subsp. magonica, Scrophularia ramosissima, Senecio rodriguezii, Sonchus montanus, Teucrium asiaticum, Teucrium capitatum subsp. majoricum, Teucrium subspinosum, Thymelaea velutina, Vicia bifoliolata, Viola stolonifera Anthyllis hystrix, Aristolochia clematitis, Arum pictum, Astragalus balearicus, Bellium bellidioides, Calicotome villosa, Carduncellus balearicus, Carlina corymbosa subsp. major, Chelidonium majus, Cneorum tricoccon, Coronilla montserratii, Crocus cambessedesii, Cyclamen balearicum, Helicodiceros muscivorus, Launaea cervicornis, Leucojum aestivum subsp. pulchellum, Limonium companyonis, Limonium minoricense, Limonium minutum, Limonium saxicola, Limonium tamarindanum, Lotus tetraphyllus, Matthiola tricuspidata, Micromeria filiformis, Micromeria rodriguezii, Ononis crispa, Orobanche cernua, Orobanche foetida, Orobanche rumseiana, Orobanche santolinae, Polycarpon colomense, Polycarpon dunense, Romulea assumptionis, Santolina chamaecyparissus subsp. magonica, Scrophularia ramosissima, Senecio rodriguezii, Sonchus montanus, Spergularia heldreichii, Teucrium capitatum subsp. majoricum, Teucrium subspinosum, Thymelaea velutina, Vicia bifoliolata Anthyllis hystrix, Aristolochia clematitis, Aristolochia paucinervis, Arum pictum, Asplenium balearicum, Asplenium trichomanes subsp. inexpectans, Astragalus balearicus, Avena barbata subsp. castellana, Bellium bellidioides, Calicotome villosa, Carduncellus balearicus, Carlina corymbosa subsp. major, Chelidonium majus, Cneorum tricoccon, Coronilla montserratii, Crocus cambessedesii, Cyclamen balearicum, Digitalis minor, Echinophora spinosa, Epipactis microphylla, Euphorbia maresii subsp. maresii, Helicodiceros muscivorus, Launaea cervicornis, Leucojum aestivum subsp. pulchellum, Limonium companyonis, Limonium minoricense, Limonium minutum, Limonium saxicola, Limonium tamarindanum, Lotus tetraphyllus, Micromeria filiformis, Micromeria rodriguezii, Ononis crispa, Orobanche cernua, Orobanche foetida, Orobanche rumseiana, Orobanche santolinae, Paeonia cambessedesii, Pastinaca lucida, Polycarpon colomense, Polycarpon dunense, Romulea assumptionis, Santolina chamaecyparissus subsp. magonica, Scrophularia ramosissima, Senecio rodriguezii, Sonchus montanus, Spergularia heldreichii, Teucrium asiaticum, Teucrium capitatum subsp. majoricum, Teucrium subspinosum, Thymelaea velutina, Vicia bifoliolata, Viola stolonifera Carduncellus balearicus Aristolochia clematitis, Aristolochia paucinervis, Asplenium trichomanes subsp. inexpectans, Astragalus balearicus, Bellium bellidioides, Calicotome villosa, Carduncellus balearicus, Carlina corymbosa subsp. major, Chelidonium majus, Cneorum tricoccon, Coronilla montserratii, Crocus cambessedesii, Cyclamen balearicum, Cymbalaria fragilis, Digitalis minor, Helicodiceros muscivorus, Launaea cervicornis, Leucojum aestivum subsp. pulchellum, Limonium companyonis, Limonium minoricense, Limonium minutumLimonium tamarindanum, Lotus tetraphyllus, Lysimachia minoricensis, Micromeria filiformis, Micromeria rodriguezii, Ononis crispa, Orobanche cernua, Orobanche foetida, Orobanche rumseiana, Orobanche santolinae, Paeonia cambessedesii, Polycarpon colomense, Polycarpon dunense, Romulea assumptionis, Santolina chamaecyparissus subsp. magonica, Scrophularia auriculata subsp. pseudoauriculata, Scrophularia ramosissima, Senecio rodriguezii, Sibthorpia africana, Silene mollissima, Sonchus montanus, Spergularia heldreichii, Teucrium asiaticum, Teucrium capitatum subsp. majoricum, Teucrium subspinosum, Thymelaea velutina, Vicia bifoliolata, Viola stolonifera Anthyllis hystrix, Arum pictum, Asplenium balearicum, Asplenium trichomanes subsp. inexpectans, Astragalus balearicus, Bellium bellidioides, Carduncellus balearicus, Carex rorulenta, Carlina corymbosa subsp. major, Chelidonium majus, Crepis triasii, Cressa Crocus cambessedesii, Cyclamen balearicum, Cymbalaria fragilis, Digitalis minor, Epipactis microphylla, Euphorbia maresii subsp. maresii, Helicodiceros muscivorus, Launaea cervicornis, Leucojum aestivum subsp. pulchellum, Limonium companyonis, Limonium minoricense, Limonium minutum, Limonium saxicola, Limonium tamarindanum, Lotus tetraphyllus, Lysimachia minoricensis, Micromeria cordata, Micromeria filiformis, Micromeria rodriguezii, Paeonia cambessedesii, Pastinaca lucida, Polycarpon colomense, Polycarpon dunense, Romulea assumptionis, Santolina chamaecyparissus subsp. magonica, Scrophularia ramosissima, Senecio rodriguezii, Sibthorpia africana, Silene mollissima, Sonchus montanus, Teucrium asiaticum, Teucrium capitatum subsp. majoricum, Teucrium subspinosum, Thymelaea velutina, Viola stolonifera Anthyllis hystrix, Aristolochia clematitis, Aristolochia paucinervis, Arum pictum, Asplenium balearicum, Astragalus balearicus, Bellium bellidioides, Calicotome villosa, Carduncellus balearicus, Carex rorulenta, Carlina corymbosa subsp. major, Cneorum tricoccon, Cyclamen balearicum, Digitalis minor, Epipactis microphylla, Helicodiceros muscivorus, Launaea cervicornis, Leucojum aestivum subsp. pulchellum, Limonium companyonis, Limonium minoricense, Limonium minutum, Limonium saxicola, Limonium tamarindanum, Lomelosia cretica, Lotus tetraphyllus, Lysimachia minoricensisMicromeria cordata, Micromeria filiformis, Micromeria rodriguezii, Ononis crispa, Orobanche foetida, Orobanche rumseiana, Orobanche santolinae, Romulea assumptionis, Santolina chamaecyparissus subsp. magonica, Scrophularia ramosissima, Senecio rodriguezii, Sonchus montanus, Teucrium capitatum subsp. majoricum, Teucrium subspinosum, Vicia bifoliolata, Vincetoxicum hirundinaria var. balearicum, Viola stolonifera Islands and plants: preservation and understanding of lora on Mediterranean islands Es Murtar Increase of the distribution scope Actions A2. Detailed cartography of the affected species distribution C2. Removal of tracks and uncontrolled accesses C3. Planting of native species to regenerate the vegetation C4. Construction of bridges on temporary Mediterranean torrents D6. Organisation of informative and civic participation sessions A3. Identification and cartography of the accesses and tracks in the affected areas C2. Removal of tracks and uncontrolled accesses C.3 Planting of native species to regenerate the vegetation C4. Construction of bridges on temporary Mediterranean torrents D6. Organisation of informative and civic participation sessions Table 7. Some of the main results of the LIFE+ RENEIX project and their relationship with actions, habitats and species of common interest Results Results Construction or installation of ethnological elements List of most suitable plants for recovery of vegetation Es Alocs – El Pilar Pas d’en Revull Es Murtar Binimel·là – Cala Mica Es Alocs – El Pilar Pas d’en Revull Binimel·là – Cala Mica Es Alocs – El Pilar 146 Reclamation Local population involvement Visual identification of project Pproject's information spreading Es Murtar Es Murtar Es Alocs – El Pilar Pas d’en Revull - Actions C1. Construction of dry stone walls using traditional techniques C4. Construction of bridges over temporary Mediterranean torrents C5. Construction and installation of traditional gates and barriers Habitats 1240 , 1410 , 1510 *, 2120, 2210, 2220 , 2230 , 2240, 2250 *, 2260, 2270 *, 3140 , 3170 *, 3290, 5210, 5320 , 5330 , 5430 , 6220 * , 6420, 8210, 8220, 92D0 , 9320 , 9340, 9540 A4. Selection of species for the recovery of vegetation C3. Planting of native species to regenerate the vegetation 1240 , 1410 , 1510 *, 2120, 2210, 2220 , 2230 , 2240, 2250 *, 2260, 2270 *, 3140 , 3170 *, 3290, 5210, 5320 , 5330 , 5430 , 6220 * , 6420, 8210, 8220, 92D0 , 9320 , 9340, 9540 A2. Detailed cartography of the affected species distribution A4. Selection of species for the recovery of vegetation C2. Removal of tracks and uncontrolled accesses C3. Planting of native species to regenerate the vegetation A2. Detailed cartography of the affected species distribution C2. Removal of tracks and uncontrolled accesses C3. Planting of native species to regenerate the vegetation D6. Organisation of informative and civic participation sessions C6. Landscape recovering in the area of Es Murtar and regeneration of the fossil dune system E3. Establishment of the project's Monitoring Board Species Asplenium trichomanes subsp. inexpectans, Bellium bellidioides, Carduncellus balearicus, Carlina corymbosa subsp. major, Chelidonium majus, Cyclamen balearicum, Leucojum aestivum subsp. pulchellum, Limonium companyonis, Limonium minoricense, Limonium minutum, Limonium saxicola, Limonium tamarindanum, Lotus tetraphyllus, Lysimachia minoricensis, Paeonia cambessedesii, Pastinaca lucidaSantolina chamaecyparissus subsp. magonica, Scrophularia ramosissima, Senecio rodriguezii, Teucrium asiaticum, Teucrium capitatum subsp. majoricum, Teucrium subspinosum, Viola stolonifera Anacamptis morio subsp. longicornu, Anthyllis hystrix, Aristolochia clematitis, Aristolochia paucinervis, Arum pictum, Asplenium balearicum, Asplenium trichomanes subsp. inexpectans, Astragalus balearicus, Avena barbata subsp. castellana, Bellium bellidioides, Brimeura fastigiata, Calicotome villosa, Carduncellus balearicus, Carex rorulenta, Carlina corymbosa subsp. major, Chelidonium majus, Cneorum tricoccon, Coronilla glauca, Coronilla montserratii, Crepis triasii,Cressa cretica, Crocus cambessedesii, Cyclamen balearicum,Cymbalaria aequitriloba,Cymbalaria fragilis,Digitalis minor, Echinophora spinosa, Elatine macropoda, Epipactis microphylla, Equisetum telmateia, Euphorbia maresii subsp. maresii, Exaculum pusillum, Helicodiceros muscivorus, Hippocrepis balearica,Hypericum balearicum, Launaea cervicornis, Leucojum aestivum subsp. pulchellum, Limonium companyonis, Limonium minoricense, Limonium minutum, Limonium saxicola, Limonium tamarindanum, Lomelosia cretica, Lotus tetraphyllus, Lysimachia minoricensis, Matthiola tricuspidata, Melissa officinalis, Micromeria cordata, Micromeria filiformis, Micromeria rodriguezii, Ononis crispa, Ophrys balearica, Orobanche cernua, Orobanche foetida, Orobanche rumseiana, Orobanche santolinae, Paeonia cambessedesii, Paronychia capitata, Pastinaca lucida, Phlomis italica, Polycarpon colomense, Polycarpon dunense, Romulea assumptionis, Santolina chamaecyparissus subsp. magonica, Scrophularia auriculata subsp. pseudoauriculata, Scrophularia ramosissima, Senecio rodriguezii, Serapias nurrica, Sibthorpia africana, Silene mollissima, Sonchus montanus, Spergularia heldreichii, Teucrium asiaticum, Teucrium capitatum subsp. majoricum, Teucrium subspinosum, Thapsia gymnesica, Thymelaea velutina, Vicia bifoliolata, Vincetoxicum hirundinaria var. balearicum, Viola stolonifera 1240 , 1410 , 1510 *, 2120, 2210, 2220 , 2230 , 2240, 2250 *, 2260, 2270 *, 3140 , 3170 *, 3290, 5210, 5320 , 5330 , 5430 , 6220 * , 6420, 8210, 8220, 92D0 , 9320 , 9340, 9540 Coronilla montserratii, Echinophora spinosa, Matthiola tricuspidata, Ononis crispa, Orobanche foetida, Polycarpon colomense, Polycarpon dunense, Scrophularia ramosissima, Senecio rodriguezii, Thymelaea velutina 1240 , 1410 , 1510 *, 2120, 2210, 2220 , 2230 , 2240, 2250 *, 2260, 2270 *, 3140 , 3170 *, 3290, 5210, 5320 , 5330 , 5430 , 6220 * , 6420, 8210, 8220, 92D0 , 9320 , 9340, 9540 Arum pictum, Astragalus balearicus, Bellium bellidioides, Calicotome villosa, Cneorum tricoccon, Crocus cambessedesii, Exaculum pusillum, Launaea cervicornis, Leucojum aestivum subsp. pulchellum, Limonium companyonis, Lotus tetraphyllus, Micromeria filiformis, Micromeria rodriguezii, Ononis crispa, Orobanche foetida, Polycarpon colomense, Romulea assumptionis, Scrophularia ramosissima, Senecio rodriguezii, Sonchus montanus, Teucrium capitatum subsp. majoricum, Teucrium subspinosum, Vicia bifoliolata 1240 , 1410 , 1510 *, 2120, 2210, 2220 , 2230 , 2240, 2250 *, 2260, 2270 *, 3140 , 3170 *, 3290, 5210, 5320 , 5330 , 5430 , 6220 * , 6420, 8210, 8220, 92D0 , 9320 , 9340, 9540 Anthyllis hystrix, Aristolochia clematitis, Aristolochia paucinervis, Arum pictum, Asplenium balearicum, Asplenium trichomanes subsp. inexpectans, Astragalus balearicus, Bellium bellidioides, Calicotome villosa, Carduncellus balearicus, Carex rorulenta, Carlina corymbosa subsp. major, Chelidonium majus, Cneorum tricoccon, Coronilla montserratii, Crepis triasii, Crocus cambessedesii, Cyclamen balearicum, Digitalis minor, Echinophora spinosa, Epipactis microphylla, Euphorbia maresii subsp. maresii, Exaculum pusillum, Helicodiceros muscivorus, Hippocrepis balearica, Launaea cervicornis, Leucojum aestivum subsp. pulchellum, Limonium companyonis, Limonium minoricense, Limonium minutum, Limonium saxicola, Limonium tamarindanum, Lomelosia cretica, Lotus tetraphyllus, Lysimachia minoricensis, Matthiola tricuspidata, Micromeria cordata, Micromeria filiformis, Micromeria rodriguezii, Ononis crispa, Orobanche cernua, Orobanche foetida, Orobanche rumseiana, Orobanche santolinae, Paeonia cambessedesii, Pastinaca lucida, Phlomis italica, Polycarpon colomense, Polycarpon dunense, Romulea assumptionis, Santolina chamaecyparissus subsp. magonica, Scrophularia ramosissima, Senecio rodriguezii, Sibthorpia africana, Silene mollissima, Sonchus montanus, Spergularia heldreichii, Teucrium asiaticum, Teucrium capitatum subsp. majoricum, Teucrium subspinosum, Thapsia gymnesica, Thymelaea velutina, Vicia bifoliolata, Vincetoxicum hirundinaria var. balearicum, Viola stolonifera D1. Creation of the project's image - - D2. Developing of the project's website E3. Establishment of the project's Monitoring Board - - D6. Organisation of informative and civic participation sessions C3. Planting of native species to regenerate the vegetation E8. Communication and coordination with the land owners and affected social sectors D5. Deterrent campaign for drivers of motor vehicles in the natural environment Es Murtar Binimel·là – Cala Mica Es Alocs – El Pilar Pas d’en Revull he LIFE+ RENEIX project Development of methodologies and techniques to regenerate dune habitats Area Binimel·là – Cala Mica Area Dissemination of the flora and habitats importance - Landscape restoration - Actions D3. Publishing of material focused on the increase of awareness on biodiversity and Natura 2000 network designed to younger audiences D8. Production of a DVD on LIFE project D9. On-line publishing about the biodiversity and endemic flora concentration focuses on the Island D10. Information and constant raising of awareness of society through both local and regional mass media D13. Installation of information panels about the LIFE project E3. Establishment of the project's Monitoring Board Habitats Species - - 1240 , 1410 , 1510 *, 2120, 2210, 2220 , 2230 , 2240, 2250 *, 2260, 2270 *, 3140 , 3170 *, 3290, 5210, 5320 , 5330 , 5430 , 6220 * , 6420, 8210, 8220, 92D0 , 9320 , 9340, 9540 D5. Deterrent campaign for drivers of motor vehicles in the natural environment E2. Establishment of the project's Scientific Board 1240 , 1410 , 1510 *, 2120, 2210, 2220 , 2230 , 2240, 2250 *, 3140 , 3290, 5210, 5320 , 5330 , 5430 , 6220 * , 8210, 8220, 92D0 , 9320 147 A2. Detailed cartography of the affected species distribution C2. Removal of tracks and uncontrolled accesses C3. Planting of native species to regenerate the vegetation C4. Construction of bridges over temporary Mediterranean torrents D6. Organisation of informative and civic participation sessions Inclusion of geological values Binimel·là – Cala Mica Es Murtar Improvement on floristic knowledge Binimel·là – Cala Mica Es Alocs – El Pilar A4. Selection of species for the recovery of vegetation A2. Detailed cartography of the affected species distribution Pas d’en Revull Es Murtar Exchange of experiences and results Binimel·là – Cala Mica Es Alocs – El Pilar Pas d’en Revull D7. Planning of botanical routes within the flora microreserve in Pas d’en Revull and El Pilar area D11. Dissemination of scientific results E6. Networking with other LIFE projects E2. Establishment of the project's Scientific Board E3. Establishment of the project's Monitoring Board 1240 , 1410 , 1510 *, 2120, 2210, 2220 , 2230 , 2240, 2250 *, 2260, 2270 *, 3140 , 3170 *, 3290, 5210, 5320 , 5330 , 5430 , 6220 * , 6420, 8210, 8220, 92D0 , 9320 , 9340, 9540 - Anacamptis morio subsp. longicornu, Anthyllis hystrix, Aristolochia clematitis, Aristolochia paucinervis, Arum pictum, Asplenium balearicum, Asplenium trichomanes subsp. inexpectans, Astragalus balearicus, Avena barbata subsp. castellana, Bellium bellidioides, Brimeura fastigiata, Calicotome villosa, Carduncellus balearicus, Carex rorulenta,Carlina corymbosa subsp. major, Chelidonium majus, Cneorum tricoccon, Coronilla glauca, Coronilla montserratii, Crepis triasii,Cressa cretica, Crocus cambessedesii, Cyclamen balearicum,Cymbalaria aequitriloba,Cymbalaria fragilis,Digitalis minor, Echinophora spinosa, Elatine macropoda, Epipactis microphylla, Equisetum telmateia, Euphorbia maresii subsp. maresii, Exaculum pusillum, Helicodiceros muscivorus, Hippocrepis balearica,Hypericum balearicum, Launaea cervicornis, Leucojum aestivum subsp. pulchellum, Limonium companyonis, Limonium minoricense, Limonium minutum, Limonium saxicola, Limonium tamarindanum, Lomelosia cretica, Lotus tetraphyllus, Lysimachia minoricensis, Matthiola tricuspidata, Melissa officinalis, Micromeria cordata, Micromeria filiformis, Micromeria rodriguezii, Ononis crispa, Ophrys balearica, Orobanche cernua, Orobanche foetida, Orobanche rumseiana, Orobanche santolinae, Paeonia cambessedesii, Paronychia capitata, Pastinaca lucida, Phlomis italica, Polycarpon colomense, Polycarpon dunense, Romulea assumptionis, Santolina chamaecyparissus subsp. magonica, Scrophularia auriculata subsp. pseudoauriculata, Scrophularia ramosissima, Senecio rodriguezii, Serapias nurrica, Sibthorpia africana, Silene mollissima, Sonchus montanus, Spergularia heldreichii, Teucrium asiaticum, Teucrium capitatum subsp. majoricum, Teucrium subspinosum, Thapsia gymnesica, Thymelaea velutina, Vicia bifoliolata, Vincetoxicum hirundinaria var. balearicum, Viola stolonifera Anthyllis hystrix, Arum pictum, Asplenium balearicum, Bellium bellidioides, Brimeura fastigiata, Carduncellus balearicus, Carex rorulenta, Carlina corymbosa subsp. major, Crocus cambessedesii, Cyclamen balearicum, Cymbalaria aequitriloba, Digitalis minor, Euphorbia maresii subsp. maresii, Helicodiceros muscivorus, Launaea cervicornis, Leucojum aestivum subsp. pulchellum, Limonium companyonis, Limonium minoricense, Limonium minutum, Limonium tamarindanum, Lotus tetraphyllus, Micromeria cordata, Micromeria filiformis, Micromeria rodriguezii, Orobanche rumseiana, Orobanche santolinae, Paronychia capitata, Pastinaca lucida, Phlomis italica, Polycarpon colomense, Romulea assumptionis, Santolina chamaecyparissus subsp. magonica, Scrophularia ramosissima, Senecio rodriguezii, Sonchus montanus, Teucrium capitatum subsp. majoricum, Teucrium subspinosum, Vicia bifoliolata, Vincetoxicum hirundinaria var. balearicum Anacamptis morio subsp. longicornu, Anthyllis hystrix, Aristolochia clematitis, Aristolochia paucinervis, Arum pictum, Asplenium balearicum, Asplenium trichomanes subsp. inexpectans, Astragalus balearicus, Avena barbata subsp. castellana, Bellium bellidioides, Brimeura fastigiata, Calicotome villosa, Carduncellus balearicus, Carex rorulenta, Carlina corymbosa subsp. major, Chelidonium majus, Cneorum tricoccon, Coronilla glauca, Coronilla montserratii, Crepis triasii,Cressa cretica, Crocus cambessedesii, Cyclamen balearicum,Cymbalaria aequitriloba,Cymbalaria fragilis,Digitalis minor, Echinophora spinosa, Elatine macropoda, Epipactis microphylla, Equisetum telmateia, Euphorbia maresii subsp. maresii, Exaculum pusillum, Helicodiceros muscivorus, Hippocrepis balearica,Hypericum balearicum, Launaea cervicornis, Leucojum aestivum subsp. pulchellum, Limonium companyonis, Limonium minoricense, Limonium minutum, Limonium saxicola, Limonium tamarindanum, Lomelosia cretica, Lotus tetraphyllus, Lysimachia minoricensis, Matthiola tricuspidata, Melissa officinalis, Micromeria cordata, Micromeria filiformis, Micromeria rodriguezii, Ononis crispa, Ophrys balearica, Orobanche cernua, Orobanche foetida, Orobanche rumseiana, Orobanche santolinae, Paeonia cambessedesii, Paronychia capitata, Pastinaca lucida, Phlomis italica, Polycarpon colomense, Polycarpon dunense, Romulea assumptionis, Santolina chamaecyparissus subsp. magonica, Scrophularia auriculata subsp. pseudoauriculata, Scrophularia ramosissima, Senecio rodriguezii, Serapias nurrica, Sibthorpia africana, Silene mollissima, Sonchus montanus, Spergularia heldreichii, Teucrium asiaticum, Teucrium capitatum subsp. majoricum, Teucrium subspinosum, Thapsia gymnesica, Thymelaea velutina, Vicia bifoliolata, Vincetoxicum hirundinaria var. balearicum, Viola stolonifera - Islands and plants: preservation and understanding of lora on Mediterranean islands Results he LIFE+ RENEIX project REFERENCES Allès, M. 2010. 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Restoration of 152 Islands and plants: preservation and understanding of lora on Mediterranean islands Appendix 1. Habitats included in the Habitats Directive of the EU and taxa of conservation interest of the vascular lora they hold Habitat 1130 Estuaries 1150 * Coastal lagoons 1160 Large shallow inlets and bays 1210 Annual vegetation of drift lines 1240 Vegetated sea cliffs of the Mediterranean coasts with endemic Limonium spp. 1310 Salicornia and other annuals colonising mud and sand 1410 Mediterranean salt meadows (Juncetalia maritimi) 1510 * Mediterranean salt steppes (Limonietalia) 2120 Shifting dunes along the shoreline with Ammophila arenaria (white dunes) 2210 Crucianellion maritimae fixed beach dunes 2220 Dunes with Euphorbia terracina 2230 Malcolmietalia dune grasslands 2230 Malcolmietalia dune grasslands 2240 Brachypodietalia dune grasslands with annuals 2250 * Coastal dunes with Juniperus spp. 2260 Cisto-Lavenduletalia dune sclerophyllous scrubs 2270 * Wooded dunes with Pinus pinea and/or Pinus pinaster 3120 Oligotrophic waters containing very few minerals generally on sandy soils of the West Mediterranean with Isoetes spp. 3130 Oligotrophic to mesotrophic standing waters with vegetation of the Littorelletea uniflorae and/or Isoeto-Nanojuncetea 3140.Oligotrophic standing waters with benthos vegetation of Chara spp. Taxa Zostera noltii Hornem. Althenia orientalis (Tzvelev) García Murillo et Talavera Tripolium pannonicum (Jacq.) Dobrocz. Althenia orientalis (Tzvelev) García Murillo et Talavera Salicornia emerici Duval-Jouve Atriplex tornabenei Tineo ex Guss. Anthemis secundiramea Biv. Arum pictum L. f. Limonium artruchium Erben Limonium biflorum (Pignatti) Pignatti Limonium fontqueri (Pau) L. Llorens Limonium minoricense Erben Limonium minutum (L.) Chaz. Limonium saxicola Erben Limonium tamarindanum Erben Orobanche iammonensis Pujadas et P. Fraga Polycarpon colomense Porta Senecio rodriguezii Willk. ex J.J. Rodr. Conservation interest (1) Less than five populations Less than five populations Less than five populations Scattered populations within the whole distribution area Less than five populations Less than five populations Single population within the Iberian flora Endemic Endemic Endemic Endemic Endemic Endemic Endemic Endemic Endemic Endemic Endemic Tripolium pannonicum (Jacq.) Dobrocz. Less than five populations Allium coppoleri Tineo Tripolium pannonicum (Jacq.) Dobrocz. Cressa cretica L. Less than five populations Less than five populations Less than five populations Echinophora spinosa L. Less than five populations Echinophora spinosa L. Cyperus capitatus Vand. Otanthus maritimus (L.) Hoffmanns. Scrophularia ramosissima Loisel. Coronilla montserratii P. Fraga et Rosselló Polycarpon dunense P. Fraga et Rosselló Matthiola tricuspidara (L.) R. Br. Senecio rodriguezii Willk. ex J.J. Rodr. Less than five populations Single population Single population Endemic Endemic Endemic Endemic Endemic Coronilla montserratii P. Fraga et Rosselló Coronilla montserratii P. Fraga et Rosselló Catapodium hemipoa Delile ex Spreng. Cneorum tricoccon L. Coronilla montserratii P. Fraga et Rosselló Catapodium hemipoa Delile ex Spreng. Echium arenarium Guss. Euphorbia nurae P. Fraga et Rosselló Ononis crispa L. Orobanche foetida Poir. Scrophularia ramosissima Loisel. Thymelaea velutina (Pourr. ex Cambess.) Endl. Coronilla montserratii P. Fraga et Rosselló Isoetes histrix Bory Endemic Endemic Less than five populations Single population Endemic Less than five populations Single population Endemic Endemic Less than five populations Endemic Endemic Endemic Less than five populations Acis autumnalis (L.) Sweet Isoetes histrix Bory Narrow distribution Less than five populations Potamogeton crispus L. Potamogeton pusillus L. Ranunculus tricophyllus Chaix Bupleurum tenuissimum L. Callitriche obtusangula Le Gall Centunculus minimus L. Corrigiola littoralis L. Damasonium bourgaei Coss. Elatina macropoda Guss. Eleocharis acicularis Roem. et Schult. Exaculum pusillum (Lam.) Caruel Galium debile Desv. Isoetes velata A. Braun 3170 * Mediterranean temporary ponds Lythrum tribracteatum Spreng. Marsilea strigosa Willd. Myriophyllum alterniflorum DC. Pilularia minuta Durieu ex A. Braun Polygonum romanum subsp. balearicum Raffaelli et L. Villar Pulicaria vulgaris Gaertn. Ranunculus tricophyllus Chaix Teucrium scordium L. Thymelaea gussonei Boreau Trifolium micranthum VIv. Trifolium ornithopodioides L. Verbena supina L. Zannichellia obtusifolia Talavera, Garcia Murillo et Smit Calystegia sylvatica (Kit.) Griseb. Equisetum telmateia Ehrh. 3290 Intermittently flowing Mediterranean rivers Zannichellia obtusifolia Talavera, Garcia Murillo et Smit of the Paspalo-Agrostidion Zannichellia peltata Bertol. Allium subvillosum Salzm. Ex Schult et Schult f. 153 Less than five populations Less than five populations Less than five populations Less than five populations Less than five populations Less than five populations Less than five populations Small and scattered populations Small and scattered populations Single population Small and scattered populations Small and scattered populations Small and scattered populations Small and scattered populations Less than five populations Single population Less than five populations Endemic Less than five populations Less than five populations Less than five populations Less than five populations Less than five populations Less than five populations Small and scattered populations Small and scattered populations Single population Less than five populations Small and scattered population Less than five populations Small and scattered populations he LIFE+ RENEIX project Habitat Taxa Arum pictum L. f. Bellium artrutxensis P. Fraga et Rosselló Bellium bellidioides L. Crocus cambessedesii Gay Helicodiceros muscivorus (L. f.) Engl. Micromeria filiformis (Aiton) Benth. 5210 Arborescent matorral with Juniperus spp. Micromeria rodriguezii Freyn. et Janka Polycarpon colomense Porta Romulea assumptionis Garcias Font Teucrium capitatum subsp. majoricum (Rouy) T. Navarro et Rosúa Teucrium subspinosum (Pourr.) Willd. Aristolochia bianori Sennen et Pau Crocus cambessedesii Gay Helicodiceros muscivorus (L. f.) Engl. Polycarpon colomense Porta 5320 Low formations of Euphorbia close to cliffs Malva minoricensis Cambess. Micromeria filiformis (Aiton) Benth. 5320 Low formations of Euphorbia close to cliffs Micromeria rodriguezii Freyn. et Janka Teucrium capitatum subsp. majoricum (Rouy) T. Navarro et Rosúa Teucrium subspinosum (Pourr.) Willd. Thapsia gymnesica Rosselló et A. Pujadas Allium subvillosum Salzm. Ex Schult et Schult f. Bellium artrutxensis P. Fraga et Rosselló Bellium bellidioides L. Crocus cambessedesii Gay Cyclamen balearicum Willk. Daphne rodriguezii Teixidor Helicodiceros muscivorus (L. f.) Engl. Euphorbia nurae P. Fraga et Rosselló Fumana juniperina (Lag. ex Dunal) Pau Leuzea conifera (L.) DC. Lotus tetraphyllus L. Malva minoricensis Cambess. Micromeria filiformis (Aiton) Benth. Micromeria rodriguezii Freyn. et Janka 5330 Thermo-Mediterranean and pre-desert Ononis crispa L. scrub Ophrys balearica Delforge Orobanche rumseiana Pujadas et P. Fraga Phlomis italica L. Rhamnus ludovici-salvatoris Chodat Romulea assumptionis Garcias Font Santolina chamaecyparissus subsp. magonica O. Bolòs, Molin. et P. Monts. Serapias nurrica Corrias Teline monspessulana (L.) K. Koch Teucrium balearicum (Pau) Castrov. et Bayón Teucrium capitatum subsp. majoricum (Rouy) T. Navarro et Rosúa Teucrium subspinosum (Pourr.) Willd. 5330 Thermo-Mediterranean and pre-desert Thapsia gymnesica Rosselló et A. Pujadas scrub Thymelaea velutina (Pourr. ex Cambess.) Endl. Valantia hispida L. Vicia bifoliolata J.J. Rodr. Viola arborescens L. Anthyllis hystrix (Willk. ex Barc.) Cardona, Contandr. et Sierra Astragalus balearicus Chater Bellium bellidioides L. Crocus cambessedesii Gay Lotus fulgurans (Porta) Sokolov Helicodiceros muscivorus (L. f.) Engl. Euphorbia maresii Knoche Carduncellus balearicus (J.J. Rodr.) G. López Malva minoricensis Cambess. Launaea cervicornis (Boiss.) Font Quer et Rothm. Lotus tetraphyllus L. 5430 Endemic phryganas of the EuphorbioMicromeria filiformis (Aiton) Benth. Verbascion Micromeria cordata (Moris ex Bertol.) Moris Micromeria rodriguezii Freyn. et Janka Orobanche santolinae Loscos et J. Pardo Polycarpon colomense Porta Romulea assumptionis Garcias Font Santolina chamaecyparissus subsp. magonica O. Bolòs, Molin. et P. Monts. Senecio rodriguezii Willk. ex J.J. Rodr. Teucrium balearicum (Pau) Castrov. et Bayón Teucrium capitatum subsp. majoricum (Rouy) T. Navarro et Rosúa Teucrium subspinosum (Pourr.) Willd. Thapsia gymnesica Rosselló et A. Pujadas Thymelaea velutina (Pourr. ex Cambess.) Endl. Aegilops neglecta Req. ex Bertol. 6220 * Pseudo-steppe with grasses and annuals Allium nigrum L. of the Thero-Brachypodietea Rostraria pubescens (Lam.) Trin. 154 Conservation interest (1) Endemic Endemic Endemic Endemic Endemic Endemic Endemic Endemic Endemic Endemic Endemic Endemic Endemic Endemic Endemic Endemic Endemic Endemic Endemic Endemic Endemic Small and scattered populations Endemic Endemic Endemic Endemic Endemic Endemic Endemic Single population Single population Endemic Endemic Endemic Endemic Endemic Endemic Endemic Endemic Endemic Endemic Endemic Endemic Single population Endemic Endemic Endemic Endemic Endemic Less than five populations Endemic Less than five populations Endemic Endemic Endemic Endemic Endemic Endemic Endemic Endemic Endemic Endemic Endemic Endemic Endemic Endemic Less than five population Endemic Endemic Endemic Endemic Endemic Endemic Endemic Endemic Endemic Small and scattered populations Single population Single population Islands and plants: preservation and understanding of lora on Mediterranean islands Habitat Taxa Crocus cambessedesii Gay Leucojum aestivum subsp. pulchellum (Salisb.) Briq. Neatostema apulum (L.) I.M. Johnst. Ononis alopecuroides L. Althaea officinalis L. Lotus gracile Salisb. Elytrigia atherica (Link) Kerguélen 6420 Mediterranean tall humid herb grasslands Leucojum aestivum subsp. pulchellum (Salisb.) Briq. of the Molinio-Holoschoenion Oenanthe lachenalii C.C. Gmel. Ranunculus repens L. Sonchus aquatilis Pourr. Allium antonii-bolosii Palau Asplenium petrarchae (Guérin) DC. Bellium bellidioides L. Carex rorulenta Porta Brimeura fastigiata (Viv.) Chouard Chelianthes acrostica (Balbis) Tod. Coronilla glauca L. Crepis triasii (Camb.) Nyman Cyclamen balearicum Willk. Cymbalaria aequitriloba (Viv.) A. Cheval 8210 Calcareous rocky slopes with chasmophytic Cymbalaria fragilis J.J. Rodr. Digitalis minor L. vegetation Erodium reichardii (Murray) DC. Euphorbia maresii Knoche Helichrysum ambiguum (L.) C. Presl Hippocrepis balearica Jacq. Hypericum balearicum L. Lavatera olbia L. Magydaris pastinacea subsp. femeniesii O. Bolòs et Vigo Matthiola tricuspidara (L.) R. Br. Micromeria filiformis (Aiton) Benth. Micromeria cordata (Moris ex Bertol.) Moris Paeonia cambessedesii (Willk.) Willk. Pastinaca lucida L. Romulea assumptionis Garcias Font Lomelosia cretica (L.) Greuter et Burdet 8210 Calcareous rocky slopes with chasmophytic Scilla obtusifolia (Guss.) Bég Sibthorpia africana L. vegetation Silene mollissima (L.) Pers. Teucrium asiaticum L. Teucrium capitatum subsp. majoricum (Rouy) T. Navarro et Rosúa Asplenium balearicum Shivas Bellium bellidioides L. Brimeura fastigiata (Viv.) Chouard Cosentinia vellaea (Aiton) Tod. Cymbalaria aequitriloba (Viv.) A. Cheval Digitalis minor L. 8220 Siliceous rocky slopes with chasmophytic Micromeria cordata (Moris ex Bertol.) Moris Pastinaca lucida L. vegetation Romulea assumptionis Garcias Font Romulea revelieri Jordan et Fourr. Silene mollissima (L.) Pers. Teucrium capitatum subsp. majoricum (Rouy) T. Navarro et Rosúa Trigonella monspeliaca L. Aristolochia clematitis L. Leucojum aestivum subsp. pulchellum (Salisb.) Briq. Tamarix boveana Bunge 92D0 Southern riparian galleries and thickets (Nerio-Tamaricetea and Securinegion tinctoriae) Urtica atrovirens Loisel. Viola stolonifera J.J. Rodr. Vitex agnus-castus L. Sonchus montanus (Willk.) Rosselló Anemone coronaria L. 9320 Olea and Ceratonia forests Cyclamen balearicum Willk. Lotus tetraphyllus L. Asplenium trichomanes subsp. Quadrivalens D.E. Meyer Cephalanthera damasonium (Mill.) Druce Cyclamen balearicum Willk. Leucojum aestivum subsp. pulchellum (Salisb.) Briq. 9340 Quercus ilex and Quercus rotundifolia Paeonia cambessedesii (Willk.) Willk. forests Quercus suber L. Viburnum tinus L. Viola alba Bess. Viola stolonifera J.J. Rodr. 9540 Mediterranean pine forests with endemic Juniperus oxycedrus subsp. oxycedrus L. Pinus pinaster Aiton Mesogean pines 155 Conservation interest (1) Endemic Endemic Less than five populations Single population Small and scattered populations Single population Single population Endemic Less than five populations Less than five populations Single population Endemic Less than five populations Endemic Endemic Endemic Single population Single population Endemic Endemic Endemic Endemic Endemic Endemic Endemic Endemic Endemic Endemic Single population Endemic Less than five populations Endemic Endemic Endemic Endemic Endemic Endemic Single population Endemic Endemic Endemic Endemic Endemic Endemic Endemic Single population Endemic Endemic Endemic Endemic Endemic Endemic Endemic Endemic Single population Single population Endemic Single population Endemic Endemic Small and scattered populations Endemic Small and scattered populations Endemic Endemic Less than five localities known Single population Endemic Endemic Endemic Small and scattered populations Single population Single population Endemic Single population Relict population in the Balearic Islands he LIFE+ RENEIX project 156 Islands and plants: preservation and understanding of lora on Mediterranean islands TUSCAN ARCHIPELAGO FLORA: FROM GENESIS TO CONSERVATION1 Angelino Carta1, Gianni Bedini1, Tommaso Guidi2 and Bruno Foggi2 Department of Biology, Botanic Garden, University of Pisa, via Luca Ghini 5, I-56125, Pisa, Italy. 2 Department of Evolutionary Biology, Laboratories of Botany, University of Florence, via La Pira, 4, I-50121, Florence, Italy. 1 Abstract he Tuscan Archipelago consists of seven islands and about twenty islets and is one of the most interesting areas in the Tyrrhenian Sea from a naturalistic and anthropological point of view. he Archipelago is geologically related to the evolution of the northern Apennine and the Cyrno-Sardinian block. Currently, the lora of the entire Tuscan Archipelago is made up of 1,300 taxa, 80% of which are herbaceous, relecting the Mediterranean setting of the area and the prevalence of secondary vegetation forms; 1.2% of taxa are endemic, most of which are related to Cyrno-Sardinian elements, suggesting that the Tuscan Archipelago represents a bridge between the loristic CyrnoSardinian territories and the Italian peninsula. Human inluence on the natural environment has been massive since Roman times (5th century B.C.), and more recently changes in land use and the development of tourism have increased the level of threat upon the lora. Following the constitution of the National Park of the Tuscan Archipelago, several activities, e.g. LIFE Natura Projects, were launched to contrast the loss of biodiversity due to (1) habitat damage, (2) invasion of foreign plants and animals, and (3) change in ecological patterns. In situ conservation measures are backed by ex situ programmes in an integrated fashion, both as a safety tool and as source of material for reintroduction projects. hrough this study we try to suggest further opportunities for new strategies of conservation. Keywords: Tuscan Archipelago, endemic lora, National Park, in situ conservation, ex situ conservation, seed banks. Corresponding author: Angelino Carta (acarta@biologia.unipi.it) 157 Tuscan Archipelago lora: from genesis to conservation “Islands are an enormous source of information and unparalleled testing sites for several scientiic theories. But this great relevance places an obligation on us. heir biota is vulnerable and precious. We must protect it. We have an obligation to hand over this singular fauna and lora with a minimum of loss from generation to generation. What is once lost is lost forever because a large extension of the island biota is unique. he Island’s fauna ofers us a great deal of information both scientiically and aesthetically. Let us do our share to live up to our obligations for their permanent preservation”. E. Mayr, 1967: 374 INTRODUCTION he Tuscan Archipelago is made up of seven islands: Elba, Giglio, Capraia, Montecristo, Pianosa, Giannutri and Gorgona; furthermore there are several islets, less than 10 ha in size (Fig. 1). All islands have been explored several times over the last centuries. Between the 19th and 20th centuries Stèphen Sommier published the irst comprehensive study on the Tuscan Archipelago lora (Sommier, 1902, 1903). His work is considered one of the irst studies devoted to a group of small islands (Greuter, 1995). Starting from the mid-1900s, several reviews followed, like the completion of the loristic list of Montecristo (Paoli & Romagnoli, 1976) and Elba Island (Fossi Innamorati, 1983, 1989, 1991, 1994, 1997), the contributions by Baldini (1998, 2000, 2001) for Giglio, Pianosa and Giannutri respectively, by Foggi et al. (2001a) for Capraia. he islets’ lora was also studied (Baldini, 1990, 1991 and Foggi et al., 2009). Based on this data and on numerous loristic (Mannocci, 2004; Frangini et al., 2005, 2007; Borzatti & Mannocci, 2008; Carta et al., 2008a; Peruzzi et al., 2008) and taxonomic acquisitions (Signorini & Foggi, 1998; Peruzzi & Carta, 2011; Peruzzi & Carta, 2013), a review of the lora on these islands -currently under construction- was undertaken. Over recent decades the biota of the Tuscan Archipelago has undergone severe changes mostly due to socio-economic transformations, shared by all the Mediterranean islands (Delanoë et al., 1996), that increased the threat level over the lora. Since the initiation of the Tuscan Archipelago National Park (1996), several initiatives for the conservation of lora and related habitats have begun. heir goals are (1) to describe main patterns of plant diversity in the Archipelago, (2) to discuss major threats afecting plant diversity and the most important actions undertaken to contrast them and (3) to suggest further opportunities for new strategies of conservation. 158 Islands and plants: preservation and understanding of lora on Mediterranean islands Fig. 1. he Tuscan Archipelago. he islets are highlighted in the boxes. GENESIS OF THE ARCHIPELAGO AND ORIGIN OF THE FLORA he geological history of the Tuscan Archipelago begins in the Upper Oligocene, in connection with the evolution of northern Apennine and the Cyrno-Sardinian block (Carmignani et al., 1995; Bortolotti et al., 2001). he inluences of terrestrial connections among the Cyrno-Sardinian-block and the Ligurian-Provenzal areas are demonstrated by the current presence of both Cyrno-Sardinian and hyrrenian endemic qualities in the Tuscan Archipelago (Table 1) (Arrigoni, 1975; Bertacchi et al., 2005). During the last ice-age, some of the islands (Elba, Pianosa, Giglio, Giannutri) were an integral part of the peninsula: these links allowed the migration of southern Mediterranean species (Ranunculus bullatus L.) or boreal species (Ostrya carpinifolia Scop.), which are 159 Tuscan Archipelago lora: from genesis to conservation now present only on Elba island thanks to its mesophilous climate belt, nonexistent on other islands. Table 1. Endemic species belonging to the Corso-Sardinian and the hyrrhenian territories. Although it is diicult to reconstruct the geological events that could help us to recognize past links between islands and mainland, it is possible to ind some major patterns in the composition of the lora: (1) the Tuscan Archipelago lora is largely (70%) constituted by Mediterranean and Tethydic species present since late Tertiary (Arrigoni, 1975), (2) while some islands (Gorgona, Capraia and Montecristo) show loristic ainities with the Cyrno-Sardinian territories; others (Pianosa, Giglio, Giannutri) are clearly linked to the Tyrrhenian lands (Arrigoni et al., 2003), and (3) Elba island appears to be divided into two sectors: the west, with obvious ainities with the Cyrno-Sardinian territories, and the east, similar to the Ligurian-hyrrhenic territories (Foggi et al., 2006). Moreover, insularity set the stage for the diferentiation or conservation of species exclusive to the Archipelago, which eventually became endemic (Garbari, 1990). he percentage of endemic plants on the Tuscan Archipelago (about 1.2%), is very low compared with other Mediterranean islands, even more so on account of the high density of species (Greuter, 1995). he highest number of endemisms occurs on Elba and Capraia islands (Table 2). 160 Islands and plants: preservation and understanding of lora on Mediterranean islands Table 2. Endemic species exclusive to the Tuscan Archipelago. Many of them (e.g Viola corsica subsp. ilvensis) are related to Cyrno-Sardinian taxa, and only a few (e.g. Crocus ilvensis) to peninsular taxa. Very interesting evidence obtained from genetic analysis is the presence of L. capraria, the only endemic species found in almost all the Archipelago islands: contrary to what was suggested on the basis of morphological data, L. capraria seems to be closer to L. cossoni and L. purpurea rather than L. arcusangeli (Coppi et al., 2013). In addition to endemic species, there are species with an interesting disjunctive distribution scope, especially with a western or southern Mediterranean distribution that in the Tuscan Archipelago reach their eastern or northernmost locations as peripheral isolated plant populations. his is the result both of palaeobiogeographical inluences and the presence of considerable environmental diversity that supports rich diversity of ecological niches: such as, Cymbalaria aequitriloba (Viv.) Cheval. grows in shaded and wet rock communities; Gennaria diphylla (Link) Parl. in lowland therophytic grasslands; Gagea bohemica (Zauschn.) Schult. & Schult. f. in supramediterranean therophytic grasslands; Cneorum tricoccon L. in thermomediterranean maquis; Brassica procumbens (Poir.) O.E. Schultz in abandoned cultivations. he Tuscan Archipelago is also one of the richest areas of pteridophytic diversity in Tuscany, with signiicant populations of micropteridophytes of ephemeral wetlands (Carta et al., 2008a and b) and the presence of species of phytogeographical interest like Cosentinia vellea (Aiton) Tod. (Atzori, 2007), Asplenium balearicum Shivas (Foggi et al., 2001), Asplenium septentrionale (L.) Hofm. (Foggi et al., 2006), and Phyllitis sagittata (DC.) Guinea & Heywood (Baldini, 2000). 161 Tuscan Archipelago lora: from genesis to conservation DIVERSITY FACTORS AND FLORAL COMPOSITION OF THE ISLANDS Environmental and vegetation diversity determine loristic richness (Arrigoni et al., 2003). he lora around the entire Tuscan Archipelago consists of 1,300 taxa, scattered around the diferent islands as shown in Table 3. he inluence of land surface area on loristic diversity of the islands shows a logical increase in loristic diversity (Arrigoni et al., 2003). Table 3. Physiographical and loristic characters of the Tuscan Archipelago islands. Capraia and Giglio, of approximately the same size and with similar topographical-edaphic characters, show roughly the same loristic diversity. However, their loristic ainity (Fig. 2) is not signiicant, due to diferent geographical settings and the origin of their respective lora. he ainity indices for Elba are only partially indicative because its size, and consequently its lora, difer widely from the rest of the islands (Peruzzi et al., 2012). In fact, Elba can boast about having 80.23% of the entire Archipelago lora. Figure 2. Floristic similarity calculated using the Sorensen index (presence-absence data). 162 Islands and plants: preservation and understanding of lora on Mediterranean islands Only 132 species are present on all the islands. hese are mostly annual herbs and grasses, with Mediterranean, Euro-Mediterranean and EuroTethydic distribution; they mostly belong to marginal habitats and more or less xerophytic meadows (Arrigoni et al., 2003). he islets show a strong loristic autonomy to one another. No species is present on all the islets, while 90 species (i.e. about 50% of the total islet lora) are found on only one islet (Foggi et al., 2009b). From a chorological point of view (Table 4), there is a prevalence of Mediterranean and Tethydic elements. Nevertheless, the abundant presence of Euro-Mediterranean and Euro-Tethydic species reveals a rather northern Mediterranean loristic combination. Table 4. Percentage of major chorological groups in the Tuscan Archipelago lora. he distribution of the growth forms, the phenologic cycle and the ecological spectrum of the lora in the Archipelago (Table 5) relect the Mediterranean setting of the area and the prevalence of anthropogenic, secondary forms of vegetation. he prevalent growth form is shown by herbs with late-winter vegetative development that forms especially in open, sunny areas derived from the degradation of woodlands. Human inluence has been massive since Roman times (5th century b.c.), while over recent decades, ater the decrease of mining and agricultural activity, the vegetation has evolved towards more structured communities. 163 Tuscan Archipelago lora: from genesis to conservation Table 5. Percentage of growth forms and ecological elements in the Archipelago lora. MAIN THREATS AFFECTING PLANT DIVERSITY IN THE TUSCAN ARCHIPELAGO he Tuscan Archipelago economy has experienced a spectacular increase during the last thirty years, with deleterious impacts on landscape and indigenous lora and vegetation (Arrigoni et al., 2003; Foggi et al., 2006). All threats are directly or indirectly related to human activities, in particular following the abandonment of agriculture and the subsequent increase of tourism and trade: (1) housing developments are a common feature near the coast, related to tourism and recreational development, afecting the residual sand dune systems, the stability of sea clifs and the hygrophilous coenoses on loodplains; (2) the reduction of cultivated surfaces led to change in landscape patterns, paving the way for the evolution of Mediterranean series of vegetation in a progressive direction, towards the re-establishment of Quercus ilex woods, while reducing open habitats where high biodiversity coenoses are typical (Foggi et al., 2008); (3) reforestation is a highly disturbing factor; conifer reforestation, in particular, drastically alters the ecology of the sites; pine plantations (Pinus halepensis Mill. and Pinus pinaster Aiton) negatively afect the preservation of habitats of great value like e.g. Juniperus turbinata Guss. brushwood on Pianosa Island (Foggi et al., 2009a) and Quercus ilex-Ostrya carpinifolia woods on Elba 164 Islands and plants: preservation and understanding of lora on Mediterranean islands (Foggi et al., 2006); (4) an excessive number of wild introduced herbivores, especially ungulates like goats, moulon and boar (Capra hircus, Ovis musimom, Sus scrofa). hese species, foreign to the Tuscan Archipelago’s fauna, threaten the renewal of woodland species and decimate a large part of the herbaceous plants they ind palatable (Giannini and Montauti, 2010); (5) the massive increase of the seagull population (Larus michahellis) (Baccetti et al., 2008) has especially afected the biota of small islets, where a direct anthropic efect is lacking. he impact of these colonies on the plant communities of small islets is shown by the extinction of 89 local species (about 1/3 of the whole islet lora) in the last 100 years (Foggi et al., 2009), paralleled by a functional shit (Grime, 2001) in plant communities gradually from stress-tolerant to ruderal strategies (Foggi et al., 2001). With regard to 16 endemic species of the Tuscan Archipelago, the IUCN procedures labeled 13 of them as being under risk (Guidi, 2010, Foggi et al., submitted) (Table 6). Romulea insularis and Silene capraria are under threat due to a variation in land management: these species live in Isoëto-Nanojunceta coenoses or in therophitic grasslands. hey are threatened by the abandonment of the agro-pastoral management of the area that limited the development of forbs and woody species. A new land management system is needed for them (Foggi et al., 2008). All other endemic species are sufrutices, living in casmophytic or lithophytic habitats. In many cases they are threatened by invasive alien species, excessively trampled, or by weed management at roadside. Furthermore, although not threatened by change in land use, the current genetic variation pattern of Linaria capraria populations in Capraia Island mismatches their geographic distribution and could be explained on the basis of former connections provided by populations established on the stone walls of agricultural terracing. he abandonment of agriculture and the subsequent loss of stone walls aggravated the connections, causing the current pattern of isolated populations (Coppi et al., 2013). 165 Tuscan Archipelago lora: from genesis to conservation Exclusive endemic species of the Tuscan Archipelago Biscutella pichiana subsp. ilvensis Centaurea aetaliae Centaurea gymnocarpa Centaurea ilvensis Crocus ilvensis Festuca gamisansii subsp. aethaliae Limonium doriae Limonium gorgonae Limonium ilvae Limonium planesiae Limonium sommierianum Linaria capraria Mentha requienii subsp. bistaminata Romulea insularis Silene capraria Viola corsica subsp. ilvensis Principal treaths 1.1 1.3 2.3 1.3 2.3 4.1 5.2.1 8.1.2 5.2.1 8.1.2 2.3 4.1 5.2.1 7.3 8.2.1 1.1 2.3 4.1 5.2.1 7.3 8.1.2 8.2.1 2.3 7.3 8.2.1 8.1.2 8.2.1 8.1.2 1.1 1.3 8.1.2 8.2.1 8.1.2 1.1 1.3 8.1.2 1.1 1.3 2.3 4.1 5.2.1 8.1.2 10.3 8.1.2 7.3 8.2.1 7.3 8.2.1 1.3 2.3 5.2.1 7.3 8.2.1 Category EN EN EN VU EN VU CR EN NT EN NT NT EN CR CR EN Table 6. Endemic species exclusive to the Tuscan Archipelago and threat level. CONSERVATION ACTIVITIES In view of the high naturalistic value of the Tuscan Archipelago, several actions have been undertaken to warrant the conservation of its loristic and ecologic diversity (Tab. 7). he most important steps made in this sense are: (1) the constitution of the National Park (1996), (2) the launching of research projects providing baseline data to plan the protection of species and habitats, and (3) the implementation of the Habitats Directive and the establishment of Natura 2000 Sites, which enabled conservation actions to be funded by EUsupported LIFE projects. Globally, about 80% of the territory is included in protected areas. Wild plant species and natural and semi-natural habitats are protected by the Habitat Directive and by Regional Law (56/2000), including in its annexes 87 species and 25 habitats present in the Tuscan Archipelago; furthermore this law appoints the Botanical Gardens as the Center for the ex situ conservation of the native lora (CESFL). 166 Islands and plants: preservation and understanding of lora on Mediterranean islands Table 7. Most important conservation activities in the Tuscan Archipelago. he National Park of the Tuscan Archipelago received EU funds for LIFE Projects aiming at the removal/control of major threat factors. Important goals were achieved and further actions are scheduled: (1) to increase in extension and in biodiversity richness the ephemeral wetland vegetation and xerophile therophytic communities on Capraia Island, following a shrub clearing treatment (Foggi et al., 2008, Carta et al., 2013); (2) experimental implant of Quercus ilex on Capraia (Foggi et al., 2001) and Montecristo, where soil erosion and predation (by goats and black rats, particularly on Montecristo) prevent the species from constituting not only woods but also well structured maquis; (3) eradication of the invasive alien plants from Capraia, Pianosa and Montecristo islands; (3) elimination of rats from Giannutri and Montecristo islands (Sposimo et al., 2007); (4) felling of cultivated Aleppo pine (Pinus halepensis) on Pianosa island with a consequent expansion of Juniperus turbinata brushwood (Giunti & Sposimo, 2007); (5) to plan and start the recovery of the Stagnone pond on Capraia Island, which is undergoing a rapid process of silting due to the spread of tall helophytes introduced to the island in 1991 (Lastrucci et al., 2009). Furthermore, on a regular basis, the National Park enforces the containment of ungulate populations on Elba, Capraia and Giglio islands (Giannini & Montauti, 2010). 167 Tuscan Archipelago lora: from genesis to conservation Compared to in situ actions, ex situ conservation initiatives started more recently (Tab. 7). hey were developed as a complement to in situ programmes, as recommended by the CBD (art. 9). Since 2008, endemic or threatened taxa have been kept ex situ in the seed bank of the Botanic Garden of Pisa (Bedini & Carta, 2011), as a contribution towards the EU-funded ENSCONET project (ENSCONET, 2009) and the national project “Conservazione ex situ e caratterizzazione tassonomica, ecoisiologica e genetica di specie minacciate della lora spontanea italiana” (PRIN, 2007). Seed collections stored in the seed bank are being used to study the germination ecology of threatened taxa, both to support their in situ management and to produce healthy living specimens in the Botanic Garden for further ecological, demographic, and genetic research. he comparison of genetic diversity between in situ populations and ex situ individuals is a current research goal (Minuto et al., 2010), in the light of the future reinforcement of depauperated populations and reintroduction into natural habitats of local ones that had become extinct (Carta et al., 2012). In this respect, utmost care is given to the traceability of genetic materials from their access into the seed bank through every step of the treatment process, as a measure to avoid genetic pollution (Godefroid et al., 2011). Besides their use for research and as a possible source for reinforcement/ reintroduction into natural habitats, ex situ living collections are valuable tools for raising public awareness of the conservation of biodiversity. An ex situ collection of Ranunculus baudotii Godron from Capraia was included in a video showing the commitment of the Botanic Garden of Pisa to conservation (http://www.youtube.com/watch?gl=IT&v=s92GOGC9FEE), while some endemic species (Centaurea gymnocarpa, C. aethaliae, C. ilvensis) are featured in a series of didactic cards downloadable from the web site of CCB (Biodiversity Conservation Centre of Cagliari) (http://lnx.ondeweb.net/ccb2/ index.php?catID=16&artID=911). Local associations have established a small “dune garden” at Lacona, Elba Island, to raise public awareness of the conservation of the psammophile communities. Interestingly, they have adopted a “lagship” species (Pancratium maritimum L.) to help get their message across (Zanichelli et al., 2010). FURTHER PERSPECTIVES TOWARDS THE CONSERVATION OF THE TUSCAN ARCHIPELAGO FLORA he lora and vegetation of the Tuscan Archipelago, as on all Mediterranean islands, are obviously undergoing signiicant transformations. In areas with scarce human impact like the islets, whether the change is caused mainly by 168 Islands and plants: preservation and understanding of lora on Mediterranean islands external forces or by the efect of the natural dynamics on small islands is still debatable (Foggi et al., 2009). At present, a monitoring program that would enable recording these variations and addressing appropriate conservation measures is still lacking. However, although from a general point of view the current patterns of loristic diversity have been identiied; speciic research is needed on two levels. First, on a species level, it is necessary to encourage ecological and genetic studies supporting in situ conservation measures and to suggest sampling strategies of populations to maximise the genetic diversity of taxa in the seed bank collections. In views of an efective, integrated in situ and ex situ strategy, all stakeholders (scientiic research centres, seed banks, botanic gardens, local administrative bodies, protected areas, and local associations) should join together in a network with the aim to exchange available information, coordinate the request for funds, and set common priorities for the conservation, management and monitoring of taxa. In this respect, recovery plans should be drated based on demographic structure and genetic diversity, such as proposed for Linaria capraria (Coppi et al., 2013), which was integrated thanks to ex situ conservation measures. Many things are still to be done to assess the conservation status of all lora, and in particular of those non endemic taxa exhibiting a particular phytogeographical signiicance or an ecosystem value to maintain the functionality of highly fragmented habitats (e.g. sand dunes). he impact of invasive alien species, documented for a handful of species (Genovesi & Shine, 2004), needs to be assessed at a closer scale. In fact they afect native communities not only at species level, by competing with native species for resources, but also at landscape level, by disrupting vegetation series over vast tracts of territory. In this case, conservation projects based on the eradication of long-established plants need to be carefully explained to the general public. he role of local associations is pivotal to develop consent about such interventions, and should be planned from the start. In any case, an adequate awareness raising policy is essential for successful conservation initiatives. Secondly, on a landscape level, it is necessary to deine a management of vegetation series at landscape unit scale, necessary to maintain the simultaneous presence of diferent vegetation dynamic stages. Management of vegetation dynamics is needed on all the islands as reported by Foggi et al. (2008; 2011) for Capraia and Giannutri, respectively. However, Elba Island stands out due to the presence of diferent land units expressed by a number of forest vegetation series and due to the more pronounced change in land use with comparison to 169 Tuscan Archipelago lora: from genesis to conservation the other islands. For these reasons, land use planning should focus especially on sustainable development, as proposed by the Tuscan Archipelago National Park and by speciic projects (Morelli, 2001; Carta, 2011). Many studies have pointed out the interesting plant diversity patterns in the Tuscan Archipelago and several actions have been put into place to preserve them; other goals may be set considering that “islands are not simply miniature continents” (Nunn, 2004). Challenges remain at the policy level; for example, the need to factor in the value of natural resources, the decision making process, and the opportunity to better deine the role of public sector science (Smith et al., 2010). ACKNOWLEDGEMENTS his research was carried out with funds from the “Tuscan Archipelago” National Park, University of Florence (ex 60%), EU-funded ENSCONET project and from Ministry for the University and Research, PRIN 2007, prot. 2007JNJ7MX_004. REFERENCES Arrigoni, P.V. 1975. Rapporti loristici tra l’Arcipelago Toscano e le terre vicine. Lavori della Società Italiana di Biogeograia. n.s., 5: 55-65. Baccetti, N., Leone, M.L., Sposimo, P. 2008. 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ARPAT news 004-10. 175 Tuscan Archipelago lora: from genesis to conservation 176 Islands and plants: preservation and understanding of lora on Mediterranean islands CONSIDERATIONS ON THE ENDEMIC FLORA OF SICILY Cristian Brullo, Salvatore Brullo and Gianpietro Giusso del Galdo Department of Biological, Geological and Environmental Sciences (Sect. Plant Biology), University of Catania, via A. Longo 19, I-95125 Catania (Italy). Abstract A survey on the endemic lora exclusive of Sicily has been carried out. Based on the taxonomical, ecological, karyological, chorological, phytosociological, phenological and conservation data concerning each endemic taxon, their role within the Sicilian territory has been examined. In particular, we provide detailed information on the numerical consistency of the Sicilian endemics in respect to the type of endemism, family, phenology, life form, chorology, environment, ecology, phytosociology, and vulnerability. A total of 322 taxa have been recognized as narrow Sicilian endemics, roughly corresponding to 10% of the whole Sicilian lora. he noteworthy relevance of the Sicilian endemic lora is due to the occurrence of several paleo-endemics, usually with a punctiform distribution and chiely localized on rocky habitats. he thermo-xerophilous and orophilous species are also well represented, mostly linked to highly preserved environments. Furthermore, the occurrence of several halophilous and nitrophilous endemics is quite relevant, testimony to the historic geographical isolation of Sicily from the neighbouring mainland territories. Keywords: Sicily, endemism, lora, phytogeography. INTRODUCTION he endemic lora of a given territory provides useful information on its paleo-geographical history and climatic changes that afect the area at hand. his is the main reason why any information concerning the taxonomical position and current geographical distribution of the endemic taxa is extremely important, especially when they are compared to the most related species. In particular, detailed information on their life cycle, morphology, karyology, Corresponding author: Salvatore Brullo (salvo.brullo@gmail.com) 177 Considerations on the endemic lora of Sicily ecology, chorology, phytosociology, nomenclature, systematic position and, if possible, even on its genome are essential not only to have a complete picture of the endemic component characterizing the lora of the surveyed area, but also to deine the role played by each endemism. Aiming at increasing our knowledge of the most relevant species growing in Sicily, an in-depth analysis focused on the endemic species living on the largest Mediterranean island has been carried out. In particular, the survey is focused on those taxa that are exclusive to this territory, neighbouring islets included. herefore, those taxa whose distribution range also include the Maltese Archipelago are excluded, even if this area phytogeographically belongs to the Sicilian territory. In order to have an updated list, as comprehensive as possible, several Sicilian loras were examined, together with a selection of the most popular and relevant Italian, European or Mediterranean loras. In particular, several loras and loristic papers published during the 18th and 19th centuries (e.g. Presl, 1826; Gussone, 1843-1845; Parlatore, 1839, Cesati et al., 1868-1889; Strobl, 1878-1887, 1880-1885; Tornabene, 1889-1892), as well as those published in the 20th and 21st centuries, such as Lojacono-Pojero (1888-1909), Fiori (19231929), Tutin et al. (1964-1980, 1993), Pignatti (1982), Greuter et al. (19841989), Giardina et al. (2007), Greuter (2008), Raimondo & Spadaro (2009) have been examined. In addition to this literature, many local loristic checklists, taxonomical revisions of genera, critical groups or species, as well as several karyological, phytogeographical, phytosociological and conservation papers have also been considered. Based on current knowledge, the Sicilian lora consists of about 3,250 taxa at infra-generic level, also including naturalized and adventitious plants. With regard to the narrow Sicilian endemics, namely those exclusively growing in Sicily and neighbouring islets, 322 taxa have been counted, roughly corresponding to 10% of the total. For each surveyed endemic species, detailed information concerning its nomenclature, phenology, life cycle, karyology, ecology, chorology, phytosociological role, type of endemism, and conservation status is provided. List of the Sicilian endemics Abies nebrodensis (Lojac.) Mattei Acer obtusatum Willd. subsp. aetnense (Tineo ex Strobl.) C. Brullo & Brullo Acinos alpinus (L.) Moench subsp. nebrodensis (Kerner & Strobl) C. Brullo & Brullo 178 Islands and plants: preservation and understanding of lora on Mediterranean islands Adenocarpus bivonii (C. Presl) C. Presl Adenocarpus commutatus Guss. Adenostyles hybrida Guss. Allium agrigentinum Brullo & Pavone Allium castellanense (Garbari, Miceli & Raimondo) Brullo et al. Allium cupanii Rain. Allium franciniae Brullo & Pavone Allium hemisphaericum (Sommier) Brullo Allium lehmannii Lojac. Allium lopadusanum Bartolo, Brullo & Pavone Allium nebrodense Guss. Allium obtusilorum DC. Allium panormitanum Brullo, Pavone & Salmeri Allium pelagicum Brullo, Pavone & Salmeri Allium vernale Tineo Alyssum nebrodense Tineo subsp. nebrodense Anthemis aetnensis Schouw Anthemis cossyrensis (Guss.) Guss. Anthemis cupaniana Tod. ex Nyman Anthemis intermedia Guss. Anthemis ismelia Lojac. Anthemis lopadusana Lojac. Anthemis messanensis Brullo Anthemis muricata (DC.) Guss. Anthemis pseudoabrotanifolia Brullo C., Brullo, Giusso & Pavone Anthyllis hermanniae L. subsp. sicula Brullo & Giusso Anthyllis vulneraria L. subsp. busambarensis (Lojac.) Pignatti Arabis madonia C. Presl Aristolochia sicula Tineo Armeria gussonei Boiss. Armeria nebrodensis (Guss.) Boiss. Arrhenatherum nebrodense Brullo, Minissale & Spampinato Asperula gussonei Boiss. Asperula peloritana Brullo C., Brullo, Giusso & Scuderi Asperula rupestris Tineo Astragalus huetii Bunge Astragalus nebrodensis (Guss.) Strobl 179 Considerations on the endemic lora of Sicily Astragalus raphaelis Ferro Astragalus siculus Biv. Aubrieta deltoidea (L.) DC. subsp. sicula (Strobl) Phitos Bellardiochloa aetnensis (C. Presl) Brullo & Siracusa Bellardiochloa nebrodensis (Asch. & Graebn.) C. Brullo, Brullo & Giusso comb. et stat. nov. [Bas.: Poa violacea Bell. var. nebrodensis Asch. & Graebn., Syn. Mitteleur. Fl. 2:435, 1900] Bellevalia dubia (Guss.) Reichemb. Bellevalia pelagica C. Brullo, Brullo & Pasta Betula aetnensis Rain. Bothriochloa panormitana (Parl.) Pilg. Brassica bivoniana Mazzola & Raimondo Brassica drepanensis (Caruel) Damanti Brassica macrocarpa Guss. Brassica rupestris Rain subsp. hispida Raimondo & Mazzola Brassica tinei Lojac. Brassica villosa Biv. subsp. brevisiliqua (Raimondo & Mazzola) Raimondo & Geraci Brassica villosa Biv. subsp. villosa Buglossoides splitgerberi (Guss.) Brullo Bupleurum dianthifolium Guss. Bupleurum elatum Guss. Calendula maritima Guss. Calendula sufruticosa Vahl. subsp. gussonei Lanza Campanula marcenoi Brullo Carduus nutans L. subsp. siculus (Franco) Greuter Celtis aetnensis (Tornab.) Strobl Celtis asperrima Lojac. Centaurea aeolica Guss. ex. Lojac. Centaurea busambarensis Guss. Centaurea erycina Raimondo & Bancheva Centaurea giardinae Raimondo & Spadaro Centaurea gussonei Raimondo & Spadaro Centaurea macroacantha Guss. Centaurea parlatoris Heldr. Centaurea saccensis Raimondo, Bancheva & Ilardi Centaurea seguenzae (Lacaita) Brullo, Marcenò & Siracusa 180 Islands and plants: preservation and understanding of lora on Mediterranean islands Centaurea sicana Raimondo & Spadaro Centaurea todaroi Lacaita Centaurea panormitana Lojac. Centaurea tyrrhena C. Brullo, Brullo & Giusso Chiliadenus lopadusanus Brullo Colymbada tauromenitana (Guss.) Holub Crepis bivonana (Reichenb.) Soldano & F. Conti Crepis hyemalis (Biv.) Cesati, Pass. & Gibelli Crepis gussonei Greuter Crocus pygmaeus Lojac. Crocus siculus Tineo ex Guss. Cymbalaria pubescens (J & C. Presl) Cuf. Cynoglossum nebrodense Guss. Cytisus aeolicus Guss. Daucus lopadusanus Tineo Daucus nebrodensis Strobl Daucus rupestris Guss. Delphinium emarginatum C. Presl Desmazeria pignattii Brullo & Pavone Dianthus busambrae Soldano & Conti Dianthus gasparrinii Guss. Dianthus graminifolius C. Presl Dianthus rupicola Biv. subsp. aeolicus (Lojac.) Brullo & Minissale Dianthus rupicola Biv. subsp. lopadusanus Brullo & Minissale Dianthus siculus C. Presl subsp. siculus Diplotaxis crassifolia (Rain.) DC. Diplotaxis scaposa DC. Draba olympicoides Strobl Echinaria todaroana (Ces.) Ciferri & Giacom. Echium italicum L. subsp. siculum (Lacaita) Greuter & Burdet Elatine gussonei (Sommier) Brullo, Lanfranco, Pavone & Ronsisvalle Eleocharis nebrodensis Parl. Erica sicula Guss. subsp. sicula Erodium neuradifolium Delile var. linosae (Sommier) Brullo Eryngium bocconei Lam. Eryngium crinitum C. Presl Erysimum bonannianum C. Presl Erysimum brulloi Ferro 181 Considerations on the endemic lora of Sicily Erysimum etnense Jordan Erysimum metlesicsii Polatschek Euphorbia bivonae Steudel Euphorbia gasparrinii Boiss. Euphorbia papillaris (Boiss.) Rafaelli et Ricceri Euphorbia pycnophylla (K. U. Kramer & Westra) C. Brullo & Brullo Evacidium discolor (DC.) Maire Festuca humifusa Brullo & Guarino Festuca morisiana Parl. subsp. sicula Cristaudo, Foggi, Galesi & Maugeri Festuca pignattiorum Markgr.-Dannenb. Filago cossyrensis Lojac. Fraxinus excelsior L. subsp. siciliensis Ilardi & Raimondo Gagea busambarensis (Tineo ex Guss.) Parl. Gagea chrysantha Schult. & Schult f. Gagea lacaitae A. Terracc. Gagea nebrodensis (Tod. ex Guss.) Nyman Galium litorale Guss. Galium pallidum C. Presl Genista aristata C. Presl Genista cupanii Guss. Genista demarcoi Brullo, Scelsi & Siracusa Genista gasparrinii (Guss.) C. Presl Genista madoniensis Raimondo Genista tyrrhena Vals. subsp. tyrrhena Helianthemum nebrodense Heldr. Helianthemum sicanorum Brullo, Giusso & Sciandrello Helichrysum archimedeum Brullo C, Brullo & Giusso Helichrysum errerae Tineo Helichrysum hyblaeum Brullo Helichrysum italicum (Roth) G. Don il. subsp. siculum (Jordan & Fourr.) Galbany et al. Helichrysum nebrodense Heldr. Helichrysum panormitanum Tineo ex Guss. subsp. cophanense Brullo C, Brullo & Giusso Helichrysum panormitanum Tineo ex Guss. subsp. messeriae (Pignatti) Brullo et al. Helichrysum panormitanum Tineo ex Guss. subsp. panormitanum 182 Islands and plants: preservation and understanding of lora on Mediterranean islands Helichrysum panormitanum Tineo ex Guss. subsp. stramineum (Guss.) Brullo et al. Helichrysum pendulum (C. Presl) C. Presl Helichrysum preslianum C. Brullo & Brullo Herniaria fontanesii Gay subsp. empedocleana (Lojac.) Brullo Hesperis cupaniana Guss. Hieracium cophanense Lojac. Hieracium lucidum Guss. Hieracium madoniense Raimondo & Di Gristina Hieracium pallidum Biv. Hieracium pignattianum Raimondo & Di Gristina Hieracium symphytifolium Froelich Hornungia revelierei (Jord.) Soldano et al. subsp. sommieri (Pamp.) Brullo et al. Iris sicula Tod. Jacobaea ambigua (Biv.) Pelser & Veldkamp Jacobaea candida (C. Presl) B. Nord. & Greuter Jurinea bocconei (Guss.) Guss. Koeleria splendens C. Presl subsp. splendens Laserpitium siculum Sprengel Lavatera agrigentina Tineo Leontodon siculus (Guss.) Nyman Leopoldia gussonei Parl. Limonium aegusae Brullo Limonium albidum (Guss.) Pignatti Limonium algusae (Brullo) Greuter Limonium bocconei (Lojac.) Litard. Limonium calcarae (Todaro ex Janka) Pignatti Limonium catanense (Tineo ex Lojac.) Brullo Limonium catanzaroi Brullo Limonium cosyrense (Guss.) O. Kuntze Limonium densilorum (Guss.) O. Kuntze Limonium lagellare (Lojac.) Brullo Limonium furnarii Brullo Limonium halophilum Pignatti Limonium hyblaeum Brullo Limonium intermedium (Guss.) Brullo Limonium ionicum Brullo Limonium lilybaeum Brullo 183 Considerations on the endemic lora of Sicily Limonium lojaconoi Brullo Limonium lopadusanum Brullo Limonium mazarae Pignatti Limonium melancholicum Brullo, Marcenò & Romano Limonium minutilorum (Guss.) O. Kuntze Limonium optimae Raimondo Limonium opulentum (Lojac.) Brullo Limonium pachynense Brullo Limonium panormitanum (Todaro) Pignatti Limonium parvifolium (Tineo) Pignatti Limonium pavonianum Brullo Limonium ponzoi (Fiori & Bèguinot) Brullo Limonium secundirameum (Lojac.) Brullo Limonium selinuntinum Brullo Limonium sibthorpianum (Guss.) O. Kuntze Limonium syracusanum Brullo Limonium tauromenitanum Brullo Limonium tenuiculum (Tineo ex Guss.) Pignatti Limonium todaroanum Raimondo & Pignatti Linaria multicaulis (L.) Miller subsp. humilis (Guss.) De Leonardis, Giardina & Zizza Linaria multicaulis (L.) Miller subsp. aetnensis (Giardina & Zizza) Brullo et al. Linaria multicaulis (L.) Miller subsp. multicaulis Linaria multicaulis (L.) Miller subsp. panormitana (Giardina & Zizza) Brullo et al. Linaria pseudolaxilora Lojac. Linum punctatum C. Presl Logia lojaconoi (Brullo) C. Brullo & Brullo Lotus versicolor Tineo Malus crescimannoi Raimondo Matthiola incana (L.) R. Br. subsp. pulchella (P. Conti) Greuter & Burdet Megathyrsus bivonianus (Brullo, Minissale, Scelsi & Spamp.) Verloove Micromeria fruticulosa (Bertol.) Šilić Muscari lafarinae (Tineo ex Lojac.) C. Brullo & Brullo Myosotis tinei C. Brullo & Brullo Odontites bocconei (Guss.) Walp. subsp. angustifolia (Lojac.) Giardina & Raimondo 184 Islands and plants: preservation and understanding of lora on Mediterranean islands Odontites bocconei (Guss.) Walp. subsp. bocconei Odontites rigidifolius (Biv.) Bentham Odontites vulgaris Moench subsp. siculus (Guss.) Bolliger Oncostema cerulea (Rain.) Speta Oncostema dimartinoi (Brullo & Pavone) Conti & Soldano Oncostema hughii (Tineo ex Guss.) Speta Oncostema sicula (Tineo ex Guss.) Speta Onosma canescens C. Presl Ophrys archimedea Delforge & M. Walravens Ophrys biancae (Tod.) Macchiati Ophrys calliantha Bartolo & Pulvirenti Ophrys lammeola Delforge Ophrys laurensis Melki & Geniez Ophrys lunulata Parl. Ophrys mirabilis Geniez & Melki Ophrys obaesa Lojac. Ophrys pallida Rain. Ophrys panormitana (Tod.) Soò Orobanche chironii Lojac. Pancratium linosae Soldano & F. Conti Petagnaea gussonei (Spreng.) Rauschert Peucedanum nebrodense (Guss.) Nyman Phagnalon metlesicsii Pignatti Pimpinella tragium Vill. subsp. glauca (C. Presl) C. Brullo & Brullo Plantago afra L. subsp. zwierleinii (Nicotra) Brullo Plantago peloritana Lojac. Poa bivonae Parl. ex Guss. Prospero hierae Brullo C., Brullo, Giusso, Pavone & Salmeri Prunus cupanianus Guss. ex Nyman Pseudoscabiosa limonifolia (Vahl) Devesa Puccinellia gussonei Parl. Pyrus castribonensis Raimondo, Schicchi & Mazzola Pyrus sicanorum Raimondo, Schicchi & Marino Pyrus vallis-demonis Raimondo & Schicchi Quercus fontanesii Guss. Quercus gussonei (Borzì) Brullo Quercus leptobalanos Guss. 185 Considerations on the endemic lora of Sicily Ranunculus rupestris Guss. Retama raetam (Forrskal) Webb subsp. gussonei (Webb) Greuter Rhamnus lojaconoi Raimondo Romulea linaresii Parl. Romulea melitensis Bég. Rosa strobliana Burnat & Gremli Rubus aetneus Tornab. Rumex aetnensis C. Presl Salix gussonei Brullo & Spampinato Salsola agrigentina Guss. Scabiosa parvilora Desf. Scleranthus annuus L. subsp. aetnensis (Strobl) Pignatti Scleranthus vulcanicus Strobl Scutellaria rubicunda Hornem. Senecio aegadensis C. Brullo & Brullo Senecio aethnensis Jan ex DC. Senecio glaber Ucria Senecio glaucus L. subsp. hyblaeus Brullo Senecio leucanthemifolius Poir. subsp. cossyrensis (Lojac.) C. Brullo & Brullo Senecio leucanthemifolius Poir. subsp. pectinatus (Guss.) C. Brullo & Brullo Senecio pygmaeus DC. Senecio siculus All. Senecio squalidus L. Serapias cossyrensis B. & H. Baumann Serapias orientalis (Greuter) H. Baumann & Kunkele subsp. siciliensis Bartolo & Pulvirenti Seseli bocconi Guss. Sesleria nitida Ten. subsp. sicula Brullo & Giusso Sideritis sicula Ucria Silene hicesiae Brullo & Signorello Silene saxifraga L. subsp. rupicola (Huet ex Nyman) C. Brullo & Brullo Silene vulgaris (Moench) Garcke subsp. aetnensis (Strobl) Pignatti Spergularia madoniaca Lojac. Stachys germanica L. subsp. dasyanthes (Rain.) Arcangeli Sternbergia aetnensis (Rain.) Guss. Sternbergia exscapa Tineo ex Guss. Stipa gussonei Moraldo 186 Islands and plants: preservation and understanding of lora on Mediterranean islands Stipa sicula Moraldo, Caputo, La Valva & Ricciardi Suaeda kocheri Guss. ex C. Brullo, Brullo & Giusso Suaeda pelagica Bartolo, Brullo & Pavone Symphytum gussonei Schultz Tanacetum siculum (Guss.) Strobl Taraxacum garbarianum Peruzzi, Aquaro, Caparelli & Raimondo hapsia garganica L. subsp. messanensis (Guss.) Brullo et al. hapsia pelagica Brullo et al. hymus nitidus Guss. Tillaea basaltica (Brullo & Siracusa) Brullo, Giusso & Siracusa Tolpis gussonei (Fiori) Brullo et al. Tolpis quadriaristata Biv. Tolpis sexaristata Biv. Torilis nemoralis (Brullo) Brullo & Giusso Trachelium lanceolatum Guss. Trifolium bivonae Guss. Trifolium congestum Guss. Trifolium macropodum (C. Presl) Guss. Trifolium mutabile Portenschl. subsp. gussoneanum (Gibelli & Belli) Brullo et al. Trifolium nigrescens Viv. var. dolychodon Sommier Trifolium savianum Guss. Tripolium sorrentinoi (Tod.) Raimondo & Greuter Tuberaria villosissima (Pomel) Grosser subsp. sicula (Grosser) Bartolo, Pulvirenti & Salmeri Urtica rupestris Guss. Valantia calva Brullo Valantia deltoidea Brullo Verbascum siculum Tod. ex Lojac. Viola aethnensis (DC.) Strobl Viola nebrodensis C. Presl Viola tineorum Erben & Raimondo Viola ucriana Erben & Raimondo Zelkova sicula Di Pasquale, Gari & Quézel 187 Considerations on the endemic lora of Sicily RESULTS Based on our investigations on the Sicilian endemic lora, we highlight the relationships existing between plants and their environment, as well as the role that abiotic factors, like soil, climate, orography, and paleo-geographical vicissitudes play and played in shaping their current distribution area. Depending on the taxonomical, morphological, karyological, ecological, chorological, phytosociological, and phenological features of the endemic species, the outcome of our analyses is here presented. 1. Type of endemism he Sicilian lora, with about 3,250 taxa at an infrageneric level, is the richest among the ive larger Mediterranean islands. he narrow Sicilian endemic taxa are 322, and they can be referred to diferent categories of endemism, chiely depending on their taxonomic and phylogenetic relationships, as well as on their karyology, chorology, ecology, and ontogenetic cycle. In particular, in order to provide an updated arrangement of the diferent types of endemism occurring in Sicily, it is here proposed a threefold classiication based on the following criteria (Favager & Contandriopoulos, 1961; Contandriopoulos, 1962;): origin (paleo-endemics and neo-endemics), taxonomical isolation (macro-endemics and micro-endemics), geographical isolation, and chromosome complement (paleo-polyploids, neo-polyploids, apomictics, patro-endemics, apo-endemics, and schizo-endemics). According to this classiication, it was possible to recognize a noteworthy occurrence of schizo-endemic taxa (27.6%), whose origin is strictly linked to the geographical isolation of the Sicilian populations from those occurring in neighbouring territories. Such endemism is usually represented by taxa with the same chromosome complement. he most relevant schizo-endemics occurring in Sicily are: Adenostyles hybrida, Anthemis messanensis, Armeria nebrodensis, Bellevalia pelagica, Campanula marcenoi, Helianthemum sicanorum, Hesperis cupaniana, Lavatera agrigentina, Leopoldia gussonei, Salsola agrigentina and Trifolium savianum. Similarly, the micro-endemics are represented by a fairly substantial number of taxa (22%), to which are referred microspecies and taxa treated at a subspeciic level, both commonly arisen from more widely spread taxa. For instance, Anthemis cossyrensis, A. intermedia, and A. lopadusana, all belonging to the cycle of A. secudiramea Biv., Brassica bivoniana, B. drepanensis, B. rupestris subsp. hispida, B. tinei, B. villosa subsp. brevisiliqua, B. villosa subsp. villosa, belonging to the B. pubescens (L.) Ardoino group, as well as Centaurea gussonei, C. parlatoris, C. sicana, and C. giardinae, all closely related to C. dissecta 188 Islands and plants: preservation and understanding of lora on Mediterranean islands Ten. On the contrary, only one macro-endemic species has been recognized in Sicily. It is Petagnaea gussonei, monospeciic genus of the Apiaceae, which is taxonomically extremely isolated. Paleoendemics are numerically rather substantial (19.6%), whose ancient origin makes these species minimally, if at all, related to other congeneric taxa (Abies nebrodensis, Asperula gussonei, Astragalus nebrodensis, Bupleurum elatum, Genista cupanii, Hieracium lucidum, Limonium calcarae, Megathyrsus bivonianus, Pseudoscabiosa limonifolia, Trachelium lanceolatum, Urtica rupestris, etc.). Whereas neoendemic species, even if taxonomically well diferentiated, are numerically less consistent (11.2%), possibly because they are linked to substrates geologically more recent (e.g. Quaternary), such as Betula aetnensis, Centaurea macroacantha, Erysimum brulloi, Helichrysum errerae, Senecio aethnensis, Serapias cossyrensis, Tanacetum siculum, Tillaea basaltica, Valantia calva, etc. Rather low is the number of polyploid taxa. Within the polyploids, two typologies are here recognized: paleo-polyploids (5.3%), characterized by weak phylogenetic relationships with other congeneric species (Allium franciniae, Bupleurum dianthifolium, Cytisus aeolicus, Genista aristata, Zelkova sicula and Viola tineorum), and neo-polyploids (5.0%), showing instead close relations with diploid species widely occurring in other territories (Anthemis aetnensis, Astragalus siculus, Hieracium pallidum, Limonium pachynense, Limonium ponzoi, Limonium tauromenitanum, Symphytum gussonei, Viola aethnensis). Another relevant group of endemics is represented by the apomictic species (6.8%), whose chromosome complement is always odd (x=3n, 5n). Such species are characterized by asexual reproduction, and, therefore, each population appears rather homogeneous and morphologically well diferentiated from the allied species. Many endemic taxa fall into this category, such as several species of the genus Limonium (L. cosyrense, L. lagellare, L.intermedium, L. minutilorum, L. optimae and L. todaroanum), and Hieracium (H. madoniense, H. pignattianum). Finally, based on the current karyological knowledge, only a few apo-endemics (1.9%), like Allium vernale, Calendula maritima, Diplotaxis crassifolia, and Valantia deltoidea, and one patro-endemic (Crepis hyemalis) occur in Sicily. 2. Family As one might expect, families with the highest degree of endemism are those whose speciation processes were, and in many cases still are, particularly intense and active. hus, there is a positive correlation among plant diversity and diferentiation, evolutionary trends and degree of endemism. 189 Considerations on the endemic lora of Sicily In Sicily, Asteraceae is the most endemic-rich family, with 72 endemics (22.4%) mainly belonging to the genera Anthemis, Centaurea, Helichrysum, and Senecio. Also quite rich in endemics is the family of the Plumbaginaceae with 37 taxa (11.5%), and with almost all its endemic taxa belonging to the genus Limonium. Also well represented are the Fabaceae (23 endemics corresponding to 7.1% of the total lora), while Brassicaceae, Poaceae, Orchidaceae, Caryophyllaceae, Alliaceae, Apiaceae, and Scrophulariaceae range from 20 (6.2%) to 11 (3.4%) endemic taxa. Finally, the remaining families make up a number of endemics never exceeding 7 (2.2%). 3. Phenology In order to have a classiication of the endemic species based on their lowering time, the blooming highest peak (acme) was considered. In particular, the winter-blooming species blossom between January and March, sometimes extending their lowering time until April, while the optimal conditions for the spring-blooming plants begin in April and last until June, occasionally they may blossom as early as March. he lowering time of the summer-blooming plants lasts from June to September, while the autumnal blooming taxa are typically characterized by a late lowering time, which usually starts in September and lasts until December. Like most Mediterranean plants, Sicilian endemics are also characterized by a clear dominance of the spring-blooming plants, whose lower production reaches its highest peak right before the dry season. In fact, 183 endemic taxa (corresponding to 56.8%) are spring-blooming, followed by summer-blooming (94 taxa corresponding to 29.2%), which are chiely represented by orophytes and halophytes. Lower numbers are recorded both for the autumnal endemics (19 taxa, 5.9% of the total) and for the late-lowering ones, with only 16 taxa (5%). Lastly, the behaviour of 10 endemics is rather unusual from a phenological point of view, since they produce lowers almost continuously, sometimes for the whole year, thus they may not be included in any of the above-mentioned categories. 4. Life form One of the most common features of the Mediterranean plants is having reduced vegetative parts, thus reducing transpiration during the remarkable summer drought, which undoubtedly represents a severe constraint for plant development. Also for this reason, dwarf species are strongly favoured by such climatic conditions, thus becoming prevailing chamaephytes or plants which 190 Islands and plants: preservation and understanding of lora on Mediterranean islands form perennial buds close to the ground (hemicryptophytes) or even under the ground (geophytes). he endemic lora of Sicily is clearly dominated by chamaephytes (37.6%), mostly found in ecologically selective habitats, such as high-mountain stands, clifs or coastal environments. In particular, chasmophytic species are able to vegetate even in summer, thanks to their high capacity to retain atmospheric moisture or to use the residual water content, while halophytes exploit the marine spray. High-mountain endemic taxa (orophytes), thanks to their physiology and structural organization, are ecologically very well adapted, being able to get water directly from the atmospheric moisture during the night and the early morning. A fairly good number of hemicryptophytes (16.1%) and geophytes (15.8%) have been recorded within the Sicilian endemic lora. hey are mainly found in open environments characterized by herbaceous vegetation (e.g. dry grasslands or meadows) or by shrubby plant communities, such as garigues, maquis, and so on. Such habitats are usually characterized by relatively deep soils, which favours the survival of underground reserve organs. Annual endemic species are about 13% of the total, and are chiely localized within ephemeral plant communities or disturbed habitats, such as abandoned ields, ruderal sites, roadsides, cultivated lands, etc. Endemic trees and shrubs are 55, and they are represented both by nanophanerophytes (11.5%) and phanerophytes (5.6%). he noteworthy importance of such plants is mainly linked to their ancient origin, which is due to the geographical isolation of the Sicilian populations. In most cases these species represent the dominant element of peculiar and ecologically specialized woodlands or shrubby communities. Finally, only one endemic hydrophyte has been found in Sicily. It grous in temporary ponds, which are rather uncommon in Sicily. 5. Chorology he distribution of the Sicilian endemic species has been investigated in order to verify the occurrence of each taxon within the phytogeographical districts recognized by Brullo et al. (1995). Actually, they distinguish two biogeographical sectors: Eusicilian and Pelagian. he former includes Sicily, Ustica, Aeolian and Egadi Islands, while the latter groups Pantelleria, Lampedusa, Linosa, and Maltese Archipelago. Based on their loristic, geological and bioclimatic peculiarities, many diferent subsectors and districts have been recognized within the above-mentioned sectors (Fig.1). he highest number of endemics is found in the Eusicilian sector (22.4%), 191 Considerations on the endemic lora of Sicily followed by the Drepano-Panormitano (15.2%) and Madonita (11.5%) districts. he high degree of endemism characterizing the latter districts is likely due to the occurrence of many mountains whose ancient origin and geographical isolation favoured the establishment of several narrow endemics. Another district particularly rich in neo-endemics is the Etnean (6.5%), whose wide altitudinal range (the highest peak reaches about 3,400 m a.s.l.) favoured the establishment of many ecologically specialized species, especially in the oroand crio-oromediterranean bioclimatic belts. Also the Agrigentino district is rather rich in endemics (5.3%). his is probably due to the occurrence of many thermo-xeric habitats, whose environmental conditions are suitable for many North-African species which are usually linked to halomorphic substrates. he last two districts, in terms of endemic richness, are Camarino-Pachinense and Hyblaean, with 3.1% and 2.8% of endemics respectively. he Peloritano (3.4%) and Nebrodense (1.9%) districts, even if they chiely include mountain areas, are rather poor in endemics, probably because they are geologically homogeneous, mostly consisting of siliceous substrata. As for the circum-Sicilian islets, the highest degree on endemism has been recorded for Lampedusa (4.8%), whereas the Egadense and Aeolian districts are characterized by lower values, 3.1% and 1.6% respectively. Geologically speaking, the volcanic nature and recent origin of the latter archipelago seems to be the main reason for this low number of endemics, but very important from the phytogeographical and taxonomical point of view (Cytisus aeolicus, Silene hicaesiae, Genista thyrrena subsp. thyrrena, Centaurea eolica, Erysimum brulloi, etc.) 6. Ecology Endemic species, depending on their ecological requirements, seem to prefer some particular soil types or environments that are characterized by peculiar edaphic or microclimatic conditions. In Sicily, we can observe that carbonatic substrates (limestones, dolomites, and marls) are deinitely richer in endemic species. Actually, 50.3% of endemics are strictly calcicolous, thus founding their optimal conditions on carbonatic rocks, while about 25.5% are those growing on siliceous substrates, likely because low-pH soils are ecologically less limiting and probably even less suitable for hosting endemic species. he endemics not linked to any particular substrate are well represented too (24.2%). Considering the soil texture, it has been possible to recognize other types of endemism. In particular, the highest degree of endemism is represented by taxa 192 Islands and plants: preservation and understanding of lora on Mediterranean islands growing on mature soils, particularly rich in humus, which are here indicated as terricolous (63.0%); whereas psammophytes, linked to sandy soils, make up 5%, ceramophilous endemics, exclusive of clayey soils, make up 4.7%, glareicolous, growing on pebbly riverbeds or screes, make up 3.4%, and the comophilous, exclusively localized on rocky ledges, make up 1.6%. Finally, a rather interesting group of endemic taxa is represented by the chasmophytes. Such species are quite abundant (22.4%), and represent an ecologically extremely specialized component of the Sicilian endemic lora. hese relic species are circumscribed to the rocky crevices, and their current narrow distribution clearly denotes their regressive status of surviving remnants of Tertiary lora. Quite relevant is the occurrence of a fairly good number of endemic halophytes (14.0%), linked to rocky coastal habitats or salt marshes. he nitrophilous endemic species are less represented but still very relevant (6.8%), and are linked to synanthropic stands, characterized by soils particularly rich in nitrates. Another limiting factor is water availability, in turn related to the soil granulometry, which allows for recognition of xerophilous endemics (56.5%), mesophilous (39.4%), quite common on the mountain belt, hygrophilous (3.7%), and hydrophilous (0.3%); the latter typically growing on periodically submerged pools. Depending on the bioclimatic features of the explored sites, four main types of endemics have been distinguished: thermophilous (57.8%), located within the infra- and thermo-Mediterranean belts; mesophilous (17.7%), widely spread in the submontane or mountain stands, chiely falling within the meso-Mediterranean bioclimatic belt, or partially in the supraMediterranean one; orophilous (22%), exclusively found in high-mountain stands with supra- or oro-Mediterranean belts. Lastly, a low number of endemics (2.5%) are not linked to any particular bioclimatic conditions, since they are found in many bioclimatic belts. Finally, open habitats characterized by long lasting solar radiation are richer in heliophilous endemics (60%) than those where the shade of the canopy or created by rocky outcrops enables the establishment of nemoral (4%) or, in any case, sciaphilous (3.1%) species. Very abundant are the endemics indiferent to solar radiation (32.6%). 7. Environment Our investigations on the Sicilian endemic lora led us to highlight the fact that several diferent habitats behave as suitable refuge for many endemic species. Woodlands, pulvinate scrubs, maquis, garigues, dry grasslands, as well 193 Considerations on the endemic lora of Sicily as many other environments (like rivers, lagoons, salt-marshes, screes, badlands, dunes, clifs, rocky coasts, volcanic substrates, etc.) are rich in endemics. Even some synathropic habitats, such as abandoned ields, roadsides, pastures, host endemic taxa whose ecology and, therefore diferentiation, is likely favoured by soils enriched with nitrogen and phosphates. As one might expect, the most endemic-rich habitats are those more specialized and ecologically selective, such as rocky walls (68), rocky coasts (43), orophilous pulvinate scrubs (38), clifs (22), and badlands (15). All these habitats are characterized by severe environmental conditions that usually hamper the establishment of widespread and common species, and therefore they are colonized by few, extremely specialized, and genetically diferentiated species. Both woods and garigues host 23 endemic taxa, followed by dry grasslands (22), and ephemeral plant communities (28). hese natural or semi-natural formations are usually represented by primary or secondary communities, being characteristic elements of the Sicilian landscape since a long time ago. Furthermore, they seem to be particularly suitable for hosting endemic plants that locally may become quite frequent. As for wet environments, the degree of endemism is low, with only a few species circumscribed to salt-marshes (6) and temporary ponds (4). On the contrary, several endemics are found in synanthropic habitats, such as pastures (21), abandoned ields (14) and roadsides (12). his is probably due to the long-lasting occurrence of abundant livestock (sheep, goats, cows, etc.) that likely acted as selective pressure for the diferentiation of pabular plants. 8. Phytosociology he analysis of the plant communities loristically characterized by Sicilian endemics allows highlighting the role played by each of them within the landscape of the island. hey are usually key-species of one or, exceptionally, more associations, but even of higher syntaxa. In order to provide complete and detailed information on the habitats where they usually grow, the phytosociological classes including associations characterized by Sicilian endemics have been examined. he highest degree of endemics has been recorded for the Asplenietea trichomanis (Br.-Bl. in Meier & Br.-Bl., 1934) Oberd. 1977 (19.8%), a class notoriously rich in rare or narrowly distributed species. In particular, these endemics are represented by chasmophytes whose origin may be dated back to the Tertiary, and that usually ind refuge on clifs or rocky walls, mainly 194 Islands and plants: preservation and understanding of lora on Mediterranean islands carbonatic, where their pioneering character facilitate their own establishment. Several endemics also occur within the plant communities of the RumiciAstragaletea siculi Pignatti & Nimis in Pignatti et al., 1980 (11.7%), class grouping orophilous shrubby phytocoenoses colonizing the high-mountain ridges and the highest peaks of Sicily. Many of these species belong to the Tertiary lora, especially those found on the Mesozoic mountains where they can be considered as relic elements, while the endemic species growing on the top of Mt. Etna have a recent origin, since they are exclusively found on this Quaternary volcano. he perennial dry grasslands of the Lygeo-Stipetea Rivas-Martínez 1978 class, host a considerable number of endemics (11.7%), mostly being very well adapted to the extremely thermo-xeric ecological conditions of the explored sites. he distribution of these endemics was originally restricted to primary stands, much more circumscribed than they are currently. Later, human impact strongly favoured the degradation processes involving most of the natural woods, thus leading to the spreading of these grasslands, and consequently the widening of the distribution range of their characteristic endemic species. Rocky coasts are suitable habitats for the halophilous communities of the Crithmo-Limonietea Br.-Bl. in Br- Bl. et al. 1952, in which several endemic species are localized (8.3%). hese sites are colonized by ecologically very specialized species, chiely belonging to the genus Limonium, which are here represented by amphimictic diploid or polyploid populations (oten with ancestral origins), or by apomictic ones, chiely triploids or aneuploids. Also, the basophilous ephemeral plant communities of the Stipo-Trachinetea distachyae Brullo in Brullo et al. 2001, host a fairly good number of endemics (7.4%), mostly represented by geophytes and therophytes. In particular, they are found on the islets where they grow along the rocky coast and small hollows whose geographical isolation and ecological peculiarity favoured the speciation processes. he shrubby communities of the Cisto-Micromerietea Oberd. 1954, represented by thermophilous garigues, host a fair number of endemic species (6.9%), having a chamaephytic, geophytic, or hemicryptophytic habitat. hese habitats represent secondary stands, whose current wide distribution in Sicily is strictly correlated with the degradation of the original woody vegetation, which took place during the last millennia. Actually, these garigues were previously localized on rocky habitats, where they played the role of edapho-xerophilous communities. he endemic lora characterizing this vegetation has undergone intense speciation processes, which were, and in some case still are, particularly active on the Orchidaceae, as well as on taxonomically isolated shrubby plants. 195 Considerations on the endemic lora of Sicily Another habitat rich in endemic species is represented by the mountain mesophilous meadows, whose typical plant communities fall in the MolinioArrhenatheretea R.Tx.1937 class (4.6%). Most of the endemic species found in these habitats are hemicryptophytes and geophytes, whose evolution has been inluenced by the selective pressure caused by grazing animals. In Sicily, these meadows are loristically characterized by the occurrence of many rare taxa coming from North-Africa and the eastern Mediterranean area. Within the thermophilous and mesophilous woods, ascribed to the Quercetea ilicis Br.-Bl. ex A. & O. Bolòs 1950 and to the Querco-Fagetea Br.-Bl. & Vlieger in Vlieger 1937 class respectively, it is possible to ind some endemic species. As for the former class, they amount to 4.6% of the total lora, while the mesophilous plant communities of the Querco-Fagetea host 3.2% of endemic species. In both cases these insular phytocoenoses are geographically isolated from those found on mainland Italy. he remaining phytosociological classes are characterized by a lower number of endemics (less than 10). Such taxa, although few in number, have a remarkable taxonomical, phytogeographical, or landscape value. In particular, it is important to note that also in classes grouping nitrophilous plant communities, such as Stellarietea mediae von Rochow 1951, Onopordetea acanthi Br.-Bl.1964, Artemisietea vulgaris von Rochow 1951 or Pegano-Salsoletea Br.-Bl. & O. Bolòs 1958, some endemic species whose origin is likely quite recent were found. 9. Vulnerability he role played by endemic species is extremely relevant both in terms of plant diversity and naturalistic value of a given territory. his means that mankind should pay particular attention to take great care of the preservation of the endemic plants. In other words, any action should take into consideration the priority necessity of safeguarding and protecting narrow endemics as a unique natural heritage, which must be passed on to forthcoming generations. he International Union for Conservation of Nature (IUCN) proposed speciic criteria for assessing the vulnerability of plants and animals. he application of such criteria needs in-depth ield surveys in order to better evaluate the real delimitation and consistency of the natural populations. A fundamental pre-requisite for the conservation of any species is the protection of the natural or semi-natural habitats where they live. With regard to Italian territory, some red books have been published by Conti et al. (1992, 1997), Pignatti et al. (2001), and Marconi (2007). In addition to these books, other red lists including Italian taxa are available; they are 196 Islands and plants: preservation and understanding of lora on Mediterranean islands Montmollin & Strahm (2005), Baillie et al. (2004), and a red list edited by EU Commission (DG Environment, 2007). As for the Sicilian endemic lora, about 31.1% of the species is vulnerable (VU). Fairly abundant are species falling into the Critically Endangered (CR) category (27.3%), followed by the Low Risk species (LR), with 25.5% of the total. Far fewer are those species falling into the Less Concern (LC) category (8.4%) or endangered (EN) category (5%), while only very few taxa are labelled as Near hreatened (NT), Extinct (EX), or Extinct in the Wild (EW). Based on the outcome of our survey, it is clear that more research is needed in order to have detailed information on the real conservation status of many endemic species of Sicily. In fact, many endemics are still not included in any of the current red lists, since only 196 taxa are quoted in these lists, 144 of which occur in only one red list (Conti et al., 1997). Most of the species not included in any red list are rare and extremely localized, with only few populations still surviving. his means that great eforts must be made urgently in order to preserve the natural environments suitable for the conservation of these plants. REFERENCES F. Vallardi. Milano. Baillie, J.E.M., Hilton-Taylor, C., Stuart, S.N. 2004. Red List of hreatened Species. A Global Species Assessment. IUCN. Gland, Switzerland and Cambridge. Contandriopoulos, J. 1962. Essai de classiication des endemiques corses. Revue de cytologie et de biologie végétales, 25(3-4): 449-459. Brullo, S., Giusso del Galdo, G., Minissale, P., Siracusa, G., Spampinato, G. 2002. Considerazioni sintassonomiche e itogeograiche sulla vegetazione della Sicilia. Bollettino delle sedute della Accademia Gioenia di Scienze Naturali in Catania, 35: 325-359. Conti, F., Manzi, A., Pedrotti, F. 1992. Libro rosso delle piante d’Italia. Tipar Poligraica Editrice. Roma. Conti, F., Manzi, A., Pedrotti, F. 1997. Liste rosse regionali delle piante d’Italia. Centro interdipartimentale audiovisivi e stampa. Camerino. Brullo, S., Minissale, P., Spampinato, G. 1995. Considerazioni itogeograiche sulla lora della Sicilia. Ecologia Mediterranea, 21(1/2): 99-117. European Commission DG Environment 2007. Interpretation manual of European Union habitats EUR 27. Cesati, de V., Passerini, G., Gibelli, G. 1868-1889. Compendio della lora italiana. 197 Considerations on the endemic lora of Sicily Favager, C., Contandriopoulos, J. 1961. Essai sur l’ endemisme. Bulletin de la Société Botanique Suisse, 71: 384-408. Pignatti, S. 1982. Flora d’Italia. Vol. 1-3. Edagricole. Bologna. Pignatti, S., Menegoni, P., Giacanelli, V. 2001. Liste rosse e blu della lora italiana. ANPA. Alcagraf. Roma. Fiori, A. 1923-1929. Nuova Flora Analitica d’Italia. Vol. 1-2. M. Ricci. Firenze. Giardina, G., Raimondo, F. M., Spadaro, V. 2007. A catalogue of plants growing in Sicily. Bocconea, 20: 5-582. Presl, C.B. 1826. Flora Sicula. Vol. 1. A. Borrosch. Pragae. Greuter, W. 2008. Med-Cheklist. Vol. 2. Luxograph. Palermo. Raimondo, F.M, Spadaro, V. 2009. Addenda et emendanda of the “A catalogue of the plants growing in Sicily”. Flora Mediterranea, 19: 303-312. Greuter, W., Burdet, H.M., Long G. 1984-1989. Med-Checklist. Vol. 1, 3, 4. Conservatoire et Jardin Botaniques. Genève. Strobl, P.G. 1878-1887. Flora der Nebroden. Flora. Vol. 61-70. Strobl, P.G. 1880-1885. Flora des Aetna. Österreichische Botanische Zeitschrit, Vol. 30-35. Gussone, G. 1843-1845. Florae Siculae Synopsis. Vol. 1-2. Typis Tramater. Neapoli. Lojacono-Pojero, M. 1889-1909. Flora Sicula. Vol. 1-3. Tip. Salvatore Bizzarrilli. Palermo. Tornabene, F. 1889-1892. Flora Aetnea. Fasc. 1-4. Tip. Galati. Catania. Tutin, T.G., Heywood, V.H., Burges, N.A., Moore, D.M., Valentine, D.H., Walters, S.M., Webb, D.A. 1964-1980. Flora Europaea. Vol. 1-5. Cambridge University Press. Cambridge. Marconi, G. 2007. Piante minacciate di estinzione in Italia. Il libro rosso fotograico. Perdisa Editore. Bologna. Montmollin, de B., Strahm, W. 2005. he top 50 Mediterranean Island Plants. Wild plants at the brink of extinction, and what is needed to save them. IUCN. Gland and Cambridge. Tutin, T.G., Burges, N.A., Chater, A.O., Edmondson, J.R., Heywood, V.H., Moore, D.M., Valentine, D.H., Walters, S.M., Webb, D.A. 1993. Flora Europaea. Vol.1. Cambridge University Press. Cambridge. Parlatore, F., 1839. Flora Panormitana. Vol. 1. Typographeo Petri Pensante. Palermo. 198 Islands and plants: preservation and understanding of lora on Mediterranean islands Fig. 1 Phytogeographical subdivision of Sicily (ater Brullo et al., 1995). 199 Considerations on the endemic lora of Sicily 200 Islands and plants: preservation and understanding of lora on Mediterranean islands SPECIES RICHNESS, BIOGEOGRAPHIC AND CONSERVATION INTEREST OF THE VASCULAR FLORA OF THE SATELLITE ISLANDS OF SICILY: PATTERNS, DRIVING FORCES AND THREATS Salvatore Pasta1 and Tommaso La Mantia2 Consiglio Nazionale delle Ricerche, Istituto di Genetica Vegetale, Corso Calataimi n° 414, I-90129 Palermo, Italy. 2 Dipartimento SAF, Viale delle Scienze, Ed. 4, Ingr. H, 90128 Palermo. 1 Abstract he vascular lora has been investigated on about 60 of the approximately 100 islands and islets of the Sicilian archipelago. his paper provides detailed information on the number of exclusive, rare, or threatened vascular plants living on these islands and islets. Focusing on the 18 most-investigated islets, we evaluate the extent to which species richness, rate of endemism, number of alien plants, and number of terrestrial habitats have been inluenced by 1) geographical setting, 2) geological history, 3) geo-pedological variability, 4) bioclimate, 5) number and patchiness of local plant communities, and 6) natural and human disturbance history and regime. Special attention is directed to the rarefaction and extinction of many interesting species that live or have lived only on these islands. Rarefaction and extinction are mostly linked to the increase in anthropogenic disturbance, which have caused the destruction, degradation, and/or fragmentation of many plant communities and especially those associated with rocky or sandy shores and temporary ponds. Interestingly, in some cases extinction has resulted from a reduction in certain human activities. For example, many noteworthy species are disappearing with the abandonment of traditional land uses that created low-impact agro-ecosystems, new microhabitats (e.g., stone walls), and open semi-natural habitats (including vineyards, cereal crops, olive groves, and fallows subject to extensive grazing). Finally, we emphasize the need for current information about species turnover, invasion processes, and demographic patterns of the vascular lora of those islands and islets that support the most fragile communities and/or species. Keywords: species richness, rate of endemism, 92/43 EU Directive, conservation policies, island biogeography Corresponding author: Salvatore Pasta (salvatore.pasta@igv.cnr.it) 201 he vascular lora of the satellite islands of Sicily INTRODUCTION he so-called “Tyrrhenian area” is among the most important hot spots of plant diversity in the world (Médail and Quézel, 1997; Myers et al., 2000). According to the most recent checklist of the Sicilian vascular lora (Raimondo et al., 2010), about 3,000 native plants live on the island, and 13% of them are endemic (Table 1). Circum-Sicilian satellite islands and islets also have high species richness. In fact, although they represent just 1% (ca. 250 Km2) of the whole regional territory, they host some 44% of its total lora (Pasta, 1997). In addition, the number of endemic plants hosted by them is high if compared with the main island and its two loristically richest mountainous areas, i.e., Madonie Mts. and Mt. Etna (Table 1). Table 1. Endemic species richness in Sicily: a rough comparison between mountain ranges and satellite islands. 202 Islands and plants: preservation and understanding of lora on Mediterranean islands he Sicilian vascular lora is one of the best studied in Europe. his is also true for the satellite islands of Sicily: over 2,300 years ago, heophrastos (372286 B.C.) wrote about plants growing on the Aeolian Islands, while Boccone, Cupani, and Ray, who were among the most renowned European botanists of the 17th century, began to explore the plants growing on circum-Sicilian islets. One century later, the monk Ucria (1789) followed the Linnaean classiication system in creating the irst checklist of the autochthonous and cultivated plants growing in Sicily. In the irst half of the 19th century, many Italian botanists (e.g., Gussone, 1832-1834), collected and described many new species on the islets. he circum-Sicilian satellite islands and islets number more than 100, but botanical knowledge is greater for some than for others. Over the last 60 years, the vascular lora of 61 islands has been explored at least once and that of 18 has been monitored two or more times. he main steps in the development of the current state of knowledge concerning the circum-Sicilian lora are detailed in Table 2. Plant lists with a comprehensive revision after 2000 (39 islands) Pelagie Arch. (Lampione, Lampedusa, Linosa and Isola dei Conigli: Pasta, 2001, 2002; La Mantia et al., 2009; Lo Cascio and Pasta, 2012); Egadi Arch. (Favignana, Levanzo and Marettimo: Romano et al., 2006; Gianguzzi et al., 2006 + 5 satellite islets: Pasta and Scuderi, 2008; Pasta et al., submitted); Ustica (Pasta et al., 2007b); Isola delle Femmine (Caldarella et al., 2010); Eolie Arch. (23 satellite islets: Lo Cascio and Pasta, 2008); Stagnone Arch. (Santa Maria and Scuola: Scuderi et al., 2007) Plant lists with a comprehensive revision after 1990 (5 islands) Stagnone Arch. (Mozia: Catanzaro, 1992); Scogli dei Ciclopi (3 islets: Siracusa, 1996); Rocca di San Nicola (Pasta, pers. obs.) Plant lists written after 1970 and then partially updated (3 islands) Pantelleria (Brullo et al., 1977); Eolie Arch. (Alicudi and Filicudi: Di Benedetto, 1973; Longhitano, 1983; Pasta, 1997; Pasta and Lo Cascio, 2002) Plant lists written after 1960 and then partially updated (3 islands) Stagnone Arch. (Isola Lunga: Di Martino & Perrone, 1970; Pasta, 2004); Eolie Arch. (Vulcano and Stromboli: Ferro & Furnari, 1968, 1970) Plant lists written after 1910 and subject to few or no improvements (5 islands) SE Sicily (Marzamemi grande, Marzamemi piccola, Vendicari, Capo Passero, Isola delle Correnti: Albo, 1919, 1959; Pirola, 1960; etc.) th 19 century plant lists that have been partially updated (3 islands) Eolie Arch. (Lipari, Salina and Panarea: Lojacono, 1878; Ferro, 1984, 2005; Pasta et al., 1999; Pasta & Lo Cascio, 2002; etc.) th 19 century plant lists subject to few or no improvements (3 islands) Egadi Arch. (Maraone and Formica: Gussone, 1832-1834); Eolie Arch. (Dattilo: Gussone, 1832-1834) Table 2. Current overview on the published plant lists for the circum-Sicilian islands and islets (from Pasta, 1997, updated). Arch = archipelago. 203 he vascular lora of the satellite islands of Sicily his paper provides an overview on the number of exclusive, rare, or threatened vascular plants living on the circum-Sicilian islands and islets, and focuses on the 18 most-investigated islets. We evaluate the extent to which species richness, rate of endemism, number of alien plants, and number of terrestrial habitats have been inluenced by a number of abiotic and biotic factors. We pay special attention to those species whose numbers have been decreasing and that are threatened with extinction. WHICH FACTORS ARE RESPONSIBLE FOR THE FLORISTIC DIVERSITY OF THE CIRCUM-SICILIAN SATELLITE ISLANDS AND ISLETS? Many papers have emphasized the high phytogeographic importance of Sicilian plant heritage (Di Martino & Raimondo, 1979; Nimis, 1985; Brullo et al., 1995; Brullo et al., 2013) but only a few have focused on the major role played by the satellite islands (Pasta, 1997; Mazzola et al., 2002; Raimondo, 2004; Bocchieri & Iiriti, 2011; Troìa et al., 2012; Troìa, 2012). he recorded high values of both species-richness and endemism depend on six main factors: 1) geographical setting; 2) geological (and geological disturbance) history; 3) geopedological variability; 4) bioclimatic belts; 5) number and patchiness of local plant communities; and 6) natural and human disturbance history and regime. Basic data on some of these factors are provided in Table 3, while additional information on their efects is provided in the following paragraphs. Geographical setting he circum-Sicilian islands (Figure 1) have a wide latitudinal range and extend from Lampedusa in the Pelagie Archipelago (at 35°30’ N) to the south and Strombolicchio in the Aeolian Archipelago (at 38°50’ N) to the north. he Strait of Messina (which is 3 km wide) currently separates Sicily from Eurasia, while the nearest part of Africa (Tunisia) is about 70 km from the island of Pantelleria. hese separations may have been less signiicant or non-existent at some times in the geologic past. Plio-Pleistocenic climate change, for example, may have favoured direct plant migration between Sicily and both Eurasia and Africa. In fact, during the Last Glacial Maximum (hereinater LGM, about 18-12 Kya), the sea level was some 80–120 m lower than today (Lambeck et al., 2010), so that the Egadi Islands, Sicily, and the Maltese Archipelago were united; Lampedusa and Lampione were part of Africa; and Pantelleria was less than 10 km from Sicily. Hence, the complex history of past connection and proximity between Sicily and nearby territories may have greatly afected 204 Islands and plants: preservation and understanding of lora on Mediterranean islands the present composition and the species richness of the region’s vascular lora. For example, because it is part of the African continental shelf, Lampedusa hosts a remarkable number of south, southwest, and southeast Mediterranean and Mediterranean-Irano-Turanian species (e.g., Suaeda pelagica, Caralluma europaea subsp. europaea, and Echinops spinosus subsp. spinosissimus). Similarly, because of their repeated past connections with the main island, the Egadi islands host a high number of Sicilian endemics (Table 3). Island No. No. No. No. No. No. surf taxa hab end end end excl (ha) isl arc sic isl rou cli dis Dist LGM Lpe 437 15 12 2 1 15 2,020 c t 205 140 Lpi 18 2 2 0 0 2 4 c t 215 142 Lin 303 10 3 2 2 8 520 v t 161 30 Pte 645 11 7 0 2 15 8,301 v t-m 70 15 Ilu 444 9 0 0 6 0 286 c t 0.5 0 Fav 593 13 1 1 17 0 1,948 c t 8 0 Mar 489 9 7 1 9 4 1,230 c t-m 24.5 2 Lev 480 12 0 0 14 0 565 c t 12.5 0 Ust 498 7 1 0 2 0 865 v t 55 50 Ali 398 5 1 3 2 1 520 v t-m 53 50.5 Fil 405 7 0 1 3 0 950 v t-m 41.5 31 Vul 356 13 0 3 0 1 2,100 v t-m 19.5 17.5 Lip 658 10 0 2 3 2 3,760 v t-m 20.5 17.5 Sal 506 11 0 2 3 0 2,524 v t-m-s 24 17.5 Pan 379 8 0 3 2 1 336 v t 35 29.5 Lbi 45 2 1 1 1 0 3.8 v t 53 41.5 Str 288 8 0 3 0 0 1,260 v t-m 53 41.5 Stc 20 3 0 0 0 2 0.1 v t 56.5 51 Table 3. Statistical data concerning the 18 best-studied circum-Sicilian islets (from Pasta, 1997, updated): Lpe = Lampedusa, Lpi = Lampione, Lin = linosa, Pte = Pantelleria, Ilu = Isola Lunga, Fav = Favignana, Mar = Marettimo, Lev = Levanzo, Ust = Ustica, Ali = Alicudi, Fil = Filicudi, Vul = Vulcano, Lip = Lipari, Sal = Salina, Pan = Panarea, LBi = Lisca Bianca, Str = Stromboli, and Stc = Strombolicchio. No. taxa = number of terrestrial 205 he vascular lora of the satellite islands of Sicily vascular plants; No. hab = number of terrestrial habitats; No. end isl = number of endemics exclusive to the given island; No. end arch = number of endemics on the archipelago; No. end sic = number of endemics of the whole Sicilian region; No. excl arch = number of taxa exclusive to the given island; surf refers to the surface area measured in hectares.; rou = main rock outcrop (c = prev. calcareous, v = prev. volcanic); cli = bioclimate following Rivas-Martínez (2008): i = infra-, t = thermo- and m = meso-mediterranean; dis = distance from the nearest mainland (measured in Km). N.B.: the sharpest diferences between present and past distances are underlined; the nearest mainland is Calabria for Stromboli, Panarea for Lbi, Str for Stc, and Africa for Lampedusa, Linosa, and Pantelleria. During the LGM, the nearest mainland for Linosa and Pantelleria was Sicily. Geological (and geological disturbance) history If we go back millions rather than thousands of years in geological history, the picture becomes even more complex. Although many palaeontologists (e.g., Rook et al., 2006) share the opinion that most of Sicily rose out of the sea only during the Miocene (i.e., 23–5.3 Mya), many others argue that repeated emersion events may have occurred earlier, i.e., during the Mid Cretaceous (120–90 Mya: Zarcone et al., 2010) or at least since the Oligocene (34–23 Mya: Rosenbaum et al., 2002). hese fragments of land may have acted as ‘stepping stones’ for plant migration between Eurasia and Africa even before the Mediterranean Sea acquired its present size and shape. Within this context, only the island of Marettimo may have experienced partial emersion as long as 230–200 Mya (Martini et al., 2007), while all the other islands have a more recent and discontinuous history of connection with the main island. For example, only a few volcanic islands emerged ca. 1.5 Mya, while most of them (e.g., the Aeolian Archipelago) appeared more recently (Calanchi et al., 2007). he ancient and long-lasting isolation of Marettimo probably accounts for much of its loristic originality. In fact, the western-most island of the Egadi Archipelago hosts the only known Sicilian population of four species of high phytogeographic interest, while the only extant relatives of several local endemics currently occur very far away. For example, hymus nitidus is related to T. richardii subsp. ebusitanus of Ibiza as well with T. richardii subsp. richardii of Majorca and the former Yugoslavia (Morales, 1997); Bupleurum dianthifolium is related to B. barceloi of Majorca; and Pseudoscabiosa limonifolia is closely related to P. saxatilis of southern Spain. As a consequence of the tectonic uplit of southern Spain and NW Africa, at the end of the Miocene (5.96–5.33 Mya), the Mediterranean Sea was separated from the Atlantic Ocean, and its waters gradually dried and disappeared. 206 Islands and plants: preservation and understanding of lora on Mediterranean islands Hence, many drought and salt-tolerant African species could colonize Europe via the Strait of Sicily. If this event, known as the Messinian crisis, ended with a tremendous tsunami, as suggested by García-Castellanos et al. (2009), then the lowland life of most of the Mediterranean Basin probably had to re-start from bare rock. he geological history of Sicily provides many examples of catastrophic volcanic activity that erased the existing lora: Vulcano (De Astis et al., 1997) and Stromboli (Rosi et al., 2000) erupted explosively and nearly continuously during the Plio-Pleistocene, while Pantelleria (Civetta et al., 1988), Lipari (Crisci et al., 1990), Salina (Gertisser & Keller, 2000), and Panarea (Lucchi et al., 2007) have been active during human history. Fig. 1. Map of the major satellite islands and archipelagoes and some of the main mountainous areas of Sicily (1: Palermo Mts.; 2: Sicani Mts.; 3: Madonie Mts.; 4: Iblei Mts.; 5: Mt. Etna). 207 he vascular lora of the satellite islands of Sicily Geo-pedological variability Another important consequence of the rather complex geological history of Sicily is the diversity of rock outcrops, which in turn involve a high variety of soil types. On the circum-Sicilian islands, the most common geological substrata are: 1) sandy or compact limestones/dolomites (which cover most of Lampedusa, Lampione, Egadi islands, and Stagnone islands and also all the minor W, NW, and SE islets); 2) base-rich or acid vulcanites (which cover Linosa, Pantelleria, Ustica, the Aeolian Islands and islets, Scogli dei Ciclopi, and part of Capo Passero islet); and 3) marls (which cover part of Lampedusa). Calcareous islands share the same pedological pattern: uneven soil depth, scattered distribution of soil and rock outcrops, and a high variety of soil assemblages. he co-occurrence of the latter three factors seems to enhance species richness (Pasta, 1997) by multiplying the niches available to root systems (Figure 2). he low plant species richness recorded on some volcanic islands (e.g., Linosa, Vulcano, and Stromboli) may be due to their rather recent emersion and/or to the frequent disruptive events, so that they are not yet saturated in terms of species richness, which is consistent with the basic principles of island biogeography (MacArthur & Wilson, 1963). Fig. 2. he pattern of correlation between α- (i.e., species-richness) and β-diversity (i.e., number of suitable ecosystems) appears to be rather regular and distinct for volcanic and calcareous islands. 208 Islands and plants: preservation and understanding of lora on Mediterranean islands Bioclimatic belts Although circum-Sicilian islets host very few weather stations, the models provided by Drago (2002) indicate that they harbour three bioclimatic thermotypes (sensu Rivas-Martínez, 2008) whose distribution (Figure 1) mostly depends on latitude and altitude. he harshest thermotype, infra-mediterranean, occurs on the islets in the Strait of Sicily (the whole Pelagian Archipelago and the lowest part of the Egadi islands and Pantelleria). he thermo-mediterranean thermotype is widespread up to 450 m a.s.l. on all the satellite islands. he tops of the major islands (i.e., Pantelleria, Marettimo, Alicudi, Filicudi, Lipari, Salina, and Stromboli) that exceed 600 m a.s.l. experience the meso-mediterranean thermotype. Moreover, a very humid microclimate occurs on the top (> 800 m a.s.l.) of Pantelleria, Salina, and Stromboli. In the absence of anthropogenic disturbance, those circum-Sicilian islets that are subject to the infra or thermo-mediterranean climate should be covered by a discontinuous maquis dominated by evergreen or summer-deciduous shrubs (e.g., Anagyris foetida, Euphorbia dendroides, Lycium intricatum, Periploca angustifolia, Rhus pentaphylla) and a few conifers like Pinus halepensis and Juniperus turbinata, while the meso-mediterranean belt should be dominated by thermophilous oak woods containing Quercus ilex, Q. suber, and Q. virgiliana (and Pinus pinaster subsp. hamiltonii at Pantelleria). According to many recent studies of the Pleistocene (Agnesi et al., 2000; Incarbona et al., 2010), glacial maxima probably coincided with very arid conditions in the central Mediterranean, so that the most widespread Sicilian natural landscape was a savannah with very scattered tree cover (Noti et al., 2009; Tinner et al., 2009). On the other hand, several works focusing on the genetic diversity of woody trees have highlighted the special role played by the main island; the canyons and the mountain ranges facing the northern coast acted as refugia because of their humid meso and microclimate (DumolinLapègue et al., 1997; Hewitt, 1999; Fineschi et al., 2005; ecc.). he same role could have been played by satellite islands, which still host some exceptionally isolated species such as Pseudoscabiosa limonifolia (Devesa, 1984), Bupleurum dianthifolium (Neves & Watson, 2004), Cytisus aeolicus (Cristofolini & Troìa, 2006), and Eokochia saxicola (Kadereit & Freitag, 2011). Number and patchiness of local plant communities Table 4 outlines the high heterogeneity of the natural landscape of 18 circumSicilian islets. In fact, these islets host 29 diferent habitats of community interest according to the 92/43 EU Directive. he large number of niches and 209 he vascular lora of the satellite islands of Sicily the unevenness of their distribution and cover probably account for much of the loristic richness and diversity between archipelagoes and among islets of the same archipelago. Habitat status on 18 circum-Sicilian islets Habitat Lpe Lpi 1210 P 1240 P L Lin Pte ILu L EX T P 1310 1410 1420 L 1430 P P P P P P P L L P T P L L Mar Ust Ali P T P P L Fil Vul L P P L EX L P P L P P P P P L T T P L L P P T P 2210* T 2230 T 3140 T 3150 T 3170* T 5210 EX EX 5320 P T L T L EX T T T T L T T T T EX EX P P P P P P P P P P P T 5330 P P P 5430 P P P 6220* P P P P P P P P P P P P P P P P P P P P P P P P P P P P P P P 6310 P L 8130 P 8210 P 8220 P P P P P 8320 P P P 8310 P P EX EX 9260 P 9340 EX P P P P P P P P P P P EX EX EX T T EX T EX EX T P P P P 91AA* 9320 Lip Sal Pan LBi Str Stc EX 1510* 2110 Fav Lev P EX EX EX T EX EX EX EX 9540 EX P 15 2 10 11 9 13 9 12 7 5 7 13 10 11 8 2 8 3 T 7 0 2 1 0 3 1 4 2 0 0 3 3 1 1 0 0 0 P T L 1 1 2 0 1 3 2 1 0 1 1 1 2 2 1 0 0 0 EX 2 0 1 1 0 1 1 0 1 2 3 3 3 3 2 0 2 0 210 Islands and plants: preservation and understanding of lora on Mediterranean islands Table 4. he status of the terrestrial habitats (according to the 92/43 EU Directive) on 18 circum-Sicilian islets. P = present; T = threatened by direct human pressure; L = localised; EX = extinct in historic times. Island abbreviations are provided in Table 3. he history of natural and human disturbance Besides earthquakes, tsunamis, and volcanoes, two other disturbance factors have greatly afected the Sicilian landscape: herbivores and humans. Herbivores could have afected the loristic assemblages of chersogenous islands (Greuter, 1991) like Favignana, Levanzo, and Lampedusa at least since the beginning of the Pleistocene (Capasso Barbato et al., 1988; Boniglio et al., 2002), while humans irst occasionally and permanently colonized Sicily c. 35 and c. 20 Ky BP, respectively (Tusa, 1994; Mussi, 2001). Human activities have inluenced the natural landscapes of the main circum-Sicilian islands since the Mesolithic (e.g., Levanzo) and during the Neolithic (e.g., Lampedusa, Pantelleria, Favignana, Ustica, and the Aeolian Archipelago). Burning, clearing, cutting, farming, ploughing, etc. not only fostered the success of many allochthonous pioneer and helio-xerophilous plants now referred to as “archaeophytes” but also gave rise to a complicated mosaic of prevalently open habitats dominated by subshrubs and grasses (Guarino et al., 2005; Guarino, 2006). Forest communities were nearly erased, so that many woody species such as Acer campestre or Quercus cfr. virgiliana disappeared during pre-historic (Poggiali et al., 2012) or historic (Calò et al., 2013) times or are now threatened with extinction (La Mantia & Pasta, 2005). In recent times, and especially during the last 20–40 years, nearly all Mediterranean islands experienced a strong decline in agro-pastoral activities. Nonetheless, the frequency and intensity of past human disturbance still afects the current plant communities, including the speed and the path of succession (Quézel & Médail, 2003; Blondel, 2007). Over recent decades, the major threats to natural conservation involve the destruction and fragmentation of native ecosystems, mostly due to seasonal mass tourism and its by-products (e.g., garbage dumping and alien introduction: Briasoulis, 2003; Vogiatzakis et al., 2008; Afre et al., 2010) and to improper aforestation activities. A DEEPER INSIGHT INTO THE EFFECTS OF HUMAN PRESSURE In the following paragraphs, we analyse the complex interaction between botanical heritage, past and present human pressure, and conservation priorities. 211 he vascular lora of the satellite islands of Sicily Agriculture Human activities can increase loristic diversity: in fact, the traditional lowimpact agricultural practices typical of the circum-Sicilian islands (including horticulture; cereal crop culture; olive, caper, and wine culture on terraces surrounded by stone walls; etc.) gave rise to complex agro-ecosystems formed by cultivated areas and fallows that hosted, and still host, many interesting species and plant communities that are rapidly disappearing with land abandonment. his is the fate of many companion species of the last cereal crops and fallows at Lampedusa (Pasta, 2001; La Mantia et al., 2011), Marettimo (Gianguzzi et al., 2006), Ustica (Pasta et al., 2007b), Pantelleria, and the Aeolian Islands (Rühl & Pasta, 2008). At present, some of these plants, like Volutaria lippii and Marrubium alysson, live only in the fallows of Linosa and Lampedusa, and nowhere else in Sicily. Fig.3. One of the last terraced areas of Lampedusa (Pelagie Archipelago) devoted to cereal crop cultures (photo T. La Mantia). 212 Islands and plants: preservation and understanding of lora on Mediterranean islands Fig.4. he progressive succession ater abandonment of Pantelleria’s cultivated terraces leads to a very fast recovery of shrubland and maquis communities (photo J. Rühl). Grazing Grazing and cattle management are important for nature conservation in the circum-Sicilian islands, as exempliied by the vascular lora of Lampedusa. he island hosts the only Italian populations of several “grazing-dependent” plants like Colymbada acaulis and Echinops spinosissimus subsp. spinosus. According to recent reports (La Mantia et al., 2009), the spread and survival of the former species depends on grazing disturbance, while the rapid decrease of the latter species correlates with the cessation of pastoral practices. Moreover, Caralluma europaea subsp. europaea, Ophrys picta, and Oncostema dimartinoi are “grazing-tolerant” in that they prefer open areas with more light and space but sufer from overgrazing and mechanical damage caused by trampling. Finally, overgrazing leads to the increasing extension of grasslands dominated by poisonous geophytes like Charybdis maritima and Asphodelus ramosus and the local endemic hapsia pelagica (Brullo et al., 2009b); the latter species may be indirectly favoured by high grazing pressure because of its low palatability. 213 he vascular lora of the satellite islands of Sicily Seasonal tourism Mass summer tourism provides rapid, short-term economic beneits but causes long-lasting ecological and economic damage. Summer tourism heavily impacts coastal ecosystems, especially sandy beaches (on Lampedusa, Linosa, Favignana, Vulcano, Panarea, and Stromboli), whose plant communities are greatly altered or even destroyed. Moreover, the continuous increase of of-road vehicles and parking areas near the coasts not only threatens the survival of many noteworthy species by increasing the fragmentation of their communities but also reduces their reproductive success because the dust generated by cars outcompetes pollen. his seems to be the sad fate of many endemic Limonium species such as L. aegusae at Favignana. Some species, like rupicolous ones, seem to be safe from this form of disturbance because they colonize sites that are diicult to reach and/or are far from the most crowded areas. In contrast, species like Juncellus laevigatus subsp. laevigatus, Limonium secundirameum, and Schoenoplectus lacustris subsp. thermalis live along the borders of “Lago di Venere” at Pantelleria and are subject to high anthropogenic pressure; because of their extreme localization, they seem somehow “self-condemned” as they become rarer and rarer due to high human pressure near the hot springs during summer. Fig. 5. he Aeolian Islands have experienced deep land use changes over recent decades. Here we see the touristic centre of Vulcano (photo T. La Mantia). 214 Islands and plants: preservation and understanding of lora on Mediterranean islands Mass tourism causes other collateral damage. For example, the entire life cycle of some endemic (e.g., Elatine gussonei) and protected species (e.g., Matricaria aurea) on Lampedusa is linked to small rock pools and temporary ponds, which have been and are continuing to be destroyed by unmanaged and illegal urbanization associated to tourism. Waste increase Insuicient or incorrect management of public and private waste dumps has supported a rapid increase in numbers of the yellow-legged seagull (Larus michahellis) throughout the whole Mediterranean basin (Médail & Vidal, 1998; Vidal et al., 2000). he consequences have been large and negative. Lampione, for example, currently hosts only 20 of the 36 plant species that it hosted 50 years ago, when no seagulls lived there; today, 300 pairs of seagulls breed and exploit the rubbish mounds on Lampedusa (some 20 Km from the islet). he local impact of seagull colonies has been particularly large on endemic plant species: Daucus rupestris, a rare Sicilian endemic, has already become extinct, while Limonium albidum and Bellevalia pelagica, which are strictly endemic on this tiny islet, are currently represented by only ca. 50 individuals (Brullo et al., 2009) and are threatened by direct disturbance (trampling, nesting activities) and indirect disturbance (nutrient increase and soil quality disruption) caused by seagulls (Pasta, 2002a; Lo Cascio & Pasta, 2012). Large seagull colonies have greatly inluenced other Sicilian microinsular plant assemblages; seagull colonies, for example, have caused an intense species turnover and a signiicant increase of xenophytes at Isola delle Femmine near Palermo (Caldarella et al., 2010). 215 he vascular lora of the satellite islands of Sicily Fig. 6. he natural landscape of Lampione and many others islets is strongly afected by a huge colony of yellow-footed seagulls (photo S. Pasta). Fig. 7. Many circum-Sicilian islands, like Linosa, are characterised by a patchy landscape due to gradual land abandonment (photo S. Pasta) 216 Islands and plants: preservation and understanding of lora on Mediterranean islands Alien introduction he data reported in Table 5 suggest that volcanic islands are more vulnerable than other kinds of islands to xenophytes. he data also conirm a pattern previously observed on many other Mediterranean and Canarian islands, which is that the vulnerability to alien invasion is positively correlated with the endemism rate. Many xenophytes are already established on the circum-Sicilian islands. hey were mostly introduced for ornamental purposes (Mazzola & Domina, 2008) and began to become naturalised during the 19th century (Pasta, 2003). Some currently act as dangerous invaders and are menacing not only to pre-forest and forest communities (e.g., Acacia spp., Ailanthus altissima, and Paraserianthes lophantha: Villari & Zaccone, 1999; Badalamenti et al., 2012; Pasta et al., 2012b) and coastal communities (e.g. Carpobrotus spp., Pennisetum setaceum: Vilà et al., 2006; Pasta et al., 2010), but also to islet endemics (Troìa et al., 2005; Pasta & La Mantia, 2008). Global warming may have played an important role in the steep increase of casual, naturalized, and even invasive aliens on Sicilian satellite islands during recent decades, and the ecological consequences of this trend could be even more severe in the future (Gritti et al., 2006; Heywood, 2011). Table 5. A rough comparison between the conservation value and the invasion rate of the vascular lora of 18 circum-Sicilian islets. Island abbreviations are provided in Table 3. Aforestation Since the 1960s, some parts of Lampedusa, Linosa, Marettimo, Levanzo, Ustica, Salina, Vulcano and Favignana have been used for the development of artiicial plantations. Unfortunately, these plantations have greatly reduced local plant diversity and harmed ecosystem functioning, especially in plantations where the inal canopy cover is too dense, where needle litter is not managed, and where soil erosion is excessive because of incorrect pre-planting practices (Pasta et al., 2012a). In particular, the use of non-native Pinus halepensis germplasm has substantially reduced the survival of the small remnant nuclei of 217 he vascular lora of the satellite islands of Sicily indigenous pines once present on Lampedusa and Marettimo and has favoured the establishment of several allochthonous trees and shrubs. CONCLUDING REMARKS A precious but endangered treasure More than 300 vascular plants (i.e., about 20% of the total lora of the circum-Sicilian islands) should be considered ‘noteworthy’ because of their biogeographic interest, e.g. 129 regional or local endemics or taxa situated at the latitudinal or longitudinal limit of their distribution area (Pasta, 1997). Moreover, 49 out of 135 Sicilian plants included in the annexes and appendices of the Bern and/or Washington (CITES) Conventions and/or the 92/43 EU Directive (Table 6) live also or only on circum-Sicilian islands. When considering the two available regional red lists following IUCN risk categories, 182 of 660 and 118 of 1,057 extinct or threatened species reported by Conti et al. (1997) and Raimondo et al. (2011), respectively, live on the considered islands and islets. Although Greuter (1991) emphasized the very high stability of Mediterranean lora, over the last two centuries extinction has occurred much more frequently than previously thought on many circum-Sicilian islands and islets. In fact, two-thirds of those species that are extinct or extinct-in-the-wild are microinsular endemics (Table 7), and many species that are protected and/ or included in Sicilian red lists have experienced local extinction or strong rarefaction over recent decades. hese include Allium subvillosum, Ambrosia maritima, Arbutus unedo, Asphodelus tenuifolius, Asplenium balearicum, Brassica macrocarpa, Calendula maritima, Cistus parvilorus, Cynomorium coccineum, Daucus rupestris, Erica sicula subsp. sicula, Erucastrum virgatum, Euphorbia papillaris, Glaucium corniculatum, Globularia alypum, Limonium avei, Loelingia hispanica, Ophrys lunulata, Orchis provincialis, Osmunda regalis, Phyllitis sagittata, Pinus halepensis, Silene bellidifolia, Silene turbinata, Suaeda vermiculata, among others. In most cases, plant disappearance has been caused, or at least enhanced, by human activities. his has undoubtedly been the case for Lampedusa and Linosa, whose natural landscapes were rapidly disrupted during the second half of the 19th century (Pasta & La Mantia, 2004). Many local extinctions involved plants that were linked to the most fragile ecosystems, such as sandy shores, dunes, brackish lagoons, temporary ponds, and forests; these habitats have been strongly disturbed or completely destroyed by human activities and 218 Islands and plants: preservation and understanding of lora on Mediterranean islands are still severely threatened by them (Table 4). Moreover, psammophilous plant communities (and their habitats, i.e., 1210, 2110, 2210*, and 2230) oten occur in small areas and can be easily destroyed by human disturbance. Other species may have disappeared (or are severely threatened) because of their extremely narrow ecological requirements and/or distribution range. An example is Eokochia saxicola (Santangelo et al., 2012). Taxon Bern Ann. 1 Brassica insularis Moris CITES App. 2 92/43 EU Directive Ann. Ann. A B X Ann. 2 Ann. 4 X X Brassica macrocarpa Guss. X X X Bupleurum dianthifolium Guss. X X X Cephalanthera rubra (L.) L.C.M. Richard X Cyclamen hederifolium Aiton X X Cyclamen repandum Sm. X X X Cytisus aeolicus Guss. X X X X 1 X X X X X X X X Dianthus rupicola Biv. Elatine gussonei (Sommier) Brullo Eokochia saxicola (Guss.) Freitag & G. X Kadereit Epipactis cfr. microphylla (Ehrh.) Sw. 2 X X Euphorbia dendroides L. X X Himanthoglossum robertianum (Loisel.) X X P. Delforge Limodorum abortivum (L.) Sw. X X Limodorum trabutianum Batt. X X Ophrys apifera Huds. X X Ophrys apulica (O. & E. Danesch) O. & X X Ophrys bertolonii Moretti X X Ophrys bombyliflora Link X X Linaria pseudolaxiflora Lojac. X X X E. Danesch Ophrys explanata Lojac. X X Ophrys flammeola Delforge X X Ophrys grandiflora Ten. X X Ophrys incubacea Tod. Ophrys lunulata Parl. Ophrys lutea Cav. X X X X 219 X X X X X Ann. 5 he vascular lora of the satellite islands of Sicily Ophrys lutea Cav. X X Ophrys picta Link X X Ophrys scolopax Cav. X X Ophrys sicula Tineo X X Ophrys speculum Link X X Ophrys sphegifera Willd. x x X X Orchis collina A. Russel X X Orchis commutata Tod. X X Orchis intacta Link X X Orchis italica Poir. X X Orchis lactea Poir. X X Orchis longicornu Poir. X X Orchis papilionacea L. X X X X Orchis anthropophora (L.) All. X Ruscus aculeatus L. Serapias bergonii E.G. Camus X Serapias cordigera L. X X Serapias cossyrensis B. & H. Baumann X X Serapias lingua L. X X Serapias nurrica Corrias X X Serapias parviflora Parl. X X Serapias vomeracea (Burm. fil.) Briq. X X Silene hicesiae Brullo & Signorello Spiranthes spiralis (L.) Chevall. X X X X Table 6. Plants of the circum-Sicilian islands protected by the Bern and CITES international conventions and the 92/43 EU Directive (data from Mercurio et al., 2012, modiied). Ann. = Annex; App. = Appendix; 1the populations of Lampedusa are ascribed to subsp. lopadusanus, while those of he Aeolian Islands are ascribed to subsp. aeolicus; 2 the population of Epipactis on Pantelleria is designated cfr. microphylla pending the results of ongoing investigations. 220 Islands and plants: preservation and understanding of lora on Mediterranean islands Endemic plants of the circum-Sicilian islands that have become extinct Echium spurium Lojac. and Limonium parvifolium (Tineo) Pignatti (Pantelleria); Limonium catanense (Lojac.) Brullo (sea cliffs near the harbour of Catania) Endemic plants of the circum-Sicilian islands that only survive in farming Limonium intermedium (Guss.) Brullo and Cistus × skanbergi Lojac. (Lampedusa) Regional extinction of plants once present only on circum-Sicilian islands Lampedusa: Carthamus lanatus L. subsp. baeticus (Boiss. & Reuter) Nyman, Launaea nudicaulis (L.) Hook. f., Teucrium creticum L. Linosa: Medicago secundiflora Durieu, Patellifolia patellaris (Moq.) A.J. Scott, R.V. Ford-Lloyd & J.T. Williams, Silene muscipula L., Spergula fallax (Lowe) E.H.L. Krause Egadi: Astragalus thermensis Valsecchi Eolie: Lamium purpureum L. Exclusive endemic plants of the circum-Sicilian islands Pelagie: Limonium lopadusanum Brullo; Lampedusa: Allium hemisphaericum (Sommier) Brullo, Allium lopadusanum Bartolo, Brullo & Pavone, Allium pelagicum Brullo, Pavone & Salmeri, Anthemis lopadusana Lojac., Chiliadenus lopadusanus Brullo, Daucus lopadusanus Tineo, Dianthus rupicola Biv. subsp. lopadusanus Brullo & Minissale, Diplotaxis scaposa DC., Oncostema dimartinoi (Brullo & Pavone) F. Conti & Soldano, Suaeda pelagica Bartolo, Brullo & Pavone and Thapsia pelagica Brullo, Guglielmo, Pasta, Pavone & Salmeri; Linosa: Erodium neuradifolium Delile var. linosae (Sommier) Brullo, Limonium algusae (Brullo) Greuter, Pancratium linosae Soldano & F. Conti and Valantia calva Brullo; Lampione: Bellevalia pelagica C. Brullo, Brullo & Pasta, Limonium albidum (Guss.) Pignatti↓ and Pancratium sp. Pantelleria + Linosa: Filago lojaconoi (Brullo) Greuter Pantelleria: Anthemis cossyrensis (Guss.) Guss., Helichrysum errerae Tin. var. errerae, Limonium cosyrense (Guss.) O. Kuntze, Limonium secundirameum (Lojac.) Greuter↓, Matthiola incana (L.) R. Br. subsp. pulchella (P. Conti) Greuter & Burdet and Serapias cossyrensis B. & H. Baumann Egadi: Brassica macrocarpa Guss.↓; Marettimo: Allium franciniae Brullo & Pavone, Bupleurum dianthifolium Guss., Helichrysum errerae Tin. var. messerii (Pignatti) Raimondo, Limonium tenuiculum (Guss.) Pignatti, Oncostema hughii (Guss.) Speta, Prospero hierae Brullo, C. Brullo, Giusso, Pavone & Salmeri and Thymus nitidus Guss.; Favignana: Limonium aegusae Brullo↓ Ustica: Limonium usticanum Giardina & Raimondo Eolie: ?Anthemis aeolica Lojac.↓, Centaurea aeolica Lojac. subsp. aeolica, Cytisus aeolicus Guss.↓, Genista thyrrena Valsecchi subsp. thyrrena and Silene hicesiae Brullo & Signorello; Alicudi: Erysimum brulloi Ferro 221 he vascular lora of the satellite islands of Sicily Plants that only occur on circum-Sicilian islands within the regional territory Lampedusa: Caralluma europaea (Guss.) N.E. Br. subsp. europaea, Cistus parviflorus Lam.↓, Colymbada acaulis (L.) Holub, Echinops spinosissimus Turra subsp. spinosus Greuter, Elatine gussonei (Sommier) Brullo, Eruca sativa Mill. subsp. longirostris (Uechtr.) Jahand. & Maire, Hypericum aegypticum L. subsp. webbii (Spach) N.K.B. Robson, Linaria reflexa (L.) Desf. subsp. lubbockii (Batt.) Brullo, Marrubium alysson L., Ophrys picta Link and Paronychia arabica (L.) DC. subsp. longiseta Batt., Linosa: Astragalus peregrinus Vahl subsp. warionis (Gand.) Maire, Linaria pseudolaxiflora Lojac., Lotus halophilus Boiss. & Spruner, Silene apetala Willd.↓, Silene behen L.↓ and Volutaria lippii (L.) Maire Pantelleria + Linosa: Bellium minutum L. Pantelleria: Allosorus guanchicus (Bolle) Christenh., Antirrhinum tortuosum Bosc., Calicotome spinosa (L.) Link, Carex illegitima Cesati, Genista aspalathoides Lam., Juncellus laevigatus (L.) C.B. Clarke subsp. laevigatus, Limodorum trabutianum Batt., Ophrys sphegifera Willd., Pinus pinaster Solander subsp. hamiltonii (Ten.) Huguet del Villar, Schoenoplectus litoralis (Schrader) Palla subsp. thermalis (Trabut) Hooper and Scrophularia frutescens L. Egadi: Aristolochia navicularis Nardi; Favignana: Ophrys scolopax Cav.; Marettimo: Erodium maritimum (L.) L'Hérit., Daphne sericea Vahl and Thymelaea tartonraira (L.) All. Eolie: Clematis vitalba L., ?Daucus foliosus Guss., Eokochia saxicola (Guss.) Freitag & G. Kadereit, Vicia articulata Hornem., Wahlenbergia lobelioides (L. f.) Link subsp. nutabunda (Guss.) Murbeck Isole del Canale di Sicilia: Filago gussonei Lojac., Hornungia revelierei (Jordan) Soldano, F. Conti, Banfi & Galasso subsp. sommieri (Pamp.) Soldano, F. Conti, Banfi & Galasso, Periploca angustifolia Labill. and Reichardia tingitana (L.) Roth Table 7. Biogeographical “highlights” of the vascular lora of Sicilian satellite islands. ↓ = subject to recent demographic decrease. ? = taxa whose taxonomic status is uncertain. 222 Islands and plants: preservation and understanding of lora on Mediterranean islands Fig. 8. Filago lojaconoi is a dwarf annual plant endemic of Linosa and Pantelleria (photo S. Pasta). Fig. 9. Oncostema dimartinoi is endemic to Lampedusa Island (photo G. Nicolini). 223 he vascular lora of the satellite islands of Sicily Fig. 10. Matthiola pulchella colonizes the rocky habitats of Pantelleria (photo L. Scuderi). Fig. 11. Silene hicesiae is one of the most interesting plants that live only on Aeolian Islands (photo P. Lo Cascio). 224 Islands and plants: preservation and understanding of lora on Mediterranean islands Fig. 12. Limonium lojaconoi is a plant endemic of Egadi Islands and western Sicily (photo L. Scuderi). Natural processes and conservation policies How to cope with land-use change? he high level of species and habitat-richness of the circum-Sicilian islands and islets cannot be maintained by a strategy of non-intervention. Recent ield investigations of succession on the circum-Sicilian islands have demonstrated that in the absence of low and regular disturbance regimes (e.g., monitored agricultural and pastoral activities), the patchy vegetation of some islands (especially the volcanic ones) will change into monotonous and rather speciespoor pre-forest and forest communities within a few decades (Rühl et al., 2006; Pasta et al., 2007a; La Mantia et al., 2008; Rühl & Pasta, 2008). As a consequence, many cultural landscapes will vanish along with many noteworthy plant species, like the dwarf annual species that thrive in the ephemeral prairies or in the fallows. On the other hand, the intervention required for promoting forest recovery and for maintaining local species-richness must be carefully planned. To prevent the irreversible loss of many island ecosystems, we emphasize the urgent need to apply the land-use measures already described in the Management Plans of the Natura 2000 Sites concerning Sicilian satellite islands (http://www.artasicilia.eu/web/natura2000/index.html). 225 he vascular lora of the satellite islands of Sicily Re-think aforestation, now or never Six of eleven of the terrestrial habitats that have disappeared on at least one of the circum-Sicilian islands correspond to woody plant communities, and these are 5210 (arborescent matorral with Juniperus spp.), 91AA* (Eastern white oak woods), 9260 (Castanea sativa woods), 9320 (Olea and Ceratonia forests), 9340 (Quercus ilex and Quercus rotundifolia forests), and 9540 (Mediterranean pine forests with endemic Mesogean pines) (Table 4). Moreover, the abovementioned studies on succession outlined that the speed and the path of secondary succession mostly depend on 1) the structure of landscape patchwork (i.e., the average distance between patches requiring propagules and mature patches where those propagules are produced), 2) the disturbance regime (i.e., frequency and intensity), and 3) climate and microclimate. Because of diferent combinations of these three parameters, succession at Lampedusa will require more than one century in order to reach a mature woody community, while a total recovery of the evergreen maquis at Pantelleria will occur within 50 years. hus, aforestation practices could be recommended not only where pre-forest and forest ecosystems are critically endangered or have already disappeared but also to facilitate the natural progressive succession processes under severe bioclimatic stress. For this purpose, old-fashioned practices like subsoiling and planting pure, dense, and monospeciic stands should not be used because they have been proven to be inefective in re-activating local ecosystem functioning. Such practices should be replaced by more sustainable and low-impact ones, like the regular sowing of a mixture of seeds of native shrubs that are able to enhance or restore local facilitation mechanisms (Pasta et al., 2012a). As already emphasized by Pasta and La Mantia (2009), Sicilian forest ecosystems play an important role in protecting many endemic, rare, or endangered plants. his is true also in the case of satellite islands, where seminatural woodlands also deserve special attention. For example, the remnant Castanea sativa orchards at Pantelleria and in the Aeolian Archipelago are not only a living monument of past agro-forestry activities but also continue to be the unique habitat for the rare, threatened, and/or protected plant species listed in Tables 6–7. As a consequence, any future project aimed at managing or even restoring Sicilian microinsular pre-forest and forest ecosystems must be planned carefully to avoid abrupt changes of abiotic factors (e.g., light and humidity) or biotic factors (e.g., herb-layer coverage) that could menace those plants that require protection. 226 Islands and plants: preservation and understanding of lora on Mediterranean islands First eforts to conserve the botanical heritage of Sicilian satellite islands he Aeolian Islands provide a paradigmatic example of the sharp diferences between conservation legal measures and their present application. Although most of them are included within regional nature reserves, and although they belong to the Natura 2000 network and are included in UNESCO’s World Heritage List (http://whc.unesco.org/en/list/), illegal practices leading to environmental damage are still very common and usually go unpunished. On the other hand, ater decades of mere species listing, researchers and politicians are demonstrating an increasing interest in the conservation of Mediterranean island plants (Delanoë et al., 1996; Montmollin & Strahm, 2005). At the local scale, the irst ield inventories for conservation purposes have been conducted (e.g., rare and threatened woody species of Lampedusa: La Mela Veca et al., 2003) and trials have been made in order to assess the best multidisciplinary criteria for determining the natural values of some territories (e.g. Aeolian Archipelago: Lo Cascio & Pasta, 2004). Meanwhile, some LIFE Projects have already aimed at conserving the vascular lora and the plant communities of Sicilian satellite islands. he irst project, NAT/IT/006217 (named “Eolife99”), focused on in situ and ex situ conservation of four species on he Aeolian Islands of priority interest according to the 92/43 UE Directive (Troìa et al., 2005; http://web.tiscali.it/ecogestioni/eolife). Subsequently, some locally threatened species have been propagated within the Project NAT/ IT/000163 “Riduzione impatto attività umane su Caretta e Tursiope e loro conservazione in Sicilia” at Lampedusa (La Mantia et al., 2012), while invasive alien plant eradication is one of the objectives of Project NAT/IT/000093 (“Pelagic Birds”; http://www.pelagicbirds.eu/). It is important that ex situ conservation actions (through seed banks: Gómez Campo, 1979; Khoury et al., 2010) and in situ conservation actions (Olivier & Hernández-Bermejo, 1995) carefully consider the genetic variability of the threatened species at the population level (Conte et al., 1998; Troìa & Burgarella, 2004; Palla et al., 2007; Scialabba et al., 2008). Moreover, a very wide knowledge gap on the reproductive biology of nearly all Sicilian insular endemics still needs to be illed (Iriondo et al., 1994). ACKNOWLEDGEMENTS his paper is dedicated to the irst author’s daughter, Jasmine, born two days ater the conclusion of the meeting of Es Mercadal. Moreover, we both are very grateful to Pere Fraga i Arguimbau for encouraging us to submit this paper and to Giuseppe Garfì for his useful suggestions that improved the quality of 227 he vascular lora of the satellite islands of Sicily the manuscript. Finally, we are very grateful to our friends Pietro Lo Cascio, Leonardo Scuderi, Giuseppina Nicolini, and all the staf of the Nature Reserve “Isola di Lampedusa” for the huge amount of photographs and information provided over the last 15 years on the vascular plants of ‘their’ islands. Some activities were conducted within the Project LIFE11 NAT/IT/000093 PELAGIC BIRDS, with the contribution of the LIFE inancial instrument of the European Union. REFERENCES Blondel, J. 2007. On humans and wildlife in Mediterranean islands. Journal of Biogeography, 35(3): 509-518. 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Vilà, M., Tessier, M., Suehs, C.M., Brundu, G., Carta, L., Galanidis, A., Lambdon, P., Manca, M., Médail, F., Moragues, E., Traveset, A., Troumbis, A.Y., Hulme, P.E. 2006. Local and regional assessments 238 Islands and plants: preservation and understanding of lora on Mediterranean islands APPENDIX A - COMPLETE EPITHETS OF THE PLANTS QUOTED IN THE TEXT (see also tables 6-7) Acer campestre L. Ailanthus altissima (Mill.) Swingle Allium subvillosum Schult. & Schult. f. Ambrosia maritima L. Anagyris foetida L. Arbutus unedo L. Asphodelus ramosus L. Asphodelus tenuifolius Lam. Asplenium balearicum Shivas Bupleurum barceloi Willk. Charybdis maritima (L.) Speta Colymbada acaulis (L.) Holub Cynomorium coccineum L. Daucus rupestris Guss. Erica sicula Guss. subsp. sicula Erucastrum virgatum (C. Presl) C. Presl Euphorbia dendroides L. Euphorbia papillaris (Boiss.) Rafaelli & Ricceri Glaucium corniculatum (L.) J.H. Rudolph Globularia alypum L. Juniperus turbinata Guss. Limonium avei (De Not.) Brullo & Erben Loelingia hispanica L. Lycium intricatum Boiss. Matricaria aurea (Loel.) Sch.-Bip. Osmunda regalis L. Paraserianthes lophantha (Willd.) I.C. Nielsen Pennisetum setaceum (Forssk.) Chiov. Phyllitis sagittata (DC.) Guinea & Heywood Pinus halepensis Mill. Pseudoscabiosa saxatilis (Cav.) Devesa Quercus ilex L. Quercus suber L. Quercus virgiliana (Ten.) Ten. 239 he vascular lora of the satellite islands of Sicily Rhus pentaphylla (Jacq.) Desf. Silene bellidifolia Jacq. Silene turbinata Guss. Suaeda vermiculata J.F. Gmel. hymus richardii Pers. subsp. ebusitanus (Font-Quer) Jalas hymus richardii Pers. subsp. richardii 240 3: Eastern Mediterranean Islands and plants: preservation and understanding of lora on Mediterranean islands 241 Flora and phytogeography of the Ionian islands (Greece) 242 Islands and plants: preservation and understanding of lora on Mediterranean islands FLORA AND PHYTOGEOGRAPHY OF THE IONIAN ISLANDS (GREECE) Maria Panitsa and Eleni Iliadou Department of Environmental and Natural Resources Management, University of Ioannina. Seferi 2, GR-30100, Agrinio, Greece. Abstract he Ionian Islands are located in the Ionian Sea in western Greece. he major Ionian Islands are Corfu (Kerkira), Lekada, Ithaci, Cephalonia and Zacynthos, but there are also many smaller islands and islets. he size of each island ranges from 1.5 ha to 78,100 ha, while the maximum elevation ranges from 12 m to 1,628 m. In the phytogeographic region of the Ionian area, there is a National Park (Mount Aenos, Cephalonia), a National Marine Park (Zacynthos) and all, or in two cases part of, the twenty-one SCI and/or SPA Natura 2000 Sites covered by more than 20 diferent habitat types from Annex I. With regard to the Ionian Islands loristic composition, a database has been created using all available literature and the authors’ unpublished data, with a total number of about 2,500 plant species and subspecies, 3.2% of which are Greek endemics and 0.9% of which are endemic to the area or a single island. his low rate of endemism is possibly due to the palaeogeography of the Ionian area, which is quite simple, with most islands becoming isolated from the mainland during the Pleistocene or even more recently. he relationship between biogeographical factors and plant diversity is examined and discussed as well as b-diversity between islands and islets. We also focus on the presence of invasive species in the loristic composition of the islands and the conservation status, measures and strategies for the protected areas and the critical species. Keywords: Biodiversity, island lora, endangered species, single island endemics, island biogeography, alien species. Corresponding author: Maria Panitsa (mpanitsa@cc.uoi.gr) 243 Flora and phytogeography of the Ionian islands (Greece) INTRODUCTION Among the main characteristics of the Greek area, focal points are: the rich plant species diversity, the high rates of endemism and rarity as well as the huge number of islands and islets surrounding mainland and dispersed in the Aegean, the Cretan and the Ionian seas. Greek islands occupy 19% of the land area of Greece and they are mainly of continental origin (Strid & Tan, 1997). he geotectonic evolution of the Greek Islands has had a major contribution in shaping the biogeographic patterns of all recent taxa of these areas (Triantis & Mylonas, 2009). he Ionian Islands (IoI) are located in the Ionian Sea in western Greece (Fig. 1). he major Ionian Islands are Cephalonia, Corfu (Kerkyra), Lekas, Zacynthos and Ithaci (Table 1). he island of Cephalonia is the largest and has a greatest elevation (1628 m) (Table 1). here are also groups of small islands and islets like the Paxoi and Antipaxoi group (both islands surrounded by many islets), Diapontia islands group, Echinades islets group (more than 20 islets), Strofades group (the 2 small islands of Stamphani and Arpuia), (Table 1). In the phytogeographic region of the Ionian Islands, there is a National Park (GR2220002: Mount Aenos, Cephalonia), a National Marine Park (GR 2210002: Zacynthos), and all, or in two cases part of, the twenty-one SCI and/ or SPA Natura 2000 Sites covered by more than 20 diferent habitat types from Annex I (Table 2). It should also be mentioned that most of the Echinades islets are part of two overlapping Natura 2000 sites (GR 2310001, GR2310015), which are also included in the Ramsar Convention protected sites and have recently been deined as a National Park. Many loristic studies have been carried out on the Ionian Islands (Table 3). Tzanoudakis and Panitsa (1995) also refer to loristic information concerning Ionian Islands and islets. Tan & Iatrou (2001) mention a total number of 1,886 plant taxa while Georghiou & Delipetrou (2010) are providing quantitative data for the Greek endemic plant taxa of the Ionian phytogeographical area. he Red Data Book of Rare and hreatened Plants of Greece (Phitos et al., 1995, 2009) also includes critical taxa of the Ionian Islands lora. 244 Islands and plants: preservation and understanding of lora on Mediterranean islands Fig. 1. he phytogeographical regions of Greece (Strid & Tan, 1997). FLORISTIC ANALYSIS Species richness In the framework of our studies concerning plant species diversity and biogeography of the small islands and islets of the Ionian area (IoI), a database has been created using all available literature for 13 islands and the authors’ unpublished data for more than 20 islets of the Echinades islets group. Over 2,540 plant species and subspecies have been registered belonging to 132 families. Table 1 presents loristic data concerning islands and island groups. For this vascular lora, angiosperms predominate (97% of the total lora) and among them more than 30% belong to three dominant families, Leguminosae, Compositae and Gramineae. Nearly 50% of the plant taxa in the database present very low incidence and has been registered on one or two of the islands or islets while none have been found on all and only 3% of the total lora is found on more than half of the islands and islets. he most common species are: Pistacia lentiscus L., Euphorbia dendroides L., Lotus cytisoides L., Asparagus acutifolius L., Brachypodium retusum (Pers.) Beauv., Parapholis incurva (L.) C.E. Hubbard, Urginea maritima (L.) Baker, Smilax aspera L. and Valantia muralis L. 245 Flora and phytogeography of the Ionian islands (Greece) Island group Island/Islet S Cephalonia (Kf) Kerkyra (Kr) Zacynthos (Za) Leukada (Le) Ithaki (It) Kalamos (Ka) Vidos (Vi) 1597 1866 937 369 609 223 175 553 Paxoi - Antipaxoi Paxoi (Px) Antipaxoi (APx) Diapontia Islets 558 269 90 364 336 60 Othonoi (Ot) Erikousa (Er) Strofades Echinades (Ec) Stamfani (St) Arpuia (Ar) Oxeia (Ox) Makropoula Makri (Ma) Vromonas Modi Apasa Swros Gravaris Kalogeros Tsakalonisi Filippos Bistros Pontikos Labrino Sofia Provati Prasso Karlonisi Petalas Drakonera Total 377 A E 78100 59200 40600 32500 9600 2500 53.8 3410 3000 410 1770 1010 450 134.3 118 16.3 426 9.3 95.3 95 26.5 2.8 3.5 1.5 25.1 10 4.5 11.4 73.2 35.3 15 120.3 1.3 75 525 240 1796 1628 914 758 1158 806 724 33 230 230 103 393 393 137 22 22 12 421 20 126 130 66 17 31 24 34 25 30 41 62 61 43 75 12 77 238 121 Table 1. Floristic richness and values of the predictive variables used for each of the evaluated Ionian Islands. Abbreviations: S = all native plant richness (species and subsp.), A = area (ha), E = elevation (m). 246 Islands and plants: preservation and understanding of lora on Mediterranean islands Islands Sitecode Category Area (ha) Habitat type codes Za, Ar, St GR2210001 SCI-SPA 21419,24 1110, 1120*, 1170, 119A, 119B, 1240, GR2210002 SCI 6957,7 1410, 2110, 5210, 5330, 5420, 5430, GR2210003 SCI 523,13 7210*, 72A0, 9320, 9540 GR2210004 SPA 136,01 GR2220001 SCI 2566,19 1110, 1120*, 1170, 119A, 5420, 5330, GR2220002 SCI 2779,43 934A, 8140,8216, 951B GR2220003 SCI 88333,27 GR2220004 SCI 3736,16 GR2220005 SCI 18742,55 GR2220006 SPA 20715,15 Kr, Px, GR2230001 SCI-SPA 187,95 1120, 1150*, 1170, 119A, 119B, 1210, APx, Ot, Er GR2230002 SCI 2292,38 1240, 1310, 1410, 1420, 2110, 2210, GR2230003 SCI-SPA 242,97 2250, 5210, 5330, 5420, 6420, 7210, GR2230004 SCI 5649,66 72A0, 9290, 92A0, 92D0, 9320, 934A, 9540 Kf - It Le Ec (part of GR2230005 SCI 888 GR2230007 SPA 1050,98 GR2230008 SPA 10146,26 GR2240001 SCI-SPA 2143,4 1150, 1240, 1310, 1410, 1420, 2110, GR2240002 SCI 1255,59 6420, 72A0, 8210, 9320, 934A0, 9540, GR2310001 SCI 35509,89 1210, 1240, 1420, 5330, 5420 GR2310015 SPA 44185,62 Ramsar site) Table 2. Site codes, category, area covered and habitat type codes (Annex 1, Dir. 92/43/ EU) of the Natura 2000 sites of the Ionian phytogeographical area. Abbreviations as in Table 1. 247 Flora and phytogeography of the Ionian islands (Greece) Island/Islet Literature Greuter and Raus (2000, 2002, 2005, 2006), Artelari (1984), Artelari and Kamari (1986), Kamari (1991), Boratynski and Browicz (1996, 1997), Damboldt and Phitos Ionian Islands (1970), Gutermann (1995), Kamari and Phitos (2006), Bareka et al. (2006), Spanou et al. (2006), Karakitsos (2006), Iliadou and Panitsa (unpublished data), Ostermeyer (1887), Spreitzenhofer (1877), Theodoridis et al. (2006), Samuel et al. (2006) Cephalonia De Bolos et al. (1996), Phitos et al. (2003), Brullo and Tzanoudakis (1994), Phitos and Artelari (1981), Phitos and Damboldt (1985), Snogerup and Snogerup (2001) Georghiou (1988), Biondi (1989), Hansen (1982), Raus (1999), Borkowsky (1994), Kerkyra Ronniger (1941) Zacynthos Leukada Braüchler et al. (2008), Zieliński (1991), Gutermann and Ehrendorfer (2000), Brullo and Tzanoudakis (1994), Phitos and Strid (1994), Snogerup and Snogerup (2001), Strasser (2001), Trigou (2006), Hofmann (1968), Willing and Willing (1983) Ithaki Kalamos Vidos Paxoi - Antipaxoi Phitos et al. (2003), Brullo and Tzanoudakis (1994), Markantonatou et al. (2002) Baliousis and Yannitsaros (2010) Hansen (1982) Georgiadis (1986), Mamasis and Panitsa (unpublished data) Othonoi Georgiadis (1983) Erikousa Georgiadis (1985) Strofades Yannitsaros et al. (1995), Panitsa et al.(unpublished data) Oxeia Christodoulakis et al. (1988), Iliadou and Panitsa (unpublished data) Echinades islets Iliadou (2008), Iliadou and Panitsa (unpublished data) group (20 islets) Table 3. Plant species diversity contributions to Ionian Islands and islets (1981-2011). 248 Islands and plants: preservation and understanding of lora on Mediterranean islands Endemism Endemicity of plants was estimated at diferent levels, as described below. Single island endemics (ES) are species whose distribution range is limited to a single island. he category of Ionian endemics (IoE) includes endemics restricted to the Ionian phytogeographical region while Greek endemics include endemics of more than one phytogeographical region, as deined by Strid and Tan (1997), (Fig. 1). Following these levels of endemicity, 81 plant taxa of the Ionian Islands lora are Greek endemics (GrE), 13 are Ionian endemics (IoE) found on more than one of the Ionian Islands and 12 are single island endemics (ES). he island of Cephalonia shelters 5 single island endemic taxa, Zacynthos has 4 and each one of the islands of Kerkyra and Lekada hosts 1 single island endemic species. Ajuga orientalis L. subsp. aenesia (Heldr.) Phitos & Damboldt, Limonium cephalonicum Artelari, Saponaria aenesia Heldr. Viola cephalonica Bornm. and Poa cephalonica Scholtz. are endemics to Cephalonia island. Asperula naufraga Ehrend. & W. Gutermann, Limonium zacynthium Artelari, L. phitosianum Artelari and Micromeria browiczii Ziel. & Kit Tan are endemics to Zacynthos island. Narcissus corcyrensis (Herbert) Nyman is endemic to the island of Kerkyra and Arenaria leucadia to Leukada. Limonium antipaxorum Artelari has a restricted geographical distribution only to Paxoi and Antipaxoi islands like Centaurea paxorum Phitos & Georgiadis, which is also distributed mainly to Paxoi and Antipaxoi islands. Silene cephallenia Heldr. subsp. cephallenia, a rare chasmophyte, Limonium ithacense Artelari, a chasmophyte endemic of Cephalonia and Ithaci and other critical plant taxa of the Ionian Islands included in the Red Data Book of Rare and hreatened Plants of Greece (Phitos et al., 2009) are presented in Table 4. In addition, Krigas et al. (2010) mentioned that up to 7% of the 1,853 Natura 2000 Important Plant Species (IPS) recorded from Greece can be found in the Ionian Islands. he wild habitats of the IPS of the Ionian Islands may range from maritime limestone rocks to ir forests and subalpine rocky outcrops. 249 Flora and phytogeography of the Ionian islands (Greece) Distribution in Family Taxon Status the Ionian area Caryophyllaceae Silene cephallenia Heldr. subsp. Critically Endangered (CR) cephallenia Kf Violaceae Viola cephalonica Bornm. Critically Endangered (CR) Kf Caryophyllaceae Arenaria leucadia Phitos & Strid Endangered (EN) Le Caryophyllaceae Asperula naufraga Ehrend. & Guterm. Endangered (EN) Za Caryophyllaceae Saponaria aenesia Heldr. Endangered (EN) Kf Scutellaria rupestris Boiss. & Heldr. Labiatae subsp. cephalonica (Bornm.) Greuter & Endangered (EN) Kf Burdet Campanulaceae Campanula garcanica Ten. subsp. Vulnerable (VU) cephallenica (Feer) Hayek Compositae Centaurea paxorum Phitos & T. Vulnerable (VU) Georgiadis Za, Kf, It, Le Px, APx Compositae Centaurea pumilio L. Vulnerable (VU) Kf Ranunculaceae Consolida brevicornis (Vis.) Soó Vulnerable (VU) Kf, It, Le, Ks Coriariaceae Coriaria myrtifolia L. Vulnerable (VU) Kr Leguminosae Medicago muricoleptis Tineo Vulnerable (VU) Kr, Le, Za Labiatae Moluccella spinosa L. Vulnerable (VU) Le, It Kr, Px, APx, LE, Liliaceae Near Threatened (NT) Lilium candidum L. Paeoniaceae Kf Paeonia mascula (L.) Mill. subsp. russi (Biv.) Cullen & Heywood Near Threatened (NT) Le, Kf, Za Table 4. Ionian Islands endemics and plant taxa with wider distribution included in the Red Data Book of rare and threatened plants of Greece (Phitos et al., 2009). Abbreviations as in Table 1. Phytogeographical correlations Using as criterion the number of common endemic plant taxa between the phytogeographical area of the Ionian Islands (IoI) and the other phytogeographical areas (Fig. 1), it is concluded that IoI is closest to the other two phytogeographical regions with west-facing coastal areas, Peloponnisos (Pe) and Sterea Ellas (StE) as well as South Pindos (SPi), (Georghiou & 250 Islands and plants: preservation and understanding of lora on Mediterranean islands Delipetrou, 2010). According to these authors the IoI has 53 Greek endemic plant taxa in common with StE, 52 with Pe and 30 with SPi, while it has less than 17 Greek endemic plant taxa in common with the other phytogeographical areas of Greece. In addition, there are eight Greek endemic plant taxa with a geographical distribution restricted to IoI and Pe, 6 restricted to IoI and StE and 1 to IoI and SPi. he Preston’s dissimilarity coeicient between pairs of IoI with the other Greek loristic regions has its lower values when values for IoI are compared with StE (0.72), with Pe (0.74) and with SPi (0.77) and these values also conirm the closest phytogeographical correlations of the Ionian phytogeographical area (IoI) with its neighbouring ones StE, Pe and SPi (Fig. 1). he rather simple, compared to the complex palaeogeography and geological history of the Aegean area, geological evolution of the islands of the Ionian, with most islands becoming isolated from the mainland during the Pleistocene or even more recently (Triantis & Mylonas, 2009; Perissoratis & Conispoliatis, 2003), has played an important role in the evolution of loral richness on the islands and could be an explanation of the low rate of endemism in the area. Alien plant species It should be pointed out that 82 of the 150 most widespread alien plant species in Europe (Lambdton et al., 2008) are among the alien taxa registered. 66 of them are found on the island of Kerkyra, 55 on Cephalonia, 36 on Lekada, 24 on Zakynthos, 16 on Ithaki and Paxoi, 12 on Kalamos and 6 on Vidos, while on the small islands and islets there are no more than 3 of these alien taxa. On the other hand, 189 out of the 340 alien plant taxa of Greece (Arianoutsou et al., 2010) have been found, 146 of them on the island of Kerkyra, 112 on Cephalonia, 65 on Lekada, 64 on Zakynthos, 33 on Ithaki and on Paxoi, and 20 on Kalamos, while on the small islands and islets there are no more than 11 of these alien taxa. he most common alien species found on the Ionian Islands used in this study are present on half of the islands included in this study and belong to the families of Malvaceae, Asteraceae, Brassicaceae, Fabaceae and Valerianaceae and are: Malva sylvestris L., Conyza bonariensis (L.) Cronquist, Hirschfeldia incana (L.) Lagrze-Fossat, Chrysanthemum segetum L., Vicia villosa Roth, Rapistrum rugosum (L.) All. and Centranthus ruber (L.) DC. he number of native species is always a crucial point in island biogeography studies. here will always be uncertainties for islands with a long period of human habitation regarding whether species occurring have been introduced by man, and whether the activities of humans have led to the extinction of native species (Willerslev et al., 2002). 251 Flora and phytogeography of the Ionian islands (Greece) Predictors of species richness Independent variables examined as potential predictors of species diversity in the Ionian Islands were: island area (A, ha), maximum elevation (E, m), shortest distance from the nearest possible source and habitat diversity (H). Distance from the nearest source is the shortest distance from the nearest inhabited island (Di, km) or distance from the nearest mainland (Dm, km). As a measure of habitat diversity we used the number of diferent Corine land cover units recorded on the islands. Standard linear regressions, carried out with Statistica 6 (StatSot, Inc., 2001), were used for exploring the relationships of plant species richness (S) with A, E, Di, Dm and H. he best model is the log-log for overall native species richness and results of the simple linear regressions are given in Table 5. Species richness variance in the Ionian Islands is highly related to A (R2 = 0.847), H (R2 = 0.796) and E (R2 = 0.706). Distance from the nearest mainland (Dm) is not signiicantly related with species richness and Di is only slightly related. Kallimanis et al. (2010) also found for the Aegean area that distance from the mainland or other inhabited islands displayed limited predictive value. As Panitsa et al. (2010) remarked for the East Aegean area, where most of the islands have been recently isolated from the neighbouring mainland as is the case of the Ionian Islands, results for the Ionian area stress an important role of habitat diversity, of which elevation is another dimension, in shaping loral diversity patterns. Choros model (Triantis et al., 2003) that considers the combined efect of area (A) and habitat diversity (H) as a predictor of species richness (K) described slightly better species richness patterns (R2 = 0.877) than area alone and has had a higher predictive power than habitat diversity alone. Increased habitat diversity due to greater topographic and geological heterogeneity is promoting species richness, particularly when the species involved tend to be habitat specialists (Whittaker & Fernández-Palacios, 2007; Sfenthourakis & Triantis, 2009). 252 Islands and plants: preservation and understanding of lora on Mediterranean islands log S = 1.529 + 0.302 log A log S = 0.989 + 0.600 log E log S = 2.778 - 0.539 log Di log S = 2.024 + 0.205 log Dm log S = 1.908 + 0.842 log H log S = 1.521 + 0.230 log K R2=0.847* R2=0.706* R2=0.329** R2=0.067 ns R2=0.796* R2=0.877* Table 5. Results of simple regressions (the best it) for the dependent variable S with A, H, E, Di and Dm as independent variables. Area (A) and habitat diversity (H) as independent variables are also given so as to evaluate the performance of the Choros (K) model. E = elevation, Dm and Di = distances from the nearest mainland and island (km), respectively. (* = P<0.0001, ** = P < 0.001, ns=non signiicant). Floral similarities among Ionian Islands Analysis of the distributional pattern of the native plant species and of the relationship between the composition of the islands’ loras, based on their common plant taxa, was made by cluster analysis (Fig. 2). he preliminary analysis resulted in three distinct groups of islands / islets for the species data sets. According to analysis, the irst unit (1, in Fig. 2) includes the two largest islands, Cephalonia and Kerkyra, which also have a high elevation and present islands low similarity measures between themselves and other smaller islands and islets. he third unit (3, in Fig. 2) includes the islets of Echinades islet group, which show rather high similarity values in comparison with the other units, with the exception of Oxeia (Ox) and Makri (Ma) which are larger and are included in the second unit (2, in Fig. 2). 253 Flora and phytogeography of the Ionian islands (Greece) Fig. 2. Dendrogram of the cluster analysis of the distribution of plant taxa in the Ionian Islands. Abbreviations as in Table 1. Island similarities concerning all native species show a signiicant geographical component, relecting the spatial autocorrelation of loras before the fragmentation of the mainland or the efects of intensive post-fragmentation dispersal. he Ionian Islands are land-bridge islands and still behave as parts of a continuous land-mass, and for this reason the reduction of area has not yet led to a signiicant loss of species (Triantis et al., 2008). he high species turnover rates documented by Panitsa et al. (2008) for small islets in the same geographical region indicate a role for dispersal in shaping the geographically congruent pattern of native species. Concluding remarks he biota of the Ionian Islands is very similar to those of the adjacent mainland, although few endemic taxa can still be found, most of which live on the larger and more heterogeneous islands (such as Cephalonia). Additionally, the fauna and lora of the Ionian Islands are far more “harmonic,” without 254 Islands and plants: preservation and understanding of lora on Mediterranean islands profound gaps in their taxonomic composition (Triantis & Mylonas, 2009). Tzanoudakis and Panitsa (1995) mentioned the enormous amount of new and basic biological information to be gathered especially in the topics where ecology and taxonomy come together. It is well known that insular ecosystems are sensitive to human interference and any measures for their development should be taken ater the ecological and socio-economic parameters in the area are considered. In the Ionian area, there is very rich plant diversity (almost 40% of the plant taxa of the Greek lora are also found in the area) although not rich in endemic plant species. he ecological importance of the Ionian area is more pronounced if we consider the existence of a large number of areas under a protection status, the presence of 11 single island endemic taxa, and according to the IUCN criteria, of 2 critically endangered, 4 endangered and 7 vulnerable plant taxa (Tables 1 and 4), as well as more than 20 habitat types, which are included in Annex I of the Directive 92/43/EU, and this should be taken into consideration in any management plan related to area development. ACKNOWLEDGMENTS his research has been co-inanced by the European Union (European Social Fund – ESF) and Greek national funds through the Operational Program “Education and Lifelong Learning” of the National Strategic Reference Framework (NSRF) - Research Funding Program: Heracleitus II. 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Endemic plants of Greece, the Peloponnese. Copenhagen: Gads Publishers Ltd. Snogerup, S., Snogerup, B. 2001. Bupleurum L. (Umbelliferae) in Europe. 1. he annuals, B. sect. Bupleurum and sect. Aristata. Willdenowia, 31: 205-308. Triantis, K.A., Mylonas, M., 2009. Greek islands, biology. In: Gillespie, R., Glague, D.A. (Eds.), Encyclopedia of Islands. University of California Press, Berkeley. Spanou, S., Verroios, G., Dimitrellos, G., Tiniakou, A., Georgiadis, T. 2006. Notes on lora and vegetation of the sand dunes of western Greece. Willdenowia 36 (Special Issue): 235-246. Triantis, K.A., Mylonas, M., Lika, K., Vardinoyannis, K. 2003. A model for species-area-habitat relationship. Journal of Biogeography, 30:19-27. Spreitzenhofer, G. C. 1877. Beitrag zur Flora der jonischen Inseln: Corfu, Cephalonia und Ithaca. Verhandlungen der Zoologisch-Botanischen Gesellschat in Wien, 27: 711-734. Triantis, K.A., Vardinoyannis, K., Mylonas, M. 2008. Biogeography, land snails and incomplete datasets: the case of three island groups in the Aegean Sea. Journal of Natural History, 42: 467-490. StatSot Inc., 2001. STATISTICA (Data Analysis Sotware System), Version 6. http://www.statsot.com. Trigou, B. 2006. Signiicant biotopes and plants of the island of Lekada: proposals for the protection of the biotopes and the native lora (in greek). Ms thesis. University of Patras, Patras. Strasser, W. 2001. Zur Flora der griechischen Insel Lekas (Lekada). Steisburg. 259 Flora and phytogeography of the Ionian islands (Greece) Tzanoudakis, D., Panitsa, M. 1995. he lora of the Greek islands. Ecologia Mediterranea, 21(1/2): 195-212. und Akarnaniens sowie der Insel Lekas (NW-Griechenland). Mitteilungsblatt, Arbeitskreis heimische Orchideen BadenWürrttemberg, 15(3): 351-413. Whittaker, R.J., Fernández-Palacios, J.M., 2007. Island Biogeography. Ecology, Evolution and Conservation, second ed. Oxford University Press, Oxford. Yannitsaros, A., Vallianatou, I., Bazos, I., Constantinidis, h. 1995. Flora and vegetation of Strofades Islands (Ionian Sea, Greece). Hellenic Society for the Protection of Nature. Willerslev, E., Hansen, A.J., Klitgaard Nielsen, K., Adsersen, H., 2002. Number of endemic and native plant species in the Galapagos Archipelago in relation to geographical parameters. Ecography, 25:109-119. Zielinski, J. 1991. Scorpiurus vermiculatus (Fabaceae) rediscovered in Greece. Willdenowia, 20(1-2): 39-41. Willing, B., Willing, E. 1983. Beitrag zu Verbreitung der Orchideen Ätoliens 260 Islands and plants: preservation and understanding of lora on Mediterranean islands THE VASCULAR FLORA OF THE MALTESE ISLANDS Sandro Lanfranco1, Edwin Lanfranco2, Rowina Westermeier1, Mark-Anthony Zammit1, Marie-Antoinette Mifsud1 and Joelene Xiberras1 Department of Biology, University of Malta, Msida MSD2080, Malta. Institute of Earth Systems, University of Malta, Malta. 1 2 Abstract he lora of the Maltese Islands comprises approximately 1,100 indigenous, archaeophytic and naturalised alien species and approximately 700 casual alien species. he most represented families are the Poaceae, Asteraceae and the Fabaceae. Life forms are predominantly therophytes or hemicryptophytes whilst most indigenous perennials are characterised by adaptations characteristic of xerophytes. he proportion of endemics is relatively low (2%), compared to that of other Mediterranean islands, and this may be a consequence of the high human population density (>1,500 persons km-2). Most endemics have only been subject to taxonomic and distributional studies and knowledge of their ecology is lacking. Ongoing work suggests that one of the endemics, Helichrysum melitense, has very low rates of reproductive success. Keywords: Maltese Islands, lora, endemism INTRODUCTION Location, population and land cover he Maltese Archipelago consists of a group of small, low-lying islands located in the central Mediterranean, approximately 96 km south of Sicily and 320 km north of North Africa. he Archipelago extends for 45 km in a NW-SE direction and covers a total land area of 315.6 km2. he largest islands are Malta (length 27 km; area 245.7 km2) and Gozo (14.5 km; 67.1 km2). he other islands of the Archipelago are much smaller and comprise Comino (area 2.8 km2), St Paul’s Islands (10.1 ha), Cominotto (9.9 ha), Filla (2.0 ha) and General’s Rock (0.7 ha). he population of the Maltese Islands as of 2010 was approximately 418,000 persons (NSO, 2011), 92% of which lived in Malta and 8% in Gozo, Corresponding author: Sandro Lanfranco (sandrolanfranco@gmail.com) 261 he vascular lora of the Maltese Islands giving a population density of more than 1,500 persons km-2 on the main island. Much of the land surface on these highly populated islands is consequently either agricultural (51%) or urban (22%) and patches characterised by ‘natural vegetation’ are limited to 18% of the total islands area (MEPA, 2010). Climate he climate of the Maltese Islands is markedly biseasonal and alternates a dry season and a wet season, a characteristic pattern of the southern and central Mediterranean. he wet season, during which approximately 86% of total annual precipitation is recorded, lasts from October to March, whilst the dry season extends from April to September. he average annual rainfall is approximately 553.12 ± 156.99mm (Galdies, 2012). December is the wettest month (average c.102.48mm) and July the driest (average c.0.49mm). Much variation occurs from year to year, with some years being excessively wet and others excessively dry. Temperatures are generally stable from year to year (average 18.62 ± 0.40°C) (Galdies, 2012). August is the hottest month (average 26.3°C) and February the coldest (average 12.4°C). Continuous cloudy skies are very rare and extended periods of sunshine in winter tend to raise soil and air temperatures. Wind speeds greater than 1.8 km hr-1 are recorded on 92.3% of days in an average year. Geology and geomorphology he rocks of the Maltese Islands are all sedimentary and consist of a simple layer-cake series of marine sediments of Oligo-Miocene age overlain by sparse and sporadic terrestrial, luvial and lacustrine deposits of Quaternary age. Weathering, erosion and tectonic activity have caused a variety of geomorphological features including sheer coastal clifs, inland scarps, isolated plateaux, dry valleys, karst terrain and sandy beaches. With the exception of the terra rossa soils of karstic plateaux, the soils derived from these parent rocks are largely young and poorly-developed. VASCULAR FLORA he current lora of the Maltese Islands is a product of concurrent processes of immigration, establishment, isolation and local extinction. Processes contributing to immigration include long-range dispersal of propagules by wind and animal vectors across water, shorter-range dispersal across land bridges during glacial periods, and direct introduction by humans over the past 262 Islands and plants: preservation and understanding of lora on Mediterranean islands 6,000-7,000 years. Although currently isolated from surrounding land-masses, the Maltese Islands have been intermittently connected with southeastern Sicily through the Malta Plateau, a submerged feature that was exposed during the periods of lower sea levels that were characteristic of the past 1 million years (Micallef et al., 2012). No similar land bridge between the Maltese Islands and North Africa has been postulated. As such, over the past 1 million years, the Maltese Islands have been alternately connected to, and isolated from, the European mainland. It is assumed that rates of immigration of propagules increased during periods of lower sea level (‘connection’), and then decreased during period of higher sea level (‘isolation’). Inlux of European fauna, including megafauna, to the Maltese Islands is known to have occurred during marine regressions (Reyment, 1983) and such episodes may also have been accompanied by migration of plants over the land bridges that were exposed at the time. Subsequent isolation of the Maltese Islands during periods of marine transgression would have reduced genetic input from mainland populations, promoting diferentiation of immigrant mainland species into distinct local forms through genetic drit, hybridisation and adaptation to local conditions. Species, families and lifeforms he vascular lora of the Maltese Islands, which may be considered an appendage to that of the Hyblean region of Sicily, comprises approximately 1,100 species from 151 families, with ten families accounting for half the species recorded. he families with highest species representation are the Poaceae (12% of species), Asteraceae (10%) and Fabaceae (9%). Approximately 77% of the species are indigenous or archaeophytic whilst 23% are naturalised aliens. A further c.700 species that may be categorized as casual aliens have also been recorded. In terms of life-form representation (sensu Raunkiaer, 1934), approximately two-thirds of the species are therophytes or hemicryptophytes (44% and 22%, respectively) whilst 15% of species are phanerophytes. he relative predominance of therophytes and hemicryptophytes is a consequence of the constraints represented by the dry season in which an ‘avoidance’ strategy would be characterised by high itness. he principal loral communities of the Maltese Islands are generally considered as seral stages of a sclerophyll series characterised by steppe, shrub formations, maquis and scattered woodland. Complex communities dominated by ruderal species and characterised by considerable seasonal and inter-annual change are also widespread. Other plant communities are restricted to speciic habitats including temporary ponds, 263 he vascular lora of the Maltese Islands watercourses, saltmarshes, coastal dunes and clifs. Vegetation patterns during the earliest stages of human colonisation have been investigated in studies based on sedimentological and palynological evidence. he results of these studies suggest the presence of Pinus-Cupressaceae woodland that was subject to deforestation in the early Neolithic (Carrol et al., 2012) while work by Djamali et al. (2012) suggests the replacement of open steppe by dense Pistacia lentiscus scrub approximately 7000BP, an event that has also been recorded in sediments from Gela, in Southern Sicily (Di Rita & Magri, 2012). Endemic species Forty-three taxa are endemic to the Maltese Islands. Of these, 23 species are strictly endemic whilst a further twenty are sub-endemic and restricted to the Maltese Islands and circum-Italian islands. he Asteraceae contribute 26% of the endemic taxa (11 species) whilst the remaining 32 species represent 16 families including the Orchidaceae (5 species), Iridaceae (4 species) and Brassicaceae (3 species). Endemic taxa include palaeoendemics such as Cheirolophus crassifolius (Bertol.) Susanna, Cremnophyton lanfrancoi Brullo & Pavone and Darniella melitensis (Botsch.) Brullo and neoendemics such as Limonium melitense Brullo, L. zeraphae Brullo, Anthemis urvilleana (D.C.) Sommier & Carauana-Gatto, Helichrysum melitense (Pignatti) Brullo et al. and Matthiola incana subsp. melitensis Brullo, Lanfranco, Pavone & Ronsisvalle. Two hydrophytes, Elatine gussonei (Sommier) Brullo et al. and Zannichellia melitensis Brullo, Giusso del Galdo & Lanfranco, are also endemic or sub-endemic to the islands. he number of endemic species, representing approximately 2% of indigenous/archaeophytic species, is relatively low compared to other Mediterranean islands and may be attributable to early and intense habitat degradation through anthropogenic inluence. It should also be emphasized that most Maltese endemic plants are colonists of relatively inaccessible rupestrian habitats, areas that are generally insulated from much of the efect of anthropogenic disturbance. Most studies on the endemic lora have been either distributional or taxonomic, with very few ecological studies, which are essential for the design of efective conservation strategies. Ongoing work on Helichrysum melitense, a critically-endangered endemic plant (Montmollin & Strahm, 2005) restricted to the western coast of Gozo (Sciberras & Sciberras, 2009) indicates that levels of reproductive success are very low (Xiberras & Lanfranco, in prep.), with 264 Islands and plants: preservation and understanding of lora on Mediterranean islands obvious implications for conservation and restoration strategies involving this species. Similar studies are planned for other endemic species. Chorological characteristics of some endemic species he biogeographic relationships of the lora on the Maltese Islands are varied and complex. Principal contributors to this complexity may include diferential survival of species in refugia during glacial periods, post-glacial dispersal from these glacial refugia and dispersal of propagules by wind and by animal vectors. he chorological characteristics of a number of endemic species may be used to infer the biogeographic complexity of the lora of the Maltese Islands. Cremnophyton lanfrancoi: A palaeoendemic species that seems to be most closely related to Atriplex cana C.A. von Meyer, native to the semi-deserts of central Asia (Kadereit et al., 2010). Palaeocyanus crassifolius (Bertol.) Dostal: A palaeoendemic species most closely related to the genus Cheirolophus of the western Mediterranean area and Macaronesia (Susanna, 1999), in which it is now oten included. Darniella melitensis: A palaeoendemic species. he genus Darniella (oten included in Salsola) is distributed throughout much of North Africa as well as Israel. he Maltese Islands are the only European station (Brullo, 1984). Jasonia bocconei (Brullo) Pardo & Morales: A species that is probably schizoendemic. he genus Jasonia (including Chiliadenus) is distributed discontinuously throughout North Africa, the Middle East (Israel, Sinai), the western Mediterranean coasts (Spain, southern France) as well as the Maltese Islands and the Pelagian Islands (Brullo, 1979). Allium lojaconoi Brullo, Lanfranco & Pavone: A schizoendemic species. One of a group of schizoendemics and an apoendemic species occurring in the Maltese, Aegadian and Pelagian Islands in the central Mediterranean (Brullo & Pavone, 1983). Hyoseris frutescens Brullo & Pavone: A species that is probably palaeoendemic. he genus Hyoseris, as narrowly deined, occurs throughout the Mediterranean area, including the Maltese Islands. Two species, Hyoseris radiata L. and H. scabra L. are widespread throughout the Mediterranean. Two other species, H. taurina (Pamp.) Martinoli and H. lucida L., have a more circumscribed distribution, the former being endemic to southern Sardinia and northern Sicily, while the latter is native to eastern North Africa (Brullo & Pavone, 1988). H. frutescens is endemic to the Maltese Islands, being quite frequent in rupestrian and coastal habitats in Gozo but very rare on the island 265 he vascular lora of the Maltese Islands of Malta. It is probably most closely related to H. taurina which, apart from its geographical proximity is the only other species of Hyoseris to show a tendency towards a shrubby form, though not to the extent of H. frutescens. Limonium zeraphae and L. melitense: hese species are schizoendemic. he genus Limonium is widespread with numerous species occurring in coastal habitats throughout the Mediterranean area. Many of these are microspecies that are found only in very restricted geographical areas. he two Maltese endemic species are most probably derived from L. virgatum Maire & Petitm., which seems to be widespread throughout the Mediterranean area. Probable hybrids between L. virgatum and L. zeraphae have been observed where these species coexist (Lanfranco, 1989). Helichrysum melitense: his species is schizoendemic and closely related to H. rupestre, an Italian species (Pignatti, 1980; Lanfranco, 1989). Euphorbia melitensis Parl.: his species is schizoendemic and closely related to E. bivonae Steudel of northwest Sicily and E. papillaris (Boissier) Rafaelli & Ricceri. hese three species are somewhat related to E. spinosa L., which is found in peninsular Italy (Rafaelli & Ricceri, 1988; Lanfranco, 1989). Anacamptis urvilleana Sommier & Caruana-Gatto: A species that is probably schizoendemic, perhaps palaeoendemic. Clearly closely related to A. pyramidalis (L.) Richards, which is widespread throughout the Mediterranean region including Malta. Although closely related, A. pyramidalis and A. urvilleana in Malta are reproductively isolated such that no hybridisation occurs. Moreover, whilst A. urvilleana is diploid (like most of the continental populations of A. pyramidalis) with 2n = 36, the Maltese population of A. pyramidalis is tetraploid with 2n = 72 (Del Prete et al., 1984, 1991; Lanfranco, 1989) and may merit taxonomic recognition as suggested by Sommier & Caruana Gatto (1915). REFERENCES con Allium parcilorum Viv. Webbia, 35(2): 295-306. Brullo, S. 1979. Taxonomic and nomenclatural notes on the genera Jasonia Cass. and Chiliadenus Cass. (Compositae). Webbia, 34(1): 289-308. Brullo, S., Pavone, P. 1983. Allium francinae, specie nuovad dell’ Isola di Marettimo (Arcipelago delle Egadi). Webbia, 37(1): 13-22. Brullo, S. 1984. Taxonomic consideration on the genus Darniella (Chenopodiaceae). Webbia, 38: 301-328. Brullo, S., Pavone, P. 1988. 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Molecular phylogeny of Atripliceae (Chenopodioideae, Cheopodiaceae): Implications for systematic, biogeography, lower and fruit evolution, and the origin of C4 photosynthesis. American Journal of Botany, 97(10): 1664-1687. Raunkiaer, C. 1934. he life forms of plants and statistical plant geography. Oxford: Clarendon. Reyment, R. A. 1983. Palaeontological aspects of island biogeography: 267 he vascular lora of the Maltese Islands colonization and evolution of mammals on Mediterranean islands. Oikos, 299-306. Susanna, A., Garnatje, T., Garcia-Jaca, N. 1999. Molecular phylogeny of Cheirolophus (Asteraceae: Cardueae – Centaurinae) based on ITS sequences of nuclear ribosomal DNA. Plant Systematics and Evolution, 214(1-4): 147-160. Sciberras, J., Sciberras, A. 2009. Notes on the distribution of Helichrysum melitense, Hyoseris frutescens and Matthiola incana subsp. melitensis in the Maltese Islands. he Central Mediterranean Naturalist, 5(1):28-34. Xiberras, J., Lanfranco, S. In preparation. Reproductive efort in Helichrysum melitense. Sommier, S., Caruana Gatto, A. 1915. Flora Melitensis Nova. Firenze: Stab. Pellas. 268 4. Islets Islands and plants: preservation and understanding of lora on Mediterranean islands 269 he vascular lora of the Maltese Islands 270 Islands and plants: preservation and understanding of lora on Mediterranean islands FLORA OF HABIBAS ISLANDS (N-W ALGERIA): RICHNESS, PERSISTENCE AND TAXONOMY Errol Véla1 In collaboration with Arne Saatkamp2 and Daniel Pavon3 Université Montpellier-2, U.M.R. AMAP (Botanique et Bioinformatique de l’Architecture des Plantes), TA A51/PS2, 34398 Montpellier cedex 5, France. 2 Université Paul Cézanne Aix-Marseille-3, U.M.R. IMEP (Institut Méditerranéen d’Ecologie et de Paléoécologie), Faculté des Sciences de St Jérôme, Av. Escadrille Normandie-Niemen, Boite 462, F 13397 Marseille cedex 20, France. 3 Université Paul Cézanne Aix-Marseille-3, U.M.R. IMEP (Institut Méditerranéen d’Ecologie et de Paléoécologie), Bâtiment Villemin, Europole de l’Arbois - BP 80, 13545 Aix-en-Provence cedex 04, France. 1 Abstract Within the Alboran Sea, along the NW-Algerian coasts, the Habibas Archipelago belongs to the Betico-Rifean hotspot and was probably a good refuge during glacial ages and subsequently during the Holocene period. Since Maire, Wilczek and Faure in 1934, loristic investigations have been very poor. More than 100 vascular plant taxa are known on the main island, from which 5 species (Spergularia pycnorrhiza, Brassica spinescens, Anthemis chrysantha, Rostraria balansae, Fumaria munbyi) are endemic from Algerian, MoroccanAlgerian or Spanish-Algerian coasts, and 2 varieties (Sonchus tenerrimus var. amicus, Asteriscus maritimus var. sericeus) were described from the archipelago as narrow endemic. Since 2006, several expeditions organized by “PIM Initiative” (initiative for the Small Islands of the Mediterranean) allowed us to conirm the presence of the main taxa and particularly the endemic ones. About 80% of the initial lora is still observed 72 years later, and the new taxa are essentially belonging to spontaneous Mediterranean lora. Nevertheless, 3 potentially invasive xenophytes on the islands are listed and need to be surveyed in the future. A succinct biogeographical analysis is made in comparison with other north-western African archipelagos. he recent classiication as Protected Marine Area should allow good conservation of natural habitats and their endemic and spontaneous lora (in a good conservation status) although ield surveys and deeper taxonomic investigations would be very useful. Corresponding author: Errol Véla (errol.vela@cirad.fr) 271 Flora of Habibas Islands (N-W Algeria): richness, persistence and taxonomy INTRODUCTION he Habibas archipelago is a small archipelago located at 10 km NW from the Algerian coast (Cap Blanc) between the cities of Oran and Beni-Saf (wilaya of Ain-Temouchent). It is circumscribed by the Alboran Sea, which represents the south-western part of the Mediterranean Sea. his marine area was expanded during the late Oligocene and early Miocene (Gueguen et al. 1998) while Rifean and Betican micro-plates were driving towards the west until they collapsed respectively into the African and Iberian plates causing an elevation of mountain chains or collision (Rif and Sierra Nevada). During the Miocene microplate migration, magmatic activity associated to back-arc basin formation consequently to rollback subduction (Rosenbaum & Lister 2004) kept us until today magmatic outcrops (e.g. Cabo de Gata, Alboran, Habibas, Rechgoun, etc.). hus, more than 90% of the outcrops of the archipelago consist of volcanic rocks (Maire & Wilczek, 1936). During Quaternary glaciations, low bathymetry (< 100 m) makes us think that the archipelago was at times connected to the African continent. he Habibas Archipelago, recently classiied as an “important plant area” (Yahi et al., 2012), belongs to the Betico-Rifean hotspot (Médail & Quézel, 1997), as they can be included in the Oran coastal hills sector “O1” (Quézel & Santa, 1962). While larger islands and the peninsula are known as glacial refugia in the Mediterranean basin (Médail & Diadéma, 2009), small islands, “which contain relict populations not involved in post-glacial migrations” (Médail & Diadéma, 2009) are oten micro-refugia favourable to long-term persistence phenomenon. Until the present day, some of them, due to their inaccessibility and inhospitality during Holocene and Historical times, are naturally protected against strong human impact relatively to the continental coasts. Habibas Islands were seldom visited by botanists until the 1990’s. In 1875, Pomel described precisely Brassica spinescens from Habibas islands, without saying if he had visited the place or if he did it from reported specimens. He does not mention the Brassica scopulorum Coss. & Dur., a nomen nudum irst mentioned by Balansa [Pl. Alg. n° 657 (1852)] from Cap Falcon, but validly described only in 1882 by Cosson himself [Illustr. FI. Atlant. p. 28, tab. 20 (1882)] and also considered as taxonomical synonym of B. spinescens. Ater Pomel had given his herbarium to Battandier, Foucaud named it unoicially Spergularia pycnorrhiza another plant from Oran, but it is Battandier (1910) who irst published the name. his plant remained unknown in the ield until the historical expedition of Maire, Wilczek and Faure in 1934 (cf. Maire & Wilckzek, 1936) when they discovered the same plant in abundance on Habibas islands. 272 Islands and plants: preservation and understanding of lora on Mediterranean islands It was then that Maire, Wilczek and Faure irst visited the island on the 4th and 5th of May 1934 with the aim of carrying out a strong botanical exploration. hey published “Florule des Îles Habibas (Maire & Wilczek, 1936), where they listed 103 vascular plant species (+ 18 cultivated by inhabitants) and several non vascular cryptogamous taxa (5 fungi, 7 lichens, 29 marine algae and 1 bryophyte new to science Tortula muralis subsp. mairei Meylan). With regard to vascular lora, they have seen ive narrow endemic species previously known on the continent (Anthemis chrysantha J. Gay, Brassica spinescens Pomel, Fumaria munbyi Boiss. & Reut., Rostraria balansae (Cosson & Durieu) J. Holub, Spergularia pycnorrhiza Foucaud ex Batt.), and have described three new endemic varieties from the Habibas island (Asteriscus maritimus var. sericeus Maire & Wilczek; Sagina ciliata var. obtusisepala Faure, Maire & Wilczeck; Sonchus tenerrimus var. amicus Faure, Maire & Wilczek) without regarding several minor forms, subvarieties or varieties only based on lower coloration (Maire, 1935). During the 1990’s, Algerian ornithologists have discovered Asplenium marinum L., a rare fern in Algeria, new to the archipelago’s lora (Boukhalfa 1993). Established in 2000, the Algerian ministry of Planning and of Environment (Ministère de l’Aménagement du Territoire et de l’Environnement, MATE) started cooperation with the French conservatory of coastal areas and lake shores (Conservatoire de l’Espace Littoral et des Rivages Lacustres, CELRL). he PIM initiative (initiative pour les Petites Iles de la Méditerranée, initiative for the small islands of the Mediterranean) was initiated by CELRL in 2006 and one of its goals is to encourage prospection with the aim of knowing better the rare and peculiar lora of these small and neglected territories. he objectives of this irst expedition were: 1) to compare current lora with lora at Maire’s period, 2) to highlight taxonomical position of endemic and/or neglected taxa, 3) to analyse biogeographical ainities of the Archipelago. MATERIAL AND METHODS With approximately 40 hectares of emerged land area, the archipelago is the largest in Algeria and consists of two main islands, a large south-western one (around 30 ha, 105 m high) and a small north-eastern one (around 10 ha, 24 m high), with a remarkable islet in an intermediate position (around 1 ha, 30m high!) and many other insigniicant islets in peripheral position. he intermediate islet is inaccessible but ofers little vegetation, while other islets consist essentially of maritime rocks. 273 Flora of Habibas Islands (N-W Algeria): richness, persistence and taxonomy he team working with Maire et al. (1936) in spring 1934 consists of three botanists studying also non vascular terrestrial and maritime plants during two consecutive half-days (4th May aternoon and 5th May morning) only on the larger island. he PIM team in 2006 consists of one botanist (E.V.) studying only terrestrial plants (including lichens) during one day and a half (1st May aternoon and 2nd May all day (long) only on the larger island. Complementary data, including the smaller island, were collected by two botanists (E.V., A.S.) in October 2007 during another expedition inanced by Algerian MATE, via a private contract. Another expedition made by J. Delauge, during spring 2007, was essentially focused on mapping vegetation and several speciic taxa (cf. Delauge & Véla, 2007). he two data sets are compiled in one table with the old (Maire, 19521987) and the modern (Dobignard & Chatelain, 2010-2013) taxonomical referential, and critical point of view will be developed on several endemic and/or neglected taxa. Relative species changes (expressed in % yr–1) between the two data sets have been calculated using Morrison’s formula (1997, 1998): Sr=[(I+E)/t(S1+S2)]x100. E and I are the number of species extinctions and species colonisations, respectively, occurring between two surveys separated by t years. S1 and S2 are the number of species on each island in the irst and second census (cf. Vidal et al., 2000). In our case, only the larger islands are considered with t=72 years. So we can provide a quick overview of the biogeographical links with other archipelagos and with coastal areas from the south-western Mediterranean. he invasion potential by xenophytes on the archipelago will be introduced. RESULTS Persistence of lora We have compiled the two species lists using the synonymic referent of “African Plant Database” for North Africa (Dobignard & Chatelain, 20102013), which can be searched online at <http://www.ville-ge.ch/musinfo/bd/ cjb/africa/index.php>. he number of spontaneous taxa found in 1934 (Maire & Wilczek, 1936) were 103 species or subspecies. In addition, 18 species were cultivated by inhabitants, mainly for food uses. he number of spontaneous taxa found in 2006-2007 (present work) is 97 species or subspecies, of which 81 are in common with the previous inventory, and 16 new ones for the island. In addition, 3 taxa are cultivated and more or 274 Islands and plants: preservation and understanding of lora on Mediterranean islands less naturalised. Two of them were originally introduced before 1934, and one is recently cultivated for ornamental uses. During the main phase of inventory (May 2006), only 83 spontaneous taxa have been found: 71 are in common with the irst date set from 1934 and 12 are new. Two additional cultivated / naturalised taxa, previously known in 1934, have been found. During the complementary inventory (October 2007), 10 previously known species have been rediscovered and 4 additional new taxa have been found. Furthermore, one new cultivated taxon has been found. he calculation of the turnover is made with only spontaneous taxa from the two data sets, separated by a period of 72 years: Sr = [(16+22)/72(103+97)]x100 = 0,264 % yr –1 Endemism and biogeography With regard to the previously known 9 endemic taxa of the Alboran area in 1934, all of them have been easily seen in 2006 and in 2007 (Table 1). It seems to be a tenth taxon, temporarily named “Lobularia maritima subsp. columbretensis?”. Half of them are chamephytic perennial sub-shrubs with stress-tolerant (S) demographical strategy and another half are therophytic annual herbs with mixed stress-tolerant and ruderal (SR) demographical strategy. 275 Flora of Habibas Islands (N-W Algeria): richness, persistence and taxonomy Table 1. List of the endemic taxa from Alboran area found on Habibas Archipelago (spring 2006 / autumn 2007) and Rechgoun island (spring 2006: Véla, unpubl. data) and their biological type and demographical strategy. Taxa endemic from Alboran Sea: Biological form* Grime** Habibas Rechgoun Anthemis chrysantha J. Gay SR CC R Th/Ch (annual/biennial) Brassica spinescens Pomel Ch S AC ∅ Fumaria munbyi Boiss. & Reut. Th R R R Rostraria balansae (Cosson & Th SR AC ∅ S AC ∅ Th SR R ∅ Ch S AC ∅ Th SR R ∅ Th/Ch (biennial) S AC R Ch S R ? (to be Durieu) J. Holub Spergularia pycnorrhiza Foucaud Ch ex Batt. Arenaria cerastioides Poir. var. oranensis (Batt.) Maire Asteriscus maritimus (L.) Less. var. sericeus Maire & Wilczek Silene pseudoatocion Desf. var. oranensis Batt. Sonchus tenerrimus L. var. amicus Faure, Maire & Wilczek Additional possible endemic taxa: Lobularia maritima (L.) Desv. subsp. columbretensis R. Fern. ? confirmed) * cf. Raunkiaer 1934. ** cf. Grime 1977, sensu Véla 2002. Between the two data sets (1934-2006), 22 taxa could be considered locally extinct (Table 2). Most of the extinct taxa are Mediterranean therophytic annuals with ruderal strategy or mixed stress-tolerant + ruderal strategy. 276 Islands and plants: preservation and understanding of lora on Mediterranean islands Table 2. List of the 22 extinct taxa on the Habibas Archipelago between 1934 and 2006 and their biogeography, biological type and demographical strategy. *Following Carazo & Fernandez 2006, Fennane & Ibn Tattou 2005, modif. ** cf. Raunkiaer 1934. *** cf. Grime 1977, sensu Véla 2002. 277 Flora of Habibas Islands (N-W Algeria): richness, persistence and taxonomy Between the two data sets (1934-2006), 16 taxa could be considered recently established (Table 3). More than a half are still Mediterranean s.l., but several paleotemperate or subcosmopolite synanthropic taxa and two xenophytes can be found. Table 3. List of the 16 recently established taxa on the Habibas Archipelago between 1934 and 2006 and their biogeography, biological type and demographical strategy. *Following Carazo & Fernandez 2006, Fennane & Ibn Tattou 2005, modif. ** cf. Raunkiaer 1934. *** cf. Grime 1977, sensu Véla 2002. 278 Islands and plants: preservation and understanding of lora on Mediterranean islands With regard to the 18 originally cultivated species (mainly for traditional food uses), 16 have completely disappeared and only 2 (Carpobrotus cf. acinaciformis, Ficus carica) still exist today as more or less naturalised xenophytes. Only one new cultivated species (Opuntia microdasys (Lehm.) Pfeif. var. microdasys), with risk of naturalisation, has been identiied. DISCUSSION Species turn-over and persistence he relative species change that is measured here (turn-over < 0.3 %) is very low compared to those observed in the French archipelago near Marseille, where gull overpopulation and other synanthropic perturbations have induced a turn-over between 0.47 and 1.19 (Vidal et al., 2000). Turn-over value decreases around the land areas of the island, and we can notice that in the same area (around 30 ha), Maire island has got species turn-over > 0.8 %. A very low species turn-over conirms the global consideration about a good conservation status of natural habitats seen on the island during the 2006-2007 expeditions. More than 80% of native species seen in 1934 are still present 72 year later, which demonstrates very good persistence capacities of indigenous communities, where even seabirds’ populations have been increasing for several years. If the extinct taxa are mainly Mediterranean annuals from dry ooligotrophic grasslands (SR therophytes), this natural phenomenon is partially compensated by several colonisations from the same functional group. Nevertheless, some of the newly established taxa are subcosmopolitan and/or xenophytic perennials, indicating a beginning of pattern change. Species such as Oxalis pes-caprae which has recently colonised the archipelago must be surveyed and some ornamental species such as Carpobrotus cf. acinaciformis and Opuntia microdasys (Lehm.) Pfeif. var. microdasys should be eradicated before their deinitive establishment on the island. Endemism and taxonomical controversies We have highlighted 10 poorly known endemic taxa. None of them are previously known as endemic around the southern Alboran area (AlgerianMoroccan coasts), ive at species level and four at variety level: Spergularia pycnorrhiza is a narrow endemic species from Habibas and Ain Franin in Algeria (Oran). Its ainities are not known, but it shows morphological convergences with S. macrorrhiza (Loisel.) Heynh., a corsosardinian endemism. S. pycnorrhiza difers by its large oval pink petals and obtuse sepals, but share with S. macrorrhiza a very peculiar woody root, fat 279 Flora of Habibas Islands (N-W Algeria): richness, persistence and taxonomy leaves and fruits with large not winged seeds. Brassica spinescens is a narrow endemic species from Habibas, Cap Falcon and Djebel Santon in Algeria (Oran). It seems to be a paleoendemism with possible ainities with B. balearica Pers. from Mallorca (Spain). Its small habitus (15-20 cm high), with highly branched woody stems and very fat and small leaves give it a very diferent appearance from other spontaneous Brassica taxa from B. fruticulosa agregate or B. oleracea agregate. Rostraria balansae is an endemic species from the southern Alboran Sea in north-western Algeria (Kristel, Canastel, Cap Falcon and Habibas) while old mentions from Melilla could be confused with R. festucoides (= Avellinia michelii) following Romero Zarco (2002). It shows some morphological and ecological ainities with the Mediterranean R. littorea aggregate (= Koeleria pubescens aggr.), but its phylogenetical ainities are not known. Fumaria munbyi is a species found around a fragmented area, mainly from the southern Alboran Sea (Habibas, Rechgoun and Oran coast) and from the Columbretes islands in eastern-Spain. Old mentions from NE Morocco are not conirmed. It shows morphological and ecological ainities with other southwestern Mediterranean species such as F. mellilaica from NE Morroco and SE Spain, but its phylogeny is not known. Anthemis chrysantha is an endemic species from both the Alboran coast in SE Spain and NW Algeria (Sánchez Gómez et al., 2004). Spanish populations were described as subsp. jimenezii (Pau) Sánchez Gómez, M. A. Carrión & A. Hernández, while the Algerian ones correspond to subsp. chrysantha. It belongs to the section Anthemis, but seems to be a paleoendemic without direct ainities. Asteriscus maritimus var. sericeus is known as endemic taxa from Habibas Archipelago and again Cap Falcon (but not seen here since its description). It remains strongly misunderstood and shows ainities and/or convergence forms with some populations from Santa Cruz’s clifs near Oran and coastal forms from Rechgoun Island (NW Algeria) or from Cap de Garde, near Annaba (NE Algeria), but none of them are identical (Fig. 1). We think that a subspecies rank will be a good taxonomical hypothesis to reconsider this very peculiar plant from the Habibas Archipelago: Asteriscus maritimus (L.) Less. subsp. sericeus (Maire & Wilczek) Véla, comb. et stat. nov. Basionym: Asteriscus maritimus (L.) Less. var. sericeus Maire & Wilczek in Maire, Bull. Soc. Hist. Nat. Afr. Nord 26: 211 (1935). “A var. mauritanico Jord. difert foliis dense et longe sericeovillosis plus minusve 280 Islands and plants: preservation and understanding of lora on Mediterranean islands incanis; lorum radii tubo parcissime pilosulo, glabrescente. Hab. in rupibus maritimis ad occidentem urbis Oran (Cap Falcon ; Iles Habibas), aprili et maio lorens.» (Maire, 1935) Sonchus tenerrimus var. amicus is known as endemic taxa from the Habibas Archipelago but it grows on Rechgoun island too (E. Véla, obs. pers.). It is strongly diferent from other forms of S. tenerrimus s.s. from coastal areas along Oran and hills, but shows morphological convergences with the S. pustulatus / masgindalii agregate from N-Morocco (Fig. 2). It probably corresponds to S. briquetianus Gand. (in Bull. Soc. Bot. France 55: 657 [1909]) from Chafarinas Archipelago and could be considered as subspecies rank like the halophytic taxa S. asper subsp. glaucescens (Jord.) Boulos, for example: Sonchus tenerrimus L. subsp. amicus (Faure, Maire & Wilczek) Véla, comb. et stat. nov. Basionym: Sonchus tenerrimus L. var. amicus Faure, Maire & Wilczek in Maire, Bull. Soc. Hist. Nat. Afr. Nord 26: 217 (1935). “Foliis crassiusculis eximie pectinatis, lacinia terminali aliis minore et habitu ad ssp. pustulatum (Willk.) Batt. vergit, sed ab ilio radice annua l. vix bienni (nec perenni sufrutescente) discedit. Rami inlorescentiae parce glandulosi ; anthodium glabrum ; pedunculi sub anthodio lanati. Hab. in rupibus vulcanicis insulae Habiba majoris, aprili et maio lorens.” (Maire, 1935) Silene pseudoatocion var. oranensis is described from Oran and grows along southern Alboran coasts from Oran to Beni-Snassen in NE Morocco. Following Maire (1963), it difers morphologically and ecologically from var. pseudoatocion (“var. genuina”), but the criteria announced are partially unstable on the ield. Furthermore, Iberian and Balearic populations described in “Flora iberica” (Talavera 1990) and their relationships with var. oranensis are poorly known and remain unclear. Arenaria cerastioides var. oranensis, recombined ater its original description as A. spathulata var. oranensis Batt., B. Soc. Bot. France, 45, p. 238 (1898) is considered as an endemic species on the Oran coastal area, but like other species varieties, it remains currently poorly known and its morphological, ecological and biogeographical properties should be studied. he taxon number ten must be highlighted here. Population of Lobularia maritima from the Habibas Archipelago (only on the main island) ofers strong morphological and ecological ainities with subsp. columbretensis R. Fern, in Anales Jard. Bot. Madrid 49: 314 (1992) recently described in the Columbretes Archipelago in E Spain and previously known as strictly narrow endemic species. Its woody erect stem, bigger leaves and bigger lowers than 281 Flora of Habibas Islands (N-W Algeria): richness, persistence and taxonomy from subsp. maritima (Fig. 3), shows strong similarities with the description of subsp. columbretensis on the Columbetes Islands around 500 km far away: “Planta claramente sufruticosa, con tallo robusto, erecto, muy ramiicado; ramas ± gruesas, muy foliosas; hojas mayores, de hasta 60 × 8 mm; pétalos 3,5-4,5 × 3 mm; semillas c. 2 mm. (...) Suelo volcánico, muy nitriicado. IV-X.” (Fernandes, 1993) Biogeographical ainities As we can see considering endemic taxa detailed above, biogeographical links are strong between Moroccan and Spanish coastal areas of the Alboran Sea, as well as the Chafarinas Islands. But biogeographical links are particularly pronounced among the small islands of the Columbretes Archipelago, around 500 km north-east, which share the same volcanic soils, semi-arid climate and high populations of seabirds. South-western and western Mediterranean taxa on fragmented coastal areas are abundant, like Succowia balearica (L.) Medik or the “small islands specialist” Stachys brachyclada De Noé. his biogeography strongly difers from the other main northern African archipelagos located in Tunisia. La Galite Archipelago in NW Tunisia shows strong ainities with Corso-Sardinian and other peri-Tyrrhenian shared taxa like Brassica insularis Moris or Limonium intricatum Brullo & Erben from the L. articulatum agregate (Pavon & Véla, 2011). Zembra Archipelago in NE Tunisia shows strong ainities with Sicilian and other Central Mediterranean shared taxa like Dianthus rupicola Biv subsp. hermaeensis (Coss.) O. Bolos & Vigo or Iberis semperlorens L. (cf. Labbe, 1954). CONCLUSION With ten endemic taxa, and half of them at speciic level, the Habibas Archipelago is one of the best key biodiversity areas of plants in northern Algeria (cf. Yahi et al., 2012) in such a small territory. Its recent classiication as Protected Marine Area should allow conservation of natural habitats and their endemic and spontaneous lora in good conditions. Scientiic surveys and assessments will be needed to reach this goal. Furthermore, obviously it is necessary to contract ield investigations and moreover to deeply re-initiate taxonomical investigations on north-African lora and its close relationships with the lora on the European side of the Mediterranean. 282 Islands and plants: preservation and understanding of lora on Mediterranean islands REFERENCES Battandier, J.A. 1910. Flore de l’Algérie. Supplément aux phanérogames. Paris, Alger. Fennane, M., Ibn Tattou, M., 2005. Flore vasculaire du Maroc: inventaire et chorologie. Volume 1. Pteridophyta, Gymnospermae, Angiospermae. Institut Scientiique, Université Mohammed V, Agdal, Rabat. Boukhalfa, D. 1993. La végétation des Iles Habibas (Oran) et la première observation d’une espèce de ptéridophyte. Le Monde des Plantes, 447: 23-24. Fernandes, R.B. 1993. Lobularia Desv. In: Castroviejo, S. (eds). Flora ibérica (vol. 4). CSIC, Madrid, p. 196-200. Carazo-Montijano, M. M., FernándezLópez, C. 2006. Catálogo de las plantas vasculares de Andalucía y Marruecos. Herbario Jaén, ISBN : 84-931296-4-X. Grime, J.P. 1979. Plant strategies and vegetation processes. John Wiley, Chichester. Delauge, J., Véla, E. 2007. Etude de la végétation des Îles Habibas. In : Ben Hadj & Bernard (eds). Réserve des Iles Habibas, Notes naturalistes, Petites îles de Méditerranée, 2004/2007. Conserv. Espace Litt. Riv. Lac. : 50-70. On line at : http://www.initiative-pim.org/images/ documents/NN-ALGERIE-HabibasPIM04-07-InitiativePIM-R-serve-des-IlesHabibas-notes-naturalistes.pdf Gueguen, E., Doglioni, C., Fernandez, M. 1998. On the post-25 Ma geodynamic evolution of the western Mediterranean. Tectonophysics, 298: 259-269. Dobignard, A., Chatelain, C. 2010-2013. Index synonymique de la lore d’Afrique du Nord. Vol. 1: Pteridophyta, Gymnospermae, Monocotyledoneae (2010); Vol. 2: Dicotyledoneae, Acanthaceae - Asteraceae (2011); Vol. 3: Dicotyledoneae, Balsaminaceae - Euphorbiaceae (2011); Vol. 4: Dicotyledoneae, Fabaceae - Nymphaeaceae (2012); Vol. 5: Dicotyledoneae, Oleaceae - Zygophyllaceae (2013). Ed. C.J.B.G., Genève. Maire, R. 1935. Contributions à l’étude de la lore de l’Afrique du Nord. Fascicule 23. Bulletin de la Société d’Histoire Naturelle de l’Afrique du Nord, 26: 184-234. Labbe, A. 1954. Contribution à la connaissance de la lore phanérogamique de la Tunisie, 4 : Additions à la lore de l’île de Zembra. Mémoires de la Société des Sciences Naturelles de Tunisie, 2: 3-12. Maire, R. 1952-1987. Flore de l’Afrique du Nord (Maroc, Algérie, Tunisie, Tripolitaine, Cyrénaïque, Sahara). Lechevalier, Paris, Vol I à XVI. Maire, R., Wilczek, E. 1936. Florule des Iles 283 Flora of Habibas Islands (N-W Algeria): richness, persistence and taxonomy Habibas. Bulletin de la Société d’Histoire Naturelle de l’Afrique du Nord, 26 bis: 6177. Rosenbaum, G., Lister, G.S., 2004. Formation of arcuate orogenic belts in the western Mediterranean region. Geological Society of America, Special Paper 383: 4156. Médail, F., Quézel, P. 1997. Hot-spots analysis for conservation of plant biodiversity in the Mediterranean basin. Annals of Missouri Botanical Garden, 84: 112-127. Morrison, L.W. 1997. he insular biogeography of small Bahamian cays. Journal of Ecology, 85: 441-454. Sánchez Gómez, P., Carrión Vilches, M.A. & Hernández González, A. 2004. Anthemis chrysantha J. Gay. In: Bañares et al. (eds). Atlas y Libro Rojo de la Flora Vascular Amenazada de España. Dirección General de Conservación de la Naturaleza, Madrid: 96-97. Morrison, L.W. 1998. he spatiotemporal dynamics of insular ant metapopulations. Ecology, 79: 1335-1146. Talavera, S. 1990. Arenaria L. In: Castroviejo, S. (eds). Flora ibérica (vol. 2). CSIC, Madrid, p. 172-224. Pavon, D., Véla, E. 2011. Espèces nouvelles pour la Tunisie observées sur les petites iles de la côte septentrionale (archipels de la Galite et de Zembra, ilots de Bizerte). Flora Mediterranea, 21: 273-286. Véla, E., 2002. Biodiversité des milieux ouverts en région méditerranéenne : le cas de la végétation des pelouses sèches du Lubéron (Provence calcaire). hèse doct., Univ. Aix-Marseille-3. Quézel, P. & Santa, S. 1962-1963. Nouvelle lore de l’Algérie et des régions désertiques méridionales. Ed. CNRS, Paris (2 vol.). Vidal, E., Médail, F., Tatoni, T., Bonnet, V. 2000. Seabirds drive plant species turnover on small Mediterranean islands at the expense of native taxa. Oecologia, 122: 427434. Raunkiaer, C. 1934. he life-forms of plants and statistical plant geography. Clarendon Press, Oxford. Yahi, N., Véla, E., Benhouhou, S., De Bélair, G., Gharzouli, R. 2012. Identifying Important Plants Areas (Key Biodiversity Areas for Plants) in northern Algeria. Journal of hreatened Taxa, 4: 2753-2765. Romero Zarco, C. 2002. Rostraria Trin. In: Valdes et al. (eds). Catalogue des plantes vasculaires du nord du Maroc incluant des clés d’identiication. CSIC, Madrid : 823824. 284 Islands and plants: preservation and understanding of lora on Mediterranean islands Fig. 1. Asteriscus maritimus subsp. sericeus (Habibas island, E. Véla, 1&2.V.2006) 285 Flora of Habibas Islands (N-W Algeria): richness, persistence and taxonomy Fig. 2. Sonchus tenerrimus subsp. amicus (Habibas island, E. Véla, 1&2.V.2006) 286 Islands and plants: preservation and understanding of lora on Mediterranean islands Fig. 3. Lobularia maritima subsp. columbretensis (Habibas island, E. Véla, 21.X.2007) 287 Flora of Habibas Islands (N-W Algeria): richness, persistence and taxonomy 288 Islands and plants: preservation and understanding of lora on Mediterranean islands FLORA OF THE HYèRES ISLANDS HIGHLIGHTS: ORIGINALITY AND THREATS Henri Michaud Conservatoire Botanique National Méditerranéen, 34 avenue Gambetta, 83400 – Hyères, France. h.michaud@cbnmed.fr Abstract he Hyères Islands, located in south-eastern France, consist of 3 small islands, the largest of 1,254 ha. Since the Middle Ages, medicinal herbs from the Archipelago have been largely used. From the 19th century up to now, the knowledge of the lora steadily increased. Today, 1,068 taxa are known on the whole Archipelago. he most remarkable species are Tyrrhenian elements, insular plants and species in northern limit of their range, all of them absent or exceptional on the nearby mainland. his lora is mainly threatened by excessive frequentation, natural maturation of the ecosystems and invasive plants. Keywords: Tyrrhenian lora, insular plants, excessive frequentation, invasive plants. INTRODUCTION TO THE HYèRES ISLANDS he Hyères Islands are located in the south-east of France. hey constitute the old Stoechades Archipelago which consists of three main islands and some rocky islets, namely, from West to East, Porquerolles, Port-Cros and Le Levant (Fig. 1). Some physical characteristics of the islands are shown in Table 1. he geologic substratum is made up of gneisses, phyllites and mica schists. Porquerolles and Port-Cros are crossed by the forty third parallel of northern latitude. he climate is mild and less rainy than on the mainland. For example, in Porquerolles, the annual rainfall average is 575 mm reaching its peak in autumn; the annual temperature average is 15.3°C, the monthly average peaks in the hottest month (M) is 26.8°C and the average of the monthly lowest temperature of the coldest month (m) is 6.1°C. With regard to Hyères, the values are 651 mm, 14,7°C, 27,3°C and 3,8°C (Aboucaya, 1989), respectively. he Port-Cros Island has been a National Park since 1963. Its coverage also extends to the neighbouring island of Porquerolles, managing 1,000 ha of natural habitats, placed under its responsibility by the Ministry of Environment. Le Levant Island is mainly (80%) under military rule. 289 Flora of the Hyères Islands highlights: originality and threats Fig. 1. Location of the Hyères islands Table 1. Somme physical characteristics of the Hyères islands KNOWLEDGE EVOLUTION ON FLORA he knowledge about the Hyères Islands lora started in the Middle Ages when medicinal herbs from the Archipelago enjoyed a large reputation. Apothecaries from Montpellier used to come to stock up there (Jahandiez, 1929). During the 17th century, the irst Floras of Provence (Garidel, 1715; Gérard, 1761) quote some of the rare species from the Hyères Islands, for example Gérard indicates Teucrium massiliense L. as rarissima planta in Insulis Stoechadum (Jahandiez, 1913). At the beginning of the next century, 48 species were mentioned by Lauvergne (1829) and Robert (1838), 9 of them 290 Islands and plants: preservation and understanding of lora on Mediterranean islands being part of the remarkable species of the Archipelago (Alkanna lutea Moris, Asplenium marinum L., Crepis leontodontoides All., Delphinium pictum Willd., Genista linifolia L., Ptilostemon casabonae (L.) Greuter, Teucrium marum L., T. massiliense, hymelaea tartonraira (L.) All.). he irst synthesis was made by Ollivier, who published in 1885 the irst comprehensive catalogue about lora on Porquerolles Island, where 538 species were listed in a synthesis ater 50 years of plants collection. 45 years later, thanks to the researches by Jahandiez (1929), the irst lists with a common purpose for the three islands were published. In 1989, Aboucaya made a new synthesis on the lora’s knowledge on the Archipelago based mainly on the work of Jahandiez, and completed with the data of the most recent literature. In order to illustrate these changes, Fig. 2 highlights the situation for Porquerolles. he most recent publication was issued two years ago (Crouzet, 2009). hrough a well documented bibliographic analysis backed up by a comprehensive ield survey, this work provides a more accurate statement on the Archipelago’s lora. he deep modiication driven by ecological, agricultural, and economical changes which occurred during the last century is taken into account in this paper. Crouzet considers that in 2009, 704 taxa are currently present; 237 ones that are mentioned in the literature are not conirmed recently, 36 are doubtful and 52, extinct. he same work has not been done for the other islands and only the total amount of taxa observed for each island is known (Port-Cros, 594; Levant, 642; the entire archipelago, 1,068; data from http://lore.silene.eu). In the last decade notable indings were made on the three islands, especially regarding plant groups poorly sampled because of their special phenology or taxonomic status. Examples of such discoveries are Asplenium balearicum Shivas, Romulea lorentii Moret, R. assumptionis Garcias Font, Verbena supina L., Fumaria bicolor Sommier ex Nicotra, F. labellata Gasp. or Silene badaroi Breistr. (Médail, 1998 ; Moret et al., 2000; Médail & Loisel, 2001; d’Onofrio et al., 2003; Crouzet et al., 2005). Although some species have disappeared since the irst known inventories were made, none of the most original species of the lora of the Archipelago (Table 2): Tyrrhenian elements (e.g. Delphinium pictum), insular plants (e.g. Fumaria bicolor, Orobanche sanguinea C. Presl), and plants around the northern limit of their range (e.g. Spergularia diandra (Guss.) Boiss., Genista linifolia), have been impacted. It should be noticed that the two endemic species described on the Hyères Islands have a controversial status. Delphinium requieni DC. is now considered to be simply a minor variant of D. pictum (Léotard, 2002), and Romulea lorentii is very close to R. requienii Parl. particularly of its var. parvilora Bég. 291 Flora of the Hyères Islands highlights: originality and threats Table 2. Distribution of patrimonial plants through the Hyères Islands. Tyrrh.: Tyrrhenian element, Ins.: insular plants 292 Islands and plants: preservation and understanding of lora on Mediterranean islands Fig. 2. Evolution of the total number of species on the Porquerolles Island according to main inventories. MAIN THREATS AND CONSERVATION ACTIONS PERFORMED NOWADAYS he tourist success of the Hyères Island entails an excess of human pressure during the tourist periods: 1 million visitors each year to Porquerolles, 220,000 to Port-Cros (http://www.portcrosparcnational.fr). he main impact is sufered on coastal ecosystems and the National Park is involved in a constant recovering of these habitats by fencing and replanting local plants, and by limiting the number of tracks and paths in order to control people’s crossing. In contrast, a low level of disturbance on other areas of the Islands induces the development of preforest and forest units where Quercus ilex predominates. Médail et al. (1995) and Médail & Loisel (1999) have proposed a model for a spatial-temporal dynamic management of heliophylous or mesosciaphylous species based on a metapopulation concept. Local disturbances by clearing patches favour the proliferation of plants like Delphinium pictum or Genista linifolia; hence plant communities could develop naturally reconstituting the organic matter and the soil seed bank. his kind of dynamic management also limits the parasite populations. For very local plants (e.g. Leucojum pulchellum Salisb.) new populations have been created. 293 Flora of the Hyères Islands highlights: originality and threats Invasion by exotic plants represents also a threat to the local lora. On the coastline, Carpobrotus edulis (L.) N.E. Br. and C. aine acinaciformis (L.) L. Bol. are very present and dynamic, producing fertile fruits (Suehs et al. 2003 ; 2004). he irst mention of their presence (in Porquerolles) is made by Hanry (1886). he National Park has eradicated the Carpobrotus spp. on an islet (Îlot du Petit Langoustier) by an action over 14 years with an annual follow-up. Another invasive plant is Cortaderia selloana (Schult. & Schult. F.) Asch. & Graebn., particularly on Le Levant Island where the plant is dynamic in temporary streams. Each year, an eradication day is organised, and some local volunteers on the Island take part. Locally, Acacias spp. (mainly A. dealbata Link and A. retinodes Schltr.) are invasive; the proliferation control of the Acacias is diicult because these plants are highly popular in gardens. Opuntia spp. are also dynamic on rocky coastal slopes. here, preliminary identiication has been done (Crouzet, 2009) and the most dynamic and problematic species is Opuntia stricta (Haworth) Haworth which spreads through seedlings and cuttings. AN APPROACH TO THE FUTURE Even if the lora seems to be well known today on the Archipelago, the eforts to follow up and improve this knowledge of the lora have to be maintained. New groups of rare or endangered plants may be still discovered, and due to human activity, new exotic species will certainly settle in the future. he management of the whole Archipelago is planned for the future in the management plan performed for the Natura 2000 site “La côte d’Hyères et son archipel”, which integrates the presence of remarkable species of the Islands as well as their main threats. REFERENCES Aboucaya A. 1989. La lore des îles d’Hyères: Etude des rapports phytogéographiques et biosystématiques avec les Maures et la Corse. hèse Université Aix-Marseille III. Crouzet N., D’Onofrio P., Blanc G., Aboucaya A., Michaud H., Noble V. 2005. Nouvelles contributions à la lore des îles d’Hyères. Scientiic Reports of Port-Cros national Park, Fr 21: 117-146. Crouzet N. 2009. La lore vasculaire de Porquerolles et de ses îlots : mise à jour critique des inventaires. (Hyères, Var, France). Scientiic Reports of Port-Cros national Park, Fr 23: 47-87. d’Onofrio P., Léotard G., Crouzet N., Aboucaya A., Michaud H. 2003. Contributions à la connaissance de la lore des îles d’Hyères. Scientiic Reports of PortCros national Park, Fr. 19: 41-62. 294 Islands and plants: preservation and understanding of lora on Mediterranean islands recherche, Université Montpellier II. Garidel P.-J. 1715. Histoire des plantes qui naissent aux environs d’Aix et dans plusieurs autres endroits de Provence. J. David , Aix. Médail F. 1998. Flore et végétation des îles satellite (Bagaud, Gabinière, Rascas) du Parc National de Port-Cros (Var, S.E. France). Travaux Scientiiques du Parc national de Port-Cros, 17: 55-80. Gerard L. 1761. Flora gallo-Provincialis. Bauche. Paris. Hanry H. 1886. Herborisations en Provence: V. Les îles d’Hyères in: Verlot, B. Le guide du botaniste herborisant. J.-B. Baillière et ils, Paris, p. 464-465. Médail F., Loisel R. 1999. Conservation des espèces végétales et gestion dynamique des habitats dans un espace protégé de Méditerranée, le Parc National de PortCros et l’île de Porquerolles (Var, S.-E. France) Bulletin de la Société Botanique du Centre-Ouest, 19: 235-250. Jahandiez E. 1913. Notice sur les plantes rares des îles d’Hyères. Annales de la Société d’histoire naturelle de Toulon, 4: 85-91. Médail F., Loisel R. 2001. Contribution à la connaissance de la lore des îles d’Hyères (Var, S.E. France). Travaux Scientiiques du Parc national de Port-Cros, 18: 107-115. Jahandiez E. 1929. Les îles d’Hyères. Monographie des îles d’Or. Presqu’île de Giens, Porquerolles, Port-Cros, île du Levant. Histoire, Description, Géologie, Flore, Faune. Rebufa, Rouard, Toulon (3ème édition) (Réimpression 1977, Laitte Reprints). Médail F., Loisel R., Rolando C. 1995. Eléments pour une gestion dynamique des populations de quatre végétaux protégés des îles d’Hyères (Var, France). Travaux Scientiiques du Parc national de Port-Cros, 16: 19-54. Lauvergne H. 1829. Géographie botanique du port de Toulon et des îles d’Hyères. Tribut académique présenté et publiquement soutenu à la faculté de médecine de Montpellier le 17 juillet 1829 pour obtenir le grade de docteur en médecine. Moret J., Guern M., Baudoin R., Baudière A. 2000. Etude phénétique du genre Romulea (Iridaceae) en France. Le Monde des Plantes, 468: 24-30. Léotard G. 2002. Etude morphologique de deux Dauphinelles de Méditerannée occidentale : Delphinium pictum Willd. Delphinium requienii DC. (Ranunculaceae). Le statut spéciique de D. requienii estil justiié ? Mémoire d’initiation à la Ollivier L. (Abbé) 1885. Catalogue de la lore de l’île de Porquerolles. Plantes vasculaires. Société d’Horticulture et de Botanique de Marseille, J. Cayer, Marseille. 295 Flora of the Hyères Islands highlights: originality and threats Robert G. N. 1838. Plantes phanérogames qui croissent naturellement aux environs de Toulon. Perreymond-Dufort, Brignoles. Suehs C. M., Afre L., Médail F. 2004. Dynamique d’invasion de deux végétaux introduits dans le basin méditerranéen, Carpobrotus spp. (Aizoaceae) sur l’île de Bagaud. Scientiic Reports of Port-Cros national Park, FR 20: 19-46. Suehs C. M., Médail F., Afre L. 2003. Invasion by South African Carpobrotus (Aizoaceae) taxa in the Mediterranean Basin: the efects of islands on plant reproductive systems. In: Child L. E., Brock J. H., Brundu G., Prach K., Pyšek P., Wade P. M. Williamson M. (eds). Plant Invasions: Ecological hreats and Management Solutions. p. 247-263. http://www.portcrosparcnational.fr consulted on 03/29/2011 http://lore.silene.eu consulted on 03/29/2011 296 Islands and plants: preservation and understanding of lora on Mediterranean islands FROM FIRE TO NATURE: EVOLUTION, RESTORATION AND CONSERVATION OF THE COLUMBRETES ISLANDS FLORA Carlos Fabregat1 and Emilio Laguna2 Jardí Botànic de la Universitat de València. Quart, 80. E-46008 Valencia, Spain. CIEF (Centro para la Investigación y Experimentación Forestal). Servicio de Vida Silvestre de la Generalitat Valenciana. Avda. Comarques del País Valencià, 114. E-46930 Valencia, Spain. 1 2 Abstract his paper deals with plant richness and singularity of the Columbretes Islands (Valencian Community, E Spain), a small volcanic archipelago 56 km of the southeast coast of Spain. hese islands are home to the entire wild population of the exclusive endemic plant Lobularia maritima subsp. columbretensis, as well as the Iberian-balearic endemic moon trefoil Medicago citrina. hey also hold the unique Spanish populations of Reseda hookeri and Fumaria munbyi, and a majority of Lavatera mauritanica. Since 1987, the Wildlife Service of the Generalitat Valenciana has been developing actions to restore the ancient vegetation, saving from extinction several climacic and preclimacic taxa (Withania frutescens, Lycium intricatum, etc.). he successful re-introduction of M. citrina on the main island –Illa Grossa– was achieved, and several conservation actions for the main threatened taxa are being carried out. Keywords: Columbretes Islands, Mediterranean lora, endemics, plant microreserve, plant conservation, re-introduction. A BRIEF APPROACH TO THE COLUMBRETES ARCHIPELAGO he Columbretes Islands, a volcanic archipelago 56 km of the coast of Castellón, in southeastern Spain, with a surface of nearly 19 Ha, consists of 30 small islands and rock formations distributed in four groups. he largest islets are known as Illa Grossa (13.33 Ha, 67 m, Fig. 1), Ferrera (1.53 Ha, 43 m), Foradada (1.63 Ha, 55 m) and Carallot. Only the irst three islets are large enough to harbour vascular plant species. Corresponding author: Emilio Laguna (laguna_emi@gva.es) 297 From ire to nature: evolution, restoration and conservation of the Columbretes Islands lora he Columbretes Islands originated from volcanic materials (basalts, trachyandesites) with pH ranging from 6.6 to 7.7, as a basic characteristic. Due to sea inluence and the presence of numerous seabirds, most of the soils are more or less saline and rich in soluble nitrogenated substances. he climate can be described in general terms as warm Mediterranean with mild winters and severe aridity, especially in summer (Bolòs, 1992). he average annual temperature ranges between 16.4 and 16.8 ºC. Rainfall data gives an average annual precipitation of 265 mm, spread over 23 days per year (Gisbert, 1987). he archipelago is noteworthy for the uniqueness of some species of its lora and for some of its vegetation types. Moreover, it is an important site for seabirds and also a signiicant recreational resource. Activities such as spearishing and scuba diving are strictly regulated. Guided visits to the largest island are also allowed, although the number of visits per day is limited. Moreover, the Illa Grossa bay is used by several recreational yachts for mooring. he name of the archipelago comes from early sailors, Greek and Latin, which included it in their charts with the name of Ophiusa or Colubraria, amazed by the abundance of snakes they found. Many ishermen, smugglers and pirates visited the islands until the late nineteenth century. he colonization of the archipelago occurred in the mid-nineteenth century following the lighthouse construction on Illa Grossa between 1856 and 1860. he arrival of the lighthousekeepers represented a dramatic change in an extremely wild environment. he vegetation of the main island was burnt to eliminate the presence of snakes. Domestic animals (such as rabbits, pigs or goats) were introduced and most of the shrubs were removed to obtain irewood. Subsequent soil erosion by rainfall following deforestation, completed a process of severe degradation of vegetation cover in the archipelago, especially noticeable on Illa Grossa, whose present development clearly difers from the historic original references published by Smyth (1831). Lighthouse-keepers inhabited the island continuously for more than a century, in precarious conditions, as evidenced by the intensive use of all resources ofered by the poor terrestrial environment and extraordinarily rich marine resources. he small colony of settlers let the island in 1975, when the lighthouse was automated. Since then, the islands had been uninhabited until the Natural Park was declared and the irst surveillance service was created. he Columbretes Islands –emerged portion– were declared Natural Park in 1988. he marine environment of the Columbretes archipelago was declared Marine Reserve in order to preserve its outstanding richness in 1991. Currently, a 298 Islands and plants: preservation and understanding of lora on Mediterranean islands team of four wardens remains on the main island carrying out surveillance, maintenance and conservation tasks. Fig.1. Illa Grossa, the main island of Columbretes archipelago (Photo: C. Fabregat) COLUMBRETES FLORA AND VEGETATION Historical approach he irst references to the lora of Columbretes correspond with the impression of an English sailor (Smyth, 1831) who visited the islands before the lighthouse construction. He described the vegetation of the ridges that rise up on both ends of Illa Grossa stating: “hese hills are covered with an exuberance of dwarf olives, geraniums, prickly pears, myrtles and brushwood”. Years later, Archduke Ludwig von Salvator of Austria arrived at the island and his vision clearly relected the great change that had occurred since human colonization: “he Columbretes (...) do not even have trees and shrubs. (...) Only Suaeda fruticosa covers the main island as a green scrub” (Salvator, 1895). he irst modern study on the lora of the archipelago was conducted by Manuel Calduch. He explored the islands between 1947 and 1965, obtaining a list of 107 species. Unfortunately, his observations were not published until many years later, ater Calduch’s death. Boira and Carretero (1987) published 299 From ire to nature: evolution, restoration and conservation of the Columbretes Islands lora the irst lora of Columbretes, which comprised a catalogue of 100 species. hey also published the irst vegetation study where 9 communities were described (Carretero & Boira, 1987). Subsequently, Bolòs (1989) completed the study of vegetation, extending the typology to 12 communities, and updated and published the Calduch’s list (Bolòs, 1992), increasing the lora of the islands to 114 species. Subsequent studies (Laguna & Jiménez, 1995; Fabregat & LópezUdias, 1997; Juan & Crespo, 1999, 2001) have completed and clariied the loristic catalogue and vegetation typology in the archipelago. Current status and main features In 2005, the Environmental Department of the Generalitat Valenciana -GV, regional government of the Valencian Community- started a project to monitor the lora and vegetation of the archipelago in order to ascertain its evolution and current status in the Columbretes Islands Nature Reserve. During the project development, existing references of the lora of Columbretes were reviewed, some new taxa were found and a loristic catalogue of 120 native or naturalized taxa was established. Ater ive years of monitoring, only 87 species from the previous list have been conirmed (Fabregat et al., 2009). he main reason is that irst studies of the lora were made when the main island was still inhabited by lighthouse-keepers, who established and maintained crops for food, and the archipelago did not enjoy protection. Crop loss, and progressive decline of human activity since the islands were protected could be the cause of the disappearance of several weeds or ruderal species such as Papaver rhoeas L., Asperula arvensis L., Galium verrucosum Hudson among others. In other cases, heavy storms which sprayed sea water over the islets have been responsible for the disappearance of other species such as Smilax aspera L. he phytogeographic spectrum of the Columbretes’ lora (Fig. 2) is dominated by Mediterranean taxa (65%) followed by pluriregional taxa (28%), with a minor percentage (7%) of exotic taxa introduced by man (Mestre et al., 2008). he high proportion of Austromediterranean elements stands out from the Mediterranean taxa, some of which represent outstanding disjunctions (e.g. Fumaria munbyi Boiss. & Reuter, Lavatera mauritanica Durieu). Characteristic plants of xeric climates of the arid Iberian SE such as Withania frutescens (L.) Pauquy, Lycium intricatum Boiss. or Triplachne nitens (Guss.) Lam. are also noteworthy. Life forms spectrum (Bolòs, 1989) is shown in Fig. 3, and is characterized by the dominance of therophytes and the absence of geophytes. he most common species are Suaeda vera Forsskal ex J.F. Gmelin, Lobularia maritima (L.) Desv. subsp. columbretensis R. Fern., Lavatera mauritanica, L. 300 Islands and plants: preservation and understanding of lora on Mediterranean islands arborea L., Chenopodium murale L., Erodium chium (L.) Willd., Brachypodium distachyon (L.) Beauv., Sonchus tenerrimus L., Medicago littoralis Rohde ex Loisel. and Mesembryanthemum nodilorum L. he vegetation of the archipelago is dominated by halo-nitrophilous communities, being the shrubby seablite scrub (Lavatero mauritanicaeSuaedetum verae O. Bolòs, Folch et Vigo in O. Bolòs 1989) the most widespread formation. In addition, some other associations are noteworthy for their singularity, such as Medicagini citrinae-Lavateretum arboreae O. Bolòs, Folch et Vigo in O. Bolòs et Vigo 1984 (ornithocoprophilous tall shrub dominated by tree mallows in addition to the arborescent moon trefoil) and Euphorbio terracinae-Lobularietum columbretensis Carretero et Boira 1987 corr. Carretero et Aguilella 1995 (prairies with tall grasses interspersed with Lobularia maritima subsp. columbretensis). Woody vegetation was almost completely destroyed, although some scarce palmettos (Chamaerops humilis L.) and lentiscs (Pistacia lentiscus L.) still remain on Ferrera islet, as a relict of the coastal maquis [Querco cocciferae-Pistacietum lentisci (Br.-Bl. et al. 1935) A. et O. Bolòs 1950] that could have covered the better soils on the islands. A complete list of plant communities of the Columbretes archipelago can be found in Table 1. Fig. 2. Phytogeographic spectrum of the Columbretes’ lora 301 From ire to nature: evolution, restoration and conservation of the Columbretes Islands lora Fig. 3. Life forms spectrum of the Columbretes’ lora Endemic, rare or threatened plant species he most important vascular plant species are Lobularia maritima subsp. columbretensis, an endemic restricted to the archipelago, and Medicago citrina (Font Quer) Greuter (Fig. 4), endemic to the archipelago and some islets surrounding the island of Ibiza and the NE Alicante coast (Serra et al., 2001). Moreover, interesting plants such as the rare Fumaria munbyi, Reseda hookeri Guss. –both are the unique Spanish populations– and Lavatera mauritanica can also be found, as previously stated. hese ive plants are protected by the Valencian Community laws. RESTORATION AND CONSERVATION OF THE COLUMBRETES ISLANDS FLORA he emerged land of Columbretes belong to the city of Castellón de la Plana, and are fully managed by the GV. In 1987, the Spanish Parliament empowered the Valencian Community to protect and manage the emerged part of the archipelago. In January 1988, the GV protected the islands as a Natural Park. hey were reclassiied as Nature Reserve in 1994. In addition to its plant treasures, Columbretes holds the best Valencian colonies of endangered 302 Islands and plants: preservation and understanding of lora on Mediterranean islands seabirds, as well as a dozen endemic species of invertebrates and an endemic lizard. In 1991, the Spanish Ministry of Agriculture protected 4400 Ha of ofshore waters and seabeds surrounding the archipelago. Furthermore, Ferrera and Foradada islets were the irst two protected Plant Micro-Reserve (PMR) islands legally designated by the Valencian administration in 1998, according to the model explained by Laguna (2001). Both PMRs are devoted to ensure monitoring and active conservation projects of the main rare, endangered or endemic plant species, particularly Reseda hookeri and Medicago citrina. Fig. 4. he endemic moon trefoil (Medicago citrina) on the Foradada islet. Ferrera islet can be seen in the background (Photo: C. Fabregat). he main actions to conserve the lora and to restore the vegetation of Columbretes Islands have been described by Laguna and Jiménez (1995), and updated by Jiménez (1998). he irst main activity, carried out during summer 1987, was the eradication of rabbits (Oryctolagus cunniculus, introduced in the late 19th century) on main island -Illa Grossa- avoiding the use of irearms, in order to prevent damages to the outstanding colonies of protected seabirds. Traps and bow and arrow were used to hunt 213 rabbits. Quick vegetation recovery was noticed, and several rare species (e.g. Lobularia maritima subsp. 303 From ire to nature: evolution, restoration and conservation of the Columbretes Islands lora columbretensis, Lavatera arborea, L. mauritanica) became dominant in the landscape of Illa Grossa within 1-2 years. All the individuals of the climacic shrubs Withania frutescens and Lycium intricatum -only 4 old plants for each species- remained scattered in inaccessible sites on the sea clifs of Illa Grossa in 1987, without opportunities to produce seeds due to the lack of local long-distance pollinators. Between 1989 and 1990, a common number of cuttings coming from each individual were cultivated on Illa Grossa, obtaining new seeds and starting a plant production line (Suárez, 1992). he progressive reinforcement started on Illa Grossa in 19921993, within the plant community dominated by Suaeda vera. In those initial years, all individuals of the invading prickly pear Opuntia maxima Mill. were eradicated, except for the case of the oldest monumental individuals –trees up to 4 m tall-, mainly maintained to secure food sources for migrant birds. he green stems of Opuntia were composted and used subsequently as mulch to fertilize the holes where new native species produced in the archipelago were planted. he main conservation project was the re-introduction of Medicago citrina on Illa Grossa, which had not been present since the 1960s (Klemmer, 1961), using both cuttings and seeds from Ferrera and Foradada islets. More than 400 plants were planted between 1990 and 1998. he population of M. citrina on Illa Grossa currently is made up of more than 300 adult individuals and new seedlings are regularly included, so the efective re-introduction task has been achieved. In order to restore the vegetation, a long-term programme was simultaneously proposed (Laguna & Jiménez, 1995), combining civil work –e.g. stonework micro-walls on surface run-of to stop the efects of soil erosion– with vegetation improvement, such as sowing annual species and planting perennial species which were fully produced in a small nursery built on Illa Grossa. However, the recovery of the last step –climacic vegetation- is still uncertain due to the lack of seed production of the remainder of individuals of Pistacia lentiscus and Chamaerops humilis. As a main management action, the Nature Reserve carries out the biological control of the woodlouse Iceria purchasi, a serious pest for the cellebrated Citrus crops of the Valencian area, which entered the Columbretes archipelago in April 1997, destroying in just a few weeks more than 2/3 of Medicago citrina population. By 1995 and 1996, the Valencian Citrus crops sufered the attack of a new pest (the leafminer Phyllocnistis citrella), which was quickly but inefectively combated using strong doses of pesticides. As a collateral efect, the biocides destroyed most of the population of the main predator of I. purchasi, the beetle Rhodolia cardinalis. he biocides generated the imbalance 304 Islands and plants: preservation and understanding of lora on Mediterranean islands on biological control of Iceria, favouring a sudden increase in their populations on the coastal agricultural lands and city gardens of the Valencian Community. Woodlouses were inadvertently carried in the feathers of migrant birds coming from the continent and stopping in Columbretes. Since 1997, hundreds of individuals of Rhodolia were regularly released in key sites of the archipelago and the population of M. citrina has been actively self-recovered. Apparently, the population explosion of Iceria killed the oldest specimens of Medicago, and most of the new individuals seem to be resistant to the pest, ensuring the survival of this species, listed in the ‘Top 50 Mediterranean Island Plants’ (Montmollin & Strahm, 2005). AKNOWLEDGEMENTS To Patricia Pérez-Rovira, who provided the correction and assisted in the translation into the English version of this paper. To the Biodiversity Service -particularly to the head of service Dr. Juan Jiménez, irst director of the Nature Reserve- and Natural Parks Service of the GV, as well as to the wardens and technicians of the Nature Reserve of Columbretes, who provided us information about the conservation activities. REFERENCES Boira, H., Carretero J.L. 1987. Flora vascular de las Islas Columbretes. In: Alonso, L.A. et al. (eds.). Islas Columbretes: Contribución al estudio de su medio natural. Monograies COPUT 5, Generalitat Valenciana, Valencia, p. 109-128. al estudio de su medio natural. Monograies COPUT 5, Generalitat Valenciana, p. 129153. Fabregat, C., López-Udias, S. 1997. Programa general de conservación de lora amenazada de la provincia de Castellón. Unpublished report. Generalitat Valenciana. Bolòs, O. 1989. La vegetació d’algunes petites illes properes a la Península Ibérica. Folia Botanica Miscellanea, 6: 115-133. Fabregat, C., Pitarch, J., Guaita, S. 2009. Propuesta I+D de realización de investigación aplicada a la evaluación del estado de conservación de la vegetación y propuesta para mejorar su gestión en la Reserva Natural de las Islas Columbretes. Unpublished report. Generalitat Valenciana. Bolòs, O. (ed.) 1992. Plantes vasculars del quadrat UTM 31SCE01: Els Columbrets. ORCA, Catàlegs lorístics locals 4: 1-37. Carretero, J.L., Boira, H. 1987. La vegetación de las Islas Columbretes. In: Alonso, L.A. et al. (eds.). Islas Columbretes: Contribución 305 From ire to nature: evolution, restoration and conservation of the Columbretes Islands lora Gisbert, J.M. 1987. Clima y suelo de las Islas Columbretes. In: Alonso, L.A. et al. (eds.). Islas Columbretes: Contribución al estudio de su medio natural. Monograies COPUT 5, Generalitat Valenciana, Valencia, p. 95108. (España). Ecologia Mediterranea, 21(1/2): 325-336. Mestre, E., González, P., Del-Señor, X., Fabregat, C. 2008. La lora exótica invasora en las Islas Columbretes: antecedentes y situación actual. In Iª Jornada sobre lora exòtica invasora al territori valencià, 2425 de Octubre de 2008. Jardí Botànic de la Universitat de València. Valencia. Jiménez, J. 1998. La Reserva Natural de las islas Columbretes. El medio terrestre. In: La reserva Marina de las Islas Columbretes. Ministerio de Agricultura Pesca y Alimentación, Madrid, p. 59-64. Montmollin, B. de, Straham, W. 2005. he Top 50 Mediterranean Island Plants. IUCN, Gland and Cambridge, 110 pp. Juan, A., Crespo, M.B. 1999. Comportamiento itosociológico de Medicago citrina (Font Quer) Greuter (Leguminosae), endemismo mediterráneoiberolevantino. Acta Botanica Malacitana, 24: 221-229. Salvator, L. von. 1895. Columbretes. Druck und Verlag von H. Mercy. Praga. Serra, L., Pérez-Botella, J., Izquierdo, J.J. 2001. Medicago citrina (Font Quer) Greuter (Leguminosae) en la Península Ibérica. Anales del Jardín Botánico de Madrid, 59(1): 158-159. Juan, A., Crespo, M.B. 2001. Anotaciones sobre la vegetación nitróila del archipiélago de Columbretes (Castellón). Acta Botanica Malacitana, 26: 219-224. Suárez, O. 1992. Estudio de la lora y vegetación de las islas Columbretes y su posible regeneración. Unpublished Career Disertation. Universidad Politécnica de Valencia. Valencia, 123 pp. Klemmer, K. 1961. Islas Columbretes; die Schlageninseln ohne Schlangen. Natur und Volk, 91: 39-47. Laguna, E. 2001. he micro-reserves as a tool for conservation of threatened plants in Europe. Nature & Environment series nº 121. Council of Europe, Strasbourg, 119 pp. Smyth, W.H. 1831. On the Columbretes, volcanic rocks near the coast of Valencia, in Spain. Journal of the Royal Geographic Society of London, 1: 58-62. Laguna, E., Jiménez, J. 1995. Conservación de la lora de las islas Columbretes 306 Islands and plants: preservation and understanding of lora on Mediterranean islands Table 1. Syntaxonomical scheme of the Columbretes Islands plant communities to subassociation level [according with Rivas-Martínez & al., Syntaxonomical checklist of vascular plant communities of Spain and Portugal to association level. Itinera Geobotanica, 14: 5-341 (2001), with minor modiications] 307 From ire to nature: evolution, restoration and conservation of the Columbretes Islands lora 308 Islands and plants: preservation and understanding of lora on Mediterranean islands THE FLORA OF THE ISLETS OF THE BALEARIC ISLANDS Juan Rita and Gabriel Bibiloni Dept. de Biologia, Universitat de les Illes Balears Abstract A description of the lora and vegetation of the islets of the Balearic Islands shall be presented here. We have found 654 species on 91 islets of the Balearic Islands. 30% of these species were found on only one island, and only 82 species have been found on more than 20% of the islets, which shows the great variability of the lora from one islet to another. We will also present a summary of the major plant communities, which include the nitro-halophytic shrub communities, as well as those that colonize the clifs that are very rich in endemic species. he islands of less than 5 ha poorly it into the general model that relates the number of species and island area. he number of habitats is shown as a better descriptor of the number of species than the surface area for these small islands. Signiicant diferences were observed between the rates of life forms, especially chamaephytes and therophytes, between the islands of less than 5 ha and more than 5 ha. Finally, we mention some of the main environmental disturbances afecting the islets, with special reference to the introduction of goats and rabbits, and the presence of seagull colonies. Keywords: Insularity, endemism, species-area relationship, life form, Cabrera, biogeography INTRODUCTION AND BACKGROUND he Balearic Islands are located in the centre of the Western Mediterranean basin, at a minimum distance of 87 Km from the Iberian Peninsula, and about 230 km from North Africa. hey consist of ive inhabited islands: Mallorca, Menorca, Eivissa, Formentera and Cabrera, plus more than a hundred small islands, islets and rocky outcrops (from 0.05 to 270 ha), as satellites of the major islands. Corresponding author: Juan Rita (jrita@uib.es) 309 he lora of the islets of the Balearic Islands he vegetation of these islands is composed almost exclusively of Mediterranean elements, being particularly abundant southern Mediterranean species. Some taxa have their northern distribution limit here. he study of these habitats is interesting because they are places where there are very speciic ecological conditions, with high environmental stress and a relative isolation from the larger islands. Some species live exclusively in these habitats due to their protective efect or because they are true specialists of small islands (Höner & Greuter, 1988). here have been several contributions to the lora and vegetation of the Balearic islets, but usually in a context of broader work. For example, catalogues and loras of the Balearic Islands made during the nineteenth and twentieth century, such as Barceló (1879-1881), Knoche (1921-1923), Duvigneaud (1979), Pla et al. (1992) provide some interesting data. he archipelago of Cabrera, with the works of Marcos (1936), Palau, (1976), Bolòs et al. (1976), Bibiloni et al. (1993), Rita & Bibiloni (1993), Bibiloni & Rita (1995 and 2000), has been quite well explored. A comprehensive loristic checklist of the islets that surround the island of Mallorca is yet to be published, with the exception of the island of Dragonera with the works of Alomar (1981) and Alomar et al. (1998). In Menorca the situation is similar, as most loristic citations refer to the Illa d’en Colom (Rodríguez, 1904, Bolòs et al. 1970) but again, there is not a checklist of the lora of their islets. On the other hand, regarding the Pitiüses, we ind the contributions of Kuhbier & Finschow (1977) and Kuhbier (1978a and b). Previously, the main islets of the Pitiüses attracted the attention of other authors such as Font i Quer (1920, 1926, 1933, etc.) and Tebar et al. (1989). he following pages include some results of the loristic exploration of more than 90 of these small islands. We present the main characteristics of their lora as well as some information about plant communities and some comments about the relationship between the surface of the islets and the number of species included in their loras. CHARACTERISTICS OF THE BALEARIC ISLETS A loristic checklist of 91 islands of less than 300 ha of the Balearic Islands has been made (see Figure 1). Each islet was visited at least three times in diferent seasons over the three years of ieldwork. his sample of islands represents, in fact, most of the Balearic islets that have been colonized by vascular plants. In Mallorca we have studied 23 islets, 28 in Eivissa, 9 in Formentera, 15 and Menorca, and 15 in the Archipelago of Cabrera, (we have excluded Cabrera Gran, the main island, because it has a signiicantly 310 Islands and plants: preservation and understanding of lora on Mediterranean islands larger surface than the other islands). Table 1 shows the size classes of the islets studied. he islets smaller than 0.5 ha represent more than a quarter of all islets studied, those smaller than 5 ha are more than three quarters of the sample. Only four islands cover an area larger than 100 ha. 85% of the islets studied are less than 50 m in height. Only ive islands are over 100 m in height, and only two (Es Vedrà in Eivissa and Dragonera in Mallorca) are higher than 300 m. Approximately 60% of the islets are less than 500 m from the coast, and only two groups of islands, the archipelago of Cabrera and Bledes, are found more than 4 km from Mallorca and Eivissa, respectively. All Balearic Islands are associated with the continental shelf, and all of them are composed of carbonate substrates, except the Illa d’en Colom on the northern coast of Menorca. Fig. 1. Map showing the location of the islets studied (Es Faralló d’Albarca (8) and Cabrera (26) were not included). 311 he lora of the islets of the Balearic Islands Islet surface area <0,5 ha 0,5-1 ha 1-2 ha 2-5 ha 5-10 ha 10-20 ha 20-100 ha 100-300 ha Num. Islets 24 19 13 14 7 5 5 4 % 26,4 20,9 14,3 15,4 7,7 5,5 5,5 4,4 Average num. sp. 23 20 22 82 46 124 175 201 ± std. error 5,3 5,1 4,7 14,1 9,9 11,7 30,0 44,6 Max. Min. 122 80 58 139 80 159 268 300 1 1 1 13 16 98 90 113 Table 1. Major values of size and plant diversity of the Balearic Islands. THE FLORA OF THE ISLETS We have found 654 species of vascular plants on the 91 islets studied. he variability from one islet to another is huge, even between the islands of similar size and geographic location. About 30% of these species (190) are found on a single island, and about 60% of species were found only in 4 islands or less. Surely many of them are occasional species that are part of the natural turnover of these islands (Snogerup & Snogerup, 2004; Panitsa et al., 2008). By contrast, only nine species have been found on more than 50% of the islands. he most frequent plant is Asparagus horridus (found on 69% of the islets), followed by Crithmum maritimum (62% of the islets), and Desmazeria marina, Parapholis incurva, Suaeda vera, Mesembryanthemum nodilorum, Sonchus oleraceus and Medicago littoralis. hree of these nine species have halophytic characteristics or belong to the coastal plant communities, and two of them are more typical of ruderal areas. 82 species (12.6%) have been found on more than 20% of the islands. hese species probably are those that best characterize the islets’ habitats; however, over 35% of these species are ruderal or associated with perturbed environments. Despite the great variability of the loristic composition of the islets, that is the result of diferent idiosyncrasies of each islet (Lomolino & Weiser, 2001, Panitsa et al., 2001), it is possible to recognize loristic ainities and diferences between the islets from the eastern Balearic Islands (Mallorca, Menorca and Cabrera), and those of the Pitiüses (Eivissa and Formentera). We have found 85 endemic and narrowly distributed species. Some of these are true islet specialists (Höner & Greuter, 1988), for example Euphorbia margalidiana, which lives on a single islet (Ses Margalides in the north of Eivissa), or Medicago 312 Islands and plants: preservation and understanding of lora on Mediterranean islands citrina and Beta vulgaris subsp. marcosii, which live on a few small islands of the archipelago of Cabrera and Eivissa (see below) but not on the main islands (Medicago citrina can be also found on the smallest islands of the Columbretes Archipelago). Rubia angustifolia subsp. caespitosa, endemic of Cabrera Gran, and Silene cambessedesii, endemic of a few islets, could also be included in this group, but they can also be found on some beaches of Eivissa and Formentera and in a area of the mainland. Other cases are Withania frutescens and Parietaria mauritanica, living in the Balearic Islands mainly on islets. Daphne rodriguezii, cited as an islets’ specialist (Höner & Greuter, 1988), is a very interesting case. here is a large healthy population on the Illa d’en Colom (north of Menorca) of this species, which lives together with its natural disperser, the endemic lizard Lacerta lilfordii (Traveset, 2002). here are other senescent populations of this plant on the Island of Menorca, but there, on the main island, Lacerta lilfordii was extinguished and this mutual relationship was disrupted, currently the plant has signiicant diiculties to maintain these populations outside the islet (Traveset, 2002). Some islands, like Cabrera Gran, Es Vedrà, Vedranell and Espartar, have endemic or narrowly distributed plants linked with clifs and issures of rocks, such as Hippocrepis balearica, Asperula paui, and the threatened Silene hifacensis. PLANT COMMUNITIES OF THE ISLETS he islets vegetation is clearly under the inluence of a marine environment. On the smallest islets only halophytic species are able to survive. However, on the medium to large sized islets it is possible to recognize a zoning of shrub communities from the coastline to the inland (see for example Fig. 2). he plant landscape of these islands is made up primarily of three major vegetation types: coastal and nitro-halophytic communities, inland shrub communities, and herbaceous communities, generally with a ruderal character. here is wide variation in these communities, with notable loristic diferences between the islands of Eivissa and Formentera and the islands of Mallorca and Menorca. he Cabrera Archipelago has some characteristics in common with both groups of islands, but in general it has a closer relationship with the eastern Balearic Islands. 313 he lora of the islets of the Balearic Islands Fig. 2. Diagram of the main plant communities of Es Vedranell (Eivissa). Coastal communities Pulvinate chamaephytes communities: Communities with Limonium spp. (Al. Crithmo-Limonion) colonize areas particularly vulnerable to penetration of salts of marine origin, mainly those closest to coastal zones. Diferent species of mostly endemic Limonium (L. ebusitanum, L. dragonericum, L. caprariense, etc.) may be the only colonizers of these areas, along with Crithmum maritimum. On the islands of Menorca and Mallorca As. Launaeetum cervicornis can also appear. Annual communities of saline soils (Al. Frankenion pulverulentae): it appears in places with sediment with high concentration of salt, sometimes it is replaced by Mesembryanthemum nodilorum. Salt and nitro-halophytic shrub communities: In areas with greater inluence of the sea with limited amounts of soil, it is common to ind shrubs with Sarcocornia fruticosa and Arthrocnemum macrostachyum. In a more inland position there is a richer community with Suaeda vera, accompanied by other species such as Daucus carota subsp. commutatus, Dactylis glomerata subsp. hispanica, Silene secundilora, Asparagus horridus, Allium commutatum, etc. On some islands, in this zone Lavatera arborea can also be found, which even become dominant (As. 314 Islands and plants: preservation and understanding of lora on Mediterranean islands Lavatero-Suadetum verae). On a few small islets there are Medicago arborea and Beta vulgaris subsp. marcosii communities (As. Medicagini citrinae-Lavateretum arborae), probably these endemic species are very sensitive to the actions of herbivores (goat and rabbits) and hence are found on small islets without these animals or in inaccessible places. Its distribution is limited to the islets of Ses Bledes, S’Estell des Coll y S’Estell de Fora in Cabrera, Els Malvins, S’Espartar, Illes Bledes in the Pitiüses. Nitrophilous shrub communities: On many islands of the Cabrera Archipelago, and some from the Pitiüses and Mallorca, there is a shrubland with Whitania frutescens (As. Ephedro-Whitanietum frutescentis), its ecological area is in the transit zone between coastal communities and the inland sclerophyllous maquis of the Al. Oleo-Ceratonion. It has a thermophile and nitrophilous character and is probably linked to seabird colonies. Maquis and non-coastal scrub Woody communities are behind nitro-halophytic vegetation; they have a high plasticity of forms and structures depending on weather, geomorphological and soil conditions of each island. In windy areas the sclerophilous shrubland acquires a coastal character, where Pistacia lentiscus, Euphorbia dendroides, and Ephedra fragilis can be dominant, as well as Phillyrea media in some islets of Cabrera Arch. and I. Colom in Menorca. On the other hand, Juniperus phoenicea subsp. turbinata is common on many islets, especially in the Pitiüses. Calcareous thickets of Al. Rosmarino Ericion are only important in Cabrera and Dragonera, sometimes they have a tree layer of Aleppo pine (Pinus halepensis). Ruderal herbaceous communities On many islands herbaceous communities dominated by nitrophilous species appear: Urtica spp., Chenopodium spp., Lavatera spp., Beta spp., Parietaria spp., etc. In islets of the Pitiüses the presence of Diplotaxis ibicensis in these environments is also common. In most cases these communities are associated with seabird colonies, or the presence of goats or rabbits. Communities of clifs and rock issures A case in point for the richness of endemic species is the casmophytic vegetation that colonizes the shady side of rocks and limestone clifs of some islets. he As. Hippocrepidetum balearicae with Hippocrepis balearica, Crepis triasii, Helichrysum ambiguum is mostly found on Cabrera Gran and Dragonera. While on some islands of the Pitiüses like Es Vedrà, Vedranell and Espartar, we 315 he lora of the islets of the Balearic Islands ind the As. Hippocrepidetum-hymo ebusitani grossi, with Asperula paui, Silene hifacensis, Lamottea dianae, Scabiosa cretica, Saxifraga corsica subsp. cossoniana, Teucrium cossonii subsp. punicum, etc. Other types of communities On the larger islets there are other plant communities, usually linked to particular environments such as dune systems, humid zones, therophyte communities, etc., which are rare or do not exist on the smaller islets. ISLANDS AREA AND NUMBER OF SPECIES he classic relationship between species and island area (SAR) was discussed for the Balearic Islands by Fraga et al. (2004), Rita & Palleras (2006), and for the archipelago of Cabrera by Bibiloni et al., (1993). For the Balearic islets (not including the ive main islands) a signiicant positive correlation between the logarithms of number of species and area has also been found, but the coeicient R2 ofers a much lower value (0.426) than has been published for others for the bigger islands (Bibiloni et. al., 1993; Rita & Palleras, 2006). he correlation between the logarithms of the number of species and island area for the islands of less than 5 ha is signiicant despite being ofered a coeicient of R2 = 0.157, so that data it very poorly to the regression line obtained (Fig. 4). By contrast, the islets of more than 5 ha presented a much smaller variance, and a R2 = 0.597, so the regression line fairly describes more accurately the relationship between species number and island area. his anomaly of species-area relationship (SAR) on small islands has been described previously and called the Small Island Efect (SIE) (Whitehead & Jones, 1969; Lomolino & Weiser, 2001; Panitsa et al., 2006). It occurs because for these small islets many environmental factors (stochasticity of environmental factors, such as strong storms, and the idiosyncrasy of each island: localisation more or less exposed to prevailing winds, distance from shore, history, etc.) may be more relevant to deine the number of species than the surface area of the island itself. However, the relationship between the number of species and number of habitats (deined on the basis of plant communities present) shows a strong positive signiicant correlation (R2 >0.8) (Fig. 5), both for the two ranges of island sizes as for the whole sample. his shows that, in this case, environmental heterogeneity is the ecological factor that best describes the loristic richness in terms of number of species over other simpler geographical variables, like the surface area that does not summarize the complexity of ecological factors that act on these islets. 316 Islands and plants: preservation and understanding of lora on Mediterranean islands Fig 3. Species-area relationship for all Balearic islets studied. Fig 4. Species-area relationship for Balearic islets covering less than 5 ha. 317 he lora of the islets of the Balearic Islands Fig 5. Species-habitat relationship for all Balearic islets studied. ISLET SIZE AND STRUCTURE OF LIFE FORMS he life forms structure of the loras of the islets deviates signiicantly from the model showed by the major islands. Its Mediterranean character is recognized in the rate of therophytes, it is the largest species group with values even higher than those given on the main islands (Fig. 6). However, the second largest group is the chamaephytes, ahead of hemicryptophytes. Phanerophytes also had higher levels than in the ive largest islands in the Archipelago. his pattern is more substantial on the islands of less than 5 ha. In this sense, signiicant diferences were found between the average ratios of therophytes, chamaephytes and phanerophytes of islands of more or less than 5 ha (Fig. 6.). On the islands of less than 5 ha, the chamaephytes rate, which average around 30%, is more than double that in Mediterranean environments of the mainland. As for the ratio of therophytes on the islets of less than 5 ha, it is signiicantly lower, close to 40% versus 60% on the islets of more than 5 ha, which are similar values to those published by Panitsa et al. (2001). hese diferences can arise due to the lack of suitable environments for non-halophilous annual plant communities on the smallest islands. 318 Islands and plants: preservation and understanding of lora on Mediterranean islands Fig. 6. Average of % of life forms for islets with less than 5 ha versus islets larger than 5 ha with asterisks where diferences are signiicant. he average of the six main islands of the archipelago are included to comparison (source Rita & Palleras, 2006). ENVIRONMENTAL PERTURBATIONS OF THE ISLETS Archaeological remains exist on some islands of the Balearic Islands showing an occupation dating to the fourth century BC. Since then, these environments have been widely used by humans to a greater or lesser degree. Too oten we have introduced goats, sheep or pigs. On the islets that are large enough, mankind has cultivated and there has been a more or less regular human presence. Some islands have had very speciic uses like pesthouse, hospital, jail for prisoners of war, target shooting for the army or navy, etc. Naturally these uses, especially agriculture and the introduction of livestock, have changed the vegetation of the islands and have facilitated the introduction of many plant species. Even now, islets as interesting as Es Vedrà (Eivissa) have a population of goats that destroys the natural vegetation. Mankind has also introduced other animals such as rats and, especially, rabbits, causing a major impact on vegetation (very evident on the Illa de l’Aire in Menorca and Espartar in Eivissa). On Es Vedrà an old forest of Juniperus turbinata was cut down to obtain timber. 319 he lora of the islets of the Balearic Islands Seabird colonies occupy many islands, in some cases their presence is so massive that they signiicantly afect the vegetation, usually with an increase in ruderal species (Table 2), as has been documented on other Mediterranean islands (Vidal et al., 1998 and 2000). % no ruderal Therophytes Es Pantaleu 68,5 Sa Torre 66,6 Na Guardis 56,8 Es Malgrats 35 Illeta de Sóller 36,6 % ruderal Therophytes 31,5 33,4 43,2 65 63,4 Imperial 24 76 Table 2. Proportion of non-ruderal vs ruderal therophytes on six islets. he irst three with low pressure from seabirds, the last three with large colonies of sea gulls. REFERENCES Bibiloni, G., Alomar, G., Rita, J. 1993. Flora vascular dels illots i addicions a la lora de Cabrera Gran. In: Alcover, J. A., Ballesteros, E. & Fornòs, J.J. (eds.). Història natural de l’Arxipèlag de Cabrera. Mon. Soc. Hist. Nat. Balears, 2: 179- 206. Ed. CSIC y Edit. Moll. Palma. Alomar, G. 1981. Flora de Sa Dragonera. Lluc, 696: 114-117. Alomar, G., Rosselló, J.A., Pons, M. 1998. Materials per a l’inventari de Biodiversitat del parc de sa Dragonera: lora, vegetació i invertebrats. Ed. Conselleria de Medi Ambient, Govern Balear. Palma. Barceló, F. 1879-1881. Flora de las Islas Baleares. Palma. Bolòs, O. de, Molinier, R., Montserrat, P. 1970. Observations phytosociologiques dans l’Íle de Minorque. Acta Geobot. Barcinonensia, 5. Barcelona. Bibiloni, G., Rita, J. 1995. Análisis de la Biodiversidad de la Flora Vascular del Archipiélago de Cabrera. In: Datos sobre la Vegetación de Cabrera. Guía de la Excursión Geobotánica de las XV Jornadas de Fitosociología. Ed. U.I.B. Palma. Bolòs et al. 1976. Impressions sobre la vegetació de l’illa de Cabrera. Treballs de la Institució Catalana d’Història Natural, 7: 105-137. Duvigneaud, J. 1979. Calalogue provisoire de la lora des Baléres. Société pour l’Echange des Plantes Vasculaires de l’Europe et du Bassin Méditerranéen, 17 (supp.):1-43. Bibiloni, G., Rita, J. 2000. Flora y vegetación terrestre. In: Parque Nacional del Archipiélago de Cabrera, pp. 51-86. Ed Esfagnos. Talavera de la Reina. Font i Quer, P. 1920. Compuestas de las 320 Islands and plants: preservation and understanding of lora on Mediterranean islands Pitiusas. Bol. Soc. Esp. Hist. Nat., 20: 141-159. Font i Quer, P. 1926. De lora occidentale adnotationes II. Butlletí de la Institució Catalana d’Història Natural, 26: 53-57. der Pityusen. Veröfentlichungen aus dem überseemuseum Bremen. Reihe A, Naturwissenschaten, 5: 1-23. Lomolino, M.V., Weiser, M. D. 2001. Towards a more general species-area relationship: diversity on all islands, great and small. Journal of Biogeography, 28: 431-445. Font i Quer, P. 1933. Observacions botàniques. VII. Sobre una Diplotaxis d’Eivissa. Butlletí de la Institució Catalana d’Història Natural, 33: 210-211. Fraga, P., Mascaró, C., Carreras, D., Garcia, O., Pallicer, X., Pons, M., Seoane, M., Truyol, M. 2004. Catàleg de la lora vascular de Menorca. Ed. IME. Col·lecció Recerca 9. Maó. Marcos, A. 1936. Contribució al coneixement de la Flora Balear. Flòrula de Cabrera i dels illots pròxims. Cavanillesia, 8 (1-7): 4-52. Palau, P.C. 1976. Catàleg de la lórula de l’illa de Cabrera i dels illots que l’envoltan. Treballs de la Institució Catalana d’Història Natural, 7: 5-103. Höner, D., Greuter, W. 1988 Plant population dynamics and species turnover on small islands near Karpathos South Aegean, (Greece). Vegetatio, 77: 129-137. Panitsa, M., Tzanoudakis, D. 2001. A loristic investigation of the islet groups Arki and Lipsi (East Aegean Area, Greece). Folia Geobotanica 36: 265-279. Knoche, H. 1921-1923. Flora Balearica. Étude phytogéographique sur les Iles Baléares. 4 vol. Reprint Otto Koeltz Science Publishers, 1974. Montpellier. Kuhbier H., Finschow, G. 1977. Notas sobre la lora de las Pitiusas (Baleares). Lagascalia, 7: 121-125. Panitsa, M., Tzanoudakis, D., Triantis, K.A., Sfenthourakis, S. 2006. Patterns of species richness on very small islands: the plants of the Aegean archipelago. Journal of Biogeography 33, 1223–1234. Kuhbier, H. 1978a. Euphorbia margalidiana spec. nov. Eine neue Wolfsmilchart von der Pityusen (Balearen/Spanien). Veröfentlichungen aus dem überseemuseum Bremen. Reihe A, Naturwissenschaten, 5: 25-37. Panitsa, M., Tzanoudakis, D., Sfenthourakis, S. 2008.Turnover of plants on small islets of the eastern Aegean Sea within two decades. Journal of Biogeography 35: 1049–1061. Pla, V., Sastre, B., Llorens, L. 1992. Aproximació al catàleg de la lora de les Illes Kuhbier, H. 1978b. Beiträge zur lora 321 he lora of the islets of the Balearic Islands Traveset, A. 2002. Consecuencias de la ruptura de mutualismos planta-animal para la distribución de especies vegetales en las Islas Baleares. Revista Chilena de Historia Natural, 75: 117-126. Balears. Ed. Universitat de les Illes Balears. Palma de Mallorca. Rita, J., Palleras, T. 2006. Biodiversidad de las plantas vasculares de las Islas Baleares. Orsis, 21: 41-58. Vidal, E., Médail, F., Tatoni, T., Roche, P., Vidal, P. 1998. Impact of gull colonies on the lora of Riou Archipelago (Mediterranean islands of South-East France). Biological Conservation, 84 (3): 235-243. Rita, J., Bibiloni, G. 1993. La Vegetació de Cabrera (Memoria del mapa de les comunitats vegetals). In: Alcover, J. A., Ballesteros, E. & Fornòs, J.J. (eds.). Historia natural de l’Arxipèlag de Cabrera. Mon. Soc. Hist. Nat. Balears, 2: 207- 255. Ed. CSIC y Edit. Moll. Palma. Rodríguez, J.J. 1904. Flórula de Menorca. Imp. Fábregues. Mahón. Vidal, E., Médail, F., Tatoni, T., Bonnet, V. 2000. Seabirds drive plant species turnover on small Mediterranean islands at the expense of native taxa. Oecologia, 122: 427–434. Snogerup, S., Snogerup, B. 2004. Changes in the flora of some Aegean islets 1968– 2000. Plant Systematics and Evolution, 245: 169–213. Whitehead, D.R., Jones, C.E: 1969. Small islands and the equilibrium theory of insular biogeography. Evolution, 23: 171179. Tebar, J., Boira, H., Llorens, L. 1989. La vegetación de la Isla del Vedrà (Pitiusas, Islas Baleares). Ecologia Mediterranea, 15 (12):23-33. 322 5: Final Islands and plants: preservation and understanding of lora on Mediterranean islands 323 he unique nature of Mediterranean island loras and the future of plant conservation 324 Islands and plants: preservation and understanding of lora on Mediterranean islands THE UNIQUE NATURE OF MEDITERRANEAN ISLAND FLORAS AND THE FUTURE OF PLANT CONSERVATION Frédéric Médail Mediterranean Institute of Biodiversity and Ecology (IMBE, UMR CNRS-IRD), Aix-Marseille University, Technopôle de l’environnement Arbois-Méditerranée, BP 80, F 13545 Aix-en-Provence cedex 04, France. frederic.medail@imbe.fr Abstract he biotic originality of Mediterranean islands can be explained by complex interactions between a highly heterogeneous historical biogeography and unique ecological processes linked to various insular conditions. But most of the ups and downs of this unique biodiversity are now closely linked with human population pressures, which have changed many times through the long history of insular systems. hese impacts will probably be exacerbated on islands because of no (or highly limited) adjacent areas of expansion. herefore, conservation and ecological monitoring of small islands and islets must be reinforced, since they constitute major refuge areas with the presence of endemic relict plants, oten threatened on the continent. his global overview presents some key issues for future research devoted to future conservation and monitoring of the Mediterranean islands’ plants and habitats. Keywords: conservation biogeography, human impact, insular biogeography, islets, Mediterranean islands, mutual interactions, threats. THE UNIQUE NATURE OF MEDITERRANEAN ISLAND FLORAS he unusual geographical, climatic and topographical diversities and the reticulate historical biogeography of the Mediterranean Basin explain the exceptional high plant diversity and endemism of this area, one of the 34 biodiversity hotspots identiied around the world (Médail & Myers, 2004). With about 10,000 islands and islets, of which 244 are inhabited by humans (Arnold, 2008), the Mediterranean Sea encompasses one of the largest “archipelagos” in the world. Some Mediterranean countries such as Greece and Croatia, with ca. 1150 islands and islets according to Nikolic (2013), encompass a signiicant number of these islands. Insular areas harbour a signiicant component of the Mediterranean plant biodiversity, with the presence of narrow endemic plants or range-restricted ones, and the occurrence of 325 he unique nature of Mediterranean island loras and the future of plant conservation genetically isolated populations. Factors explaining the biological unicity of these insular loras are manifold: (i) varied paleogeography and geology, (ii) diferent geographical situations, (iii) wide ranges of morphology, size (from the biggest island of Sicily with 25,700 km2 to small islets of a few dozen square meters), or altitude (from 3342 m at Mt. Etna to lat islets of less of one meter). If the unique richness of Mediterranean insular loras is mainly due to strong environmental heterogeneities between islands, another key factor is the longlasting inluence of man who acts as a major disperser of plants and as a huge «designer» of Mediterranean insular landscapes through burning, cutting, grazing and ploughing. Indeed, the considerable beta and gamma diversities of insular ecosystems are also the heritage of various human activities that have had profound consequences on the distribution and dynamics of species, ecosystems, and landscapes (Blondel, 2008; Vogiatzakis et al., 2008). For historical and geographical reasons, but also due to the particular biotic interactions between species, insular conditions determine a speciic nature of plant assemblages and biodiversity. he percentage of endemism oten reaches high levels while there is rather limited plant richness (eg. Whittaker & Fernández-Palacios, 2007). his general insular pattern is also found on the larger Mediterranean islands. Here, plant endemism is generally comprised of between 10-12% whereas the overall range of lora is greater than expected, including between 1,600 and 2,800 taxa (species and subspecies) (Médail, 2008). On insular mountain ranges, endemism level is clearly higher since at altitudes above 1,700 m a.s.l. endemics represent about 35-40% of the vascular lora in Corsica and in Crete. If the global patterns of taxonomic diversity are now well estimated, at least for large Mediterranean islands (Greuter, 1995, 2001; Quézel, 1995), several gaps of knowledge exist in ecological research and conservation planning. his synthesis proposes some key issues for future ecological and evolutionary research on Mediterranean island plants in order to better assign conservation priorities and biodiversity monitoring. BIOGEOGRAPHY AND EVOLUTION OF MEDITERRANEAN ISLAND FLORAS Mediterranean islands represent major refuge areas and conservatories of old, oten mid-Tertiary loras with numerous relict plants characterized by a prolonged evolutionary standstill (Médail & Diadema, 2009). he relict nature of Mediterranean island plants is well supported by the presence of palaeoendemics restricted to one or few of these islands, and by the existence 326 Islands and plants: preservation and understanding of lora on Mediterranean islands of some relicts of the subtropical Tertiary environments. his is the case, for example, for the few populations of the fern Woodwardia radicans in Corsica and Crete, and for two small trees of the Elm family, Zelkova sicula in Sicily and Z. abelicea in Crete. An outstanding example of the importance of ancient palaeogeography to explain current patterns of plant distribution and biogeographical links concerns the Tyrrhenian islands. he eastern Balearic Islands (Minorca and Majorca), Corsica, Sardinia, and part of Sicily are some of the remnant areas that once belonged to the Protoligurian massif, a west-Mediterranean Hercynian formation that was fragmented in the mid-Tertiary (OligoceneMiocene), causing notably the rotation and migration of the Corsica-Sardinia block between 23 Ma and 16 Ma. he distribution of numerous Tyrrhenian endemic plants shared among these islands (eg. Arenaria balearica, Delphinium pictum, Dracunculus muscivorus, Teucrium marum) relects this crucial palaeogeographical event. Nevertheless, more recent evolutionary history related to the climatic aridiication since the Pliocene (ca. 3.2 Ma) and the onset of the Mediterranean climate inluence also the phylogeography of species as suggested by hymus herba-barona (Molins et al., 2011). In order to explain current patterns of plant distribution and endemism on the Mediterranean islands, two other major geological events must be invoked: the Messinian salinity crisis of the Late Miocene, and the severe cooling episodes along the late Pliocene and the Early-Middle Pleistocene (Tzedakis, 2009). he Messinian salinity crisis was provoked by the interruption of marine relationships between the Atlantic Ocean and the Mediterranean Sea. his has induced an almost complete desiccation of the Mediterranean Sea between 5.96 Myr and 5.33 Myr, with two evaporitic steps. During these two episodes, there were some opportunities for the migration and establishment of droughtresistant plant species as even the major islands were completely joined to the continent. Five million years ago, the beginning of the Pliocene was marked by the return of the sea and this resulted in the inal separation of some major islands (Crete and Karpathos, Corsica, Sardinia, Balearic Islands) from the mainland. he second determinant episode is related to several drastic marine regressions that have occurred during the recurrent ice ages at the end of the Pliocene and until the Last Glacial Maximum (ca. 18,000 ± 2000 yr BP). Marine regressions consist in more or less severe decreases in sea level, between 100 and 150 m below the current level, inducing the possible terrestrial migration of a more competitive cool-temperate lora on some ofshore islands. his is the case of most of the Aegean islands, except Rhodes, the Cyclades and the Crete327 he unique nature of Mediterranean island loras and the future of plant conservation Karpathos island group which remained insular throughout the Pleistocene. On the whole, the contribution of these land-bridge connections is important to explain biogeographical ainities between currently distant and isolated loras. Nevertheless, long-distance dispersal of seeds by birds or marine currents is also relevant to island colonisation but well-documented evidence is still rare except for common halophilous plants (Westberg & Kadereit, 2009). Nevertheless, an eastwards long-distance dispersal is invoked to explain the geographical disjunction of Armeria pungens, a disjoint western Mediterranean coastal sand-dune plant, and recent genetic analysis suggests that CorsoSardinian populations originated from the southwest Portuguese ones (Piñeiro et al., 2007). If Mediterranean islands have served as important Tertiary and glacial refuges, their role in the local and more recent diferentiation of plants is probably equally important. hese islands possess highly polymorphic species and vicariant endemic plants stemming from more or less recent speciation events (eg. Limonium, Centaurea) (Rosselló, 2013). Isolation and environmental heterogeneity have favoured here diverse evolutionary processes of gradual speciation of plants, such as genetic drit or adaptive radiation. Several wellstudied examples are found in the Aegean islands (Eysimum sect. Cheiranthus, Nigella arvensis complex), where the history of isolation of these multiple islands determine pronounced random plant diferentiation following fragmentation of a former contiguous distribution area. Detailed molecular studies in Nigella of the Aegean archipelago demonstrate that the main diversiication process occurs during Late Pleistocene (Bittkau & Comes, 2009). herefore, if Mediterranean island loras are in part relict, their evolutionary dynamics are probably underestimated, in particular on small islands subject to harsh and stochastic environmental conditions. INSULAR BIOGEOGRAPHY AS DETERMINANT OF CURRENT PLANT DIVERSITY According to the seminal theory of insular biogeography developed by Robert H. MacArthur and Edward O. Wilson in the 1960s, there is a global dynamic equilibrium determining the number of species found on an island. his equilibrium theory of species richness is based upon the balance between species immigration to an island, and extinction from it of local populations, under the inluence of island isolation and island area, respectively. Another classic rule is the strong and recurrent relationship between species number and area, but this pattern is not as simple as it may seem since the analysis of 328 Islands and plants: preservation and understanding of lora on Mediterranean islands the species-area relationships (SARs) reveal a high level of uncertainty across biomes or taxa (Guilhaumon et al., 2008). A study of the species composition of 48 small islands of the Provence archipelago (S.E. France) demonstrates the combined efects of physiographic variables (area, isolation, elevation and substrate) and habitat diversity on plant species richness and composition (Médail & Vidal, 1998). he cornerstone of this relationship is habitat diversity, which increases on larger islands, which have stronger topographical diversity and elevation, favouring the settlement and persistence of plant species and ecosystems not strictly linked to the presence of salt. For the Provence islands, there is a greater random variation in the number of plant species present and in presence/absence of plants on smaller islands (area less than 3.5 hectares) than on larger islands. Small islands are submitted to harsh environmental conditions (continuous sea-sprays and strong winds) but also oten sufer greater disturbances (storms, nesting sea gulls), which explains why an important set of plant species cannot survive on islands below a critical size. his «small island efect» is perceptible for islands below 1-3 ha, and for some Aegean islets, a signiicant increase in plant richness is only detected when the land surface is greater than 500 m in length and has an altitude of at least 50 m a.s.l. (Höner & Greuter, 1988). Due to the generally small distances of islands from each other and from the continent, the efect of isolation is not always so obvious and it is in general poorly correlated with plant richness. Nevertheless, there are oten some striking diferences in loristic composition between ofshore islets and the roughly similar ecosystems located on the opposite coast, in spite of the reduced physical barrier, the short time of separation and their apparently similar environmental conditions. Furthermore, some remote islands exhibit a loristic pattern quite similar to those of the remote oceanic islands: this is the case of Alborán island (7.1 ha, 15 m a.s.l.) isolated between Spain (85 km) and Morocco (55 km) which includes very limited plant richness (20 species) but with the presence of three endemic plants (Anacyclus alboranensis, Diplotaxis siettiana, Senecio alboranicus) only restricted to this lat island (Mota et al., 2006). One of the most fascinating and intriguing patterns is related to the botanical unicity of each island. Some close islands show very diferent plant species composition, suggesting the existence of selective plant dispersal through some narrow stretches of sea, as well as random colonisation and extinction processes. For example, the distribution of ca. 60 plants species (notably Campanula, Dianthus, Erysimum, Helichrysum) restricted to mostly 329 he unique nature of Mediterranean island loras and the future of plant conservation maritime clifs (chasmophyte plants) of the Aegean show marked diferences between islands, even on those less than 10-20 km apart. Recent investigations on Ionian Islands demonstrate indeed the high beta-diversity, i.e. loristic independence, for the Echinades islets group (Panitsa & Eleni, 2013). Despite repeated land-connections linked to sea-level changes during geological times, small distances have played here an efective barrier to plant dispersal, allowing plant population isolation and speciation processes. INSULARITY, A FACTOR PROMOTING ORIGINAL PLANT DYNAMICS AND BIOTIC INTERACTIONS Since islands constitute more simpliied systems in terms of species richness -notably redundant ones- and ecosystem function, they represent robust “natural mesocosms” to test hypotheses related to the complex links between biodiversity, ecosystem structure and function. Compared to the continent, island communities and ecosystems are more sensitive to exogenous disturbances and to environmental stochasticity, which promotes oten rapid and contrasted dynamics. his is particularly the case of small islands and islets which oten house large sea-bird colonies as they beneit from the tranquillity necessary to accomplish their nesting cycle. hese colonial seabirds exert high pressure on ecosystems by modifying patterns and dynamics of plant communities. he impact of seabirds on the vegetation is severe, with physical (trampling, pulling-up, soil erosion, burrowing) or chemical (soil manuring induced by guano rich in phosphorous and nitrogenous compounds, salt deposition) disturbances (Vidal et al., 1998, 2000; García et al., 2002). hese strong ecological pressures favour the most resistant (ruderal) plants at the expense of oligotrophic stress-tolerant species. Seagulls’ inluence may lead to severe imbalances for insular communities since (i) they oten induce changes in the leaf nutrient status of the dominant plants, (ii) they alter the cover, composition or turnover of the plants, and (iii) they modify interactive processes between species. Besides wind, birds act also as important natural vectors for the dispersal of seeds from mainland or other islands. hus, passive introductions of new islet plants are indeed frequently observed near nesting colonies of seagulls. he efects of an increasingly large yellow-legged gull Larus cachinnans colony on the lora of the Marseilles archipelago were studied through the analysis of loristic changes (species turnover) that have occurred in the past 40 years (Vidal et al., 1998). Plant turnover appears to be positively linked to gull nesting density and it is inversely correlated to island area since small islets appear to be more afected than larger islands. Plants 330 Islands and plants: preservation and understanding of lora on Mediterranean islands with the highest turnover rate were primarily ruderal, annual, wind-dispersed species, with a wide geographic distribution (Vidal et al., 2000). Disturbance by seabirds favours the massive establishment of non-native species which has led to the extinction of some endangered plants on islets characterized by important species turnover. Because of the intrinsic characteristics of island ecosystems, there exist particular types of plant-animal interactions. One of the most striking examples is the plant-lizard mutualism deeply studied in the Balearic archipelago. Here, endemic lizards (Podarcis lilfordi and P. pityusensis) acted as probably the only seed dispersers of a native shrub species Cneorum tricoccon (Riera et al., 2002) and of an endangered endemic Minorcan shrub Daphne rodriguezii (Traveset & Riera, 2005). But introduction of carnivorous mammals in the Balearic Islands has caused a dramatic mutualism disruption, between Daphne rodriguezii and Podarcis lilfordi. Seed dispersal by lizards is the critical stage that limits population expansion and seedling recruitment, drastically reducing Daphne populations, except on the Colom islet where lizards still persist (RodriguezPérez & Traveset 2010). Disperser loss also has a negative impact on the genetic diversity of this Daphne, which possesses higher relatedness among individuals for Minorcan populations (Calviño-Cancela et al., 2012). Lizards can also pollinate some coastal Mediterranean plants (Crithmum maritimum, Euphorbia dendroides), notably on islets where they occur with a high density and are not threatened by the introduction of exotic carnivores. Studies of reproductive ecology of plants on small islands appear also relevant to better understand the pollination syndrome occurring in isolated populations when insects are occasional (Pérez-Bañón et al., 2007), or even absent as for the bee-pollinated endemic Medicago citrina in the Columbretes archipelago (Pérez-Bañón et al., 2003). 331 he unique nature of Mediterranean island loras and the future of plant conservation Structuration / continent Plant communities with original composition floristic Functioning Specific functional processes (flux, biotic interactions) Poor communities with few redundant species Impacts exacerbated by exogenous disturbances Higher abundance of rare, endemic and relict species, often in range limit Inflation density: relaxation of competition processes / expansion of ecological niches Isolated populations, with few individuals Processes of genetic differentiation (genetic drift, founding effects) and local adaptation Communities subject to drastic ecological stress, with important stochasticity Huge spatio-temporal fluctuations richness and composition of plant Table 1. Main patterns determining the ecological and functional importance of small islands THREATS TO MEDITERRANEAN ISLAND PLANTS If the coupled natural and human inluences contribute to the extreme heterogeneity and the biotic originality of Mediterranean islands (Vogiatzakis et al., 2008), the current main threats faced by the island biodiversity are mostly due to direct and indirect human impacts. Evidence of early insular colonisation by man are still debated in the Mediterranean, but a lower Palaeolithic occupation dated to at least 130,000 years ago in southern Crete (Plakias region) suggests that the early “inhabitants” reached this island using sea crat (Strasser et al., 2010): this inding could push the history of seafaring in the Mediterranean back by more than 100,000 years! But the irst proofs of long human presence on an island seem to occur on Cyprus -where the settlement of Mesolithic hunter-gatherers dates back at least 10,000 years b.C. and the development of agriculture occurs between 87008000 years b.C. (Guilaine et al., 2011). Nevertheless, it is still highly diicult to assess the magnitude of plant extinction induced by man during Holocene history. he local disappearance of the Dwarf-Palm (Chamaerops humilis L.) in Crete during the Antiquity, because of over-exploitation, constitutes a rare well-documented case, already mentioned by heophrastus (Amigues, 1991). Current human-induced threats are manifold in the Mediterranean region and they can be ranked by decreasing order of global importance: urbanization, tourism and recreation, environmental changes (land-use and global warming), biological invasions, ires, collecting pressures. he major islands are usually characterized by an increase in human 332 Islands and plants: preservation and understanding of lora on Mediterranean islands population, whereas smaller islands (except some hotspots of tourism such as Capri, Corfou, Djerba) are subject to a clear demographic decline. Since the 1960s, tourism on islands has increased extensively, with a height on some Balearic Islands (Majorca and Ibiza) where a peak was reached in 2000-2001 with 11 million tourists. herefore, on the Balearic Islands (López et al., 2013), it is estimated that urbanization and infrastructure explain one third of the current threats concerning the 180 threatened plant taxa. his huge human pressure induces a strong urban development, which is concentrated along the coasts, destroying or threatening several fragile ecosystems such as sand-dunes and wetlands, and to a lesser extent, coastal rocky habitats. For example, on the Greek island of Skiathos (N. Sporades), tourism development since the 1970s has produced an 80% reduction of these coastal ecosystems. Changes in agricultural and livestock farming extending inland have caused a recent collapse of the traditional Mediterranean triptyque of landuse (agriculture, grazing, forestry), which has moulded insular landscapes over several centuries (Rackham & Moody 1996; Blondel, 2008). Diverse trends in landscape dynamics cause major modiications to the structure and composition of ecosystems. In the western part of Crete, human immigration from arid mountains has lead to the decline of agricultural land surfaces by 39% between 1945 and 1990, and favoured expansion and the densiication of forest ecosystems dominated by Cupressus sempervirens and Pinus brutia. On the contrary, high shrublands and natural forests of eastern Sardinia have diminished by 35% between 1955 and 1996, whereas grazing, burned low shrublands and deforestation are progressing. On this island, and on other smaller islands of the Aegean, uncontrolled grazing by sheep and goats can lead to overgrazing and even to desertiication, i.e. land degradation under arid and semi-arid climates. Landscape dynamics are more contrasted in Corsica, because if land-abandonment determines a global increase of shrublands and forested areas, frequent ires linked to illegal pastoral practices can counterbalance this trend. Islands of the world have proven to be especially sensitive to biological invasions in both frequency and the degree of impact when compared to the continent (Whittaker & Fernández-Palacios, 2007). Invasions oten modify population dynamics, community structure, the composition and functioning of ecosystems and may accelerate the extinction of indigenous plants. Mediterranean islands and islets are also in places seriously threatened by aggressive alien plants, notably along coasts, in lowlands and along rivers. Exotic plant species represent 17% (473 taxa) of the Corsican lora but only 333 he unique nature of Mediterranean island loras and the future of plant conservation 6% of which are well established (171 naturalized taxa), 9.2% (184 taxa) of the Sardinian lora, and 8.4% (124 taxa) of the Balearic Islands’ lora. Small islands are probably the most threatened by plant invasions (Pretto et al., 2012). Some these most invasive plants are Acacia spp., Ailanthus altissima, Carpobrotus spp., Cortaderia selloana, Opuntia ssp., Oxalis pes-caprae and Senecio angulatus. Comparative studies conducted on several large Mediterranean islands demonstrate that impact depended on the identity of the invasive plant and the invaded island, suggesting that impact of invaders is context-speciic (Traveset et al., 2008). Climatic changes represent a new threat for the persistence of several insular plant populations and communities, notably those linked to temporary wet habitats. his is the case of Apium bermejoi, a narrow endemic of Minorca located in a single area of 50m2 where the ca. 100 individuals occupy only one square meter; this critically endangered plant (CR sensu IUCN) is highly vulnerable to prolonged drought period and its present decline is probably related to a series of dry summers (Moragues & Mayol, 2013). Regarding Cyprus, several populations of narrow endemics (Sideritis cypria, Onosma caespitosa, Salvia veneris) are also threatened by the strong reduction of annual rainfall (less than 20 to 40%) and the signiicant increase in temperatures (Kadis, 2013). Climate change will strongly afect orophilous plant diversity, species turnover and local endemics of the mountain zones, notably the spatially-restricted subalpine and alpine areas, as in the Leka Ori massif of Crete (Kazakis et al., 2007). But despite these diverse threats and the fact that a large number of endemic plant species are narrowly distributed on a single island with few populations, only a reduced number of endemics seem to have still become extinct on the Mediterranean islands. Of the about forty Mediterranean plants presumed extinct, ten species are strictly insular endemics (Blondel & Médail, 2009). Two of these species are only extinct in the wild, Lysimachia minoricensis from Minorca and Diplotaxis siettiana from the Alborán islet, but in this latter case plant reintroduction was successful. Sicily seems to be the most impacted island with the extinction of four endemics (Allium permixtum, Anthemis abrotanifolia, Carduus rugulosus, Limonium catanense) and one from Lampedusa (Limonium intermedium). Over the course of history, Sicily has been at the crossroad of important trading routes and human presence has impacted ecosystems over an earlier and more constant period than on the Italian peninsula. Human activities caused a huge retraction of woodlands that occupy at present only about 10% of Sicily, mostly on Mount Etna and in the northern mountains (Madonie, Nebrodi, and Peloritani). In the eastern Mediterranean, two 334 Islands and plants: preservation and understanding of lora on Mediterranean islands endemic species from the hasos island (N. Aegean) (Geocaryum bornmuelleri and Paronychia bornmuelleri) are presumed extinct, and one endemic pink (Dianthus multinervis) from the remote islet of Jabuka in Croatia. On large islands, the percentage of taxa that are threatened ranges from 2% (Corsica) to 11% (Crete). In Corsica, as much as 90% of the local extinct plants (74 taxa) occurred in low altitude, between 0 and 800 m a.s.l., and they were mainly located in arable ields, wetlands, coastal areas and rocky grasslands (Verlaque et al., 2001). herefore, the lora of Mediterranean islands is on the whole deeply threatened, especially the endemic species that grow in low altitude habitats and in wet habitats. IMPORTANCE OF SMALL ISLANDS AND ISLETS FOR PLANT CONSERVATION Most of the ecological studies carried out were devoted to large Mediterranean islands, but even the smallest ones should be better investigated since several studies point out their high biotic originality and their oten high taxonomic diversity considering their reduced size: this is the case of the satellite islands of Sicily (Pasta and La Mantia, 2013) or the Balearic Islands (Rita and Bibiloni, 2013). From the taxonomic diversity point of view, several comparative inventories demonstrate that small islands (i.e. size < ca. 1000 ha) play a disproportionate role for the magnitude of plant richness. On 71 satellite islands of Sardinia -which represent only 1.1% of the total surface of the main island- 1,200 plants were censused on the whole, i.e. almost half of the total Sardinian lora. In Corsica, 39 properly censused islets harbour 534 plant taxa, i.e. 21.6% of the whole Corsican lora on only 0.025% of the total surface of the main island (Serrano, 2008). he same pattern is found for the lora of the satellite islets of the Balearic Islands: 654 species occur on 91 islets, i.e. 40% of the lora of this archipelago, whereas 30% of these micro-insular plants are present on a single islet (Rita & Bibiloni, 2013). Within these highly spatially-reduced territories occur rapid microspeciation processes, and the combination with particular biotic assemblages and interactions between species favour the presence of some «islet specialists» (Höner & Greuter, 1988). hese plants grow exclusively or are very abundant on these islets, but not on the mainland or on the closest larger island. hey are oten adapted to some disturbance or stress (ruderal and stress-tolerant strategies sensu Grime) and are salt-tolerant, but not strictly halophilous. Some possess a large pan-Mediterranean distribution (Allium commutatum, Hymenolobus 335 he unique nature of Mediterranean island loras and the future of plant conservation procumbens, Lavatera arborea), others constitute narrow endemics (e.g. Atriplex recurva and Silene holzmannii in the Aegean islands, Nananthea perpusilla and Silene velutina on some satellite islets around Sardinia or Corsica, Euphorbia margalidiana on a unique Balearic islet). heir distribution and abundance can be explained by their optimal specialisation to the highly harsh and unusual environmental conditions of these islets. Islet specialists oten possess a good ability for dispersal by sea drit over distances of hundreds of kilometres since loating diasporas can stand up to a month in the sea water. Another interesting pattern is that small ofshore islands can determine extreme limits of geographical ranges for some range-restricted plants. his is the case for the island of Zembra, which harbours the southernmost populations of some plants located mainly in Italy-Sicily (Erodium maritimum, Iberis semperlorens) or in the eastern Mediterranean (Sarcopoterium spinosum) and that are absent from the close (ca. 10 km) Tunisian continental coast. his pattern is also found on the Hyères archipelago, a remnant of the ancient Protoligurian massif, sheltering several Tyrrhenian endemics (Delphinium pictum, Ptilostemon casabonae, Teucrium marum), which are totally absent along the close mainland of the siliceous Provence, even though environmental conditions are similar. Because of their signiicant number (more than 1,500 for the western Mediterranean), small islands and islets encompass a large range of environmental and biogeographical situations, forming suitable “experimental laboratories” to test evolutionary and functional hypothesis which are useful for a better implementation of conservation eforts. Small islands also represent current refuges of very scattered or highly threatened plants with regards to the disproportionate human impacts destroying the coasts of the mainland, and they need therefore to be included in international conservation networks. his task represents the main objective of the “Small islands initiative” (“PIM: Petites îles de Méditerranée”) launched by the French Conservatoire du Littoral in 2006 (Renou, 2012). WHAT IS NEEDED FOR THE FUTURE OF MEDITERRANEAN ISLAND FLORA CONSERVATION? he complicated historical biogeography of the Mediterranean islands has induced the persistence of original and relict loras, but it has also favoured repeated local extinctions and re-colonisations of specialized plants. herefore, the future of their conservation planning should be included within a conservation biogeography schedule (Ladle & Whittaker, 2011) in order to 336 Islands and plants: preservation and understanding of lora on Mediterranean islands furnish the prerequisite tools for the identiication of the most threatened plants and the crucial conservation areas in today’s context of global change. Here, I propose some key issues for future research, in order to improve conservation and management of ecosystems and plant diversities on the Mediterranean islands and islets. Prioritising scientiic knowledge in order to increase conservation planning eiciency i) Understanding evolutionary and biogeographical processes Phylogenetical and phylogeographical studies have demonstrated the complex and reticulate historical biogeography of the Mediterranean region and the importance of large islands as reservoirs of unique genetic lineages, notably for most endemics and narrowly distributed plants (Médail & Diadema, 2009). Nevertheless, the time frame and evolutionary consequences of biogeographical events linked to repeated cycles of island connections and isolation, in relation to marine regressions-transgressions, remain largely unknown (Mansion et al., 2008). his is particularly worrying because these aspects are essential for an optimal evolutionary conservation of these heterogeneous insular loras. here is increasing evidence that primary speciation induced by geographical isolation (mainly by vicariance events), followed by inter-speciic gene low is deeply involved in the diversiication and cryptic speciation in several insular plant groups of the Mediterranean (Rosselló, 2013). he few studies examining intra-island phylogeographies of endemic plants demonstrate the frequent split of populations into several isolated and genetically divergent lineages, and their persistence in some particular areas, an “island beneath island syndrome” (Bauzà-Ribot et al., 2011). he narrow Balearic endemic Senecio rodriguezii exhibits a high number of haplotypes restricted to some small areas, probably shaped by the repeated cycles of sea-level changes during the Quaternary (Molins et al., 2009), whereas for the Corso-Sardinian endemic Mercurialis corsica, AFLP markers allow to detect a clear geographical isolation of the Cap Corse genotypes in N. Corsica (Migliore et al., 2011). his kind of genetic study also appears useful to perform the distinction between diferent Evolutionary Signiicant Units (ESUs) and for evolutionary conservation planning. Despite a long tradition of studies concerning rare insular plants and endemics, a focus on the evolutionary process of this distinct component is still necessary (Rosselló, 2013). Phylogenetic studies have to be used to better assess endemic species’ categories -and not only the classical categories based upon 337 he unique nature of Mediterranean island loras and the future of plant conservation chromosome numbers and polyploidy level (Favarger & Contandriopoulos, 1961)- and to evaluate the spatial restriction of phylogenetic diversity, termed phylogenetic endemism by Rosauer et al. (2009). Some recent studies concerning continental regions point out that there is a non-random relationship between evolutionary distinctiveness and geographical rarity of species: rare species possess high levels of evolutionary distinctiveness (Tucker et al., 2012; Taberlet et al., 2012), and this pattern should be tested for insular Mediterranean loras of various sizes. On short time-scales, mitigation of biodiversity loss requires estimation of populations and community responses to rapid environmental changes. his concern relies on the emerging concept of evolutionary rescue, “the idea that evolution might occur quickly enough to arrest population decline and allow population recovery before extinction ensues” (Gonzalez et al., 2013). herefore, many more studies are needed: (a) to better deine insular refuges at the scale of an archipelago or a larger biogeographic area; (b) to predict hotspots of evolutionary distinctiveness (evolutionary hotspots), based notably on endemic and rare plants; (c) to develop ine and local phylogeographies for conservation planning on the island scale; (d) to distinguish cryptic diversity linked to independently evolving lineages; and (e) to estimate short term evolutionary rescue of plants or communities. ii) Reconstructing palaeoenvironments and estimating the magnitude of ancient human impacts Due to their conined environment and their contrasted histories of human impacts, Mediterranean islands form suitable systems to better evaluate the inluence of man on the structure and function of ecosystems and landscapes, but also to understand the dynamics of current biodiversity. Palaeoecological studies must indeed be developed (i) to obtain a better knowledge of past environments between and within islands, (ii) to infer vegetation dynamics in relation to human impact versus climatic forcing (eg. Djamali et al., 2013), (iii) to identify tipping points of ecological collapse, and (iv) to propose suitable trajectories for ecological restoration. hese results could also furnish new insights for the long-lasting debate about the nature of Mediterranean environments: the “lost Eden paradigm” versus the “cultural landscape paradigm” (Blondel, 2013). If palaeoecological data exists for some large islands (Corsica, Sicily, Malta, Balearic Islands), almost no data is available for medium and small islands, and this precludes a good estimate of vegetation dynamics and ecosystem naturalness. 338 Islands and plants: preservation and understanding of lora on Mediterranean islands iii) Identifying key biological interactions and ecosystem functions Since functional diversity is oten correlated with island area, isolation index, elevation and island age, it appears desirable to confront these aspects with a various range of insular conditions. Processes of interactions among organisms are related to ecosystem services that plants provide. But there are too few studies linking biodiversity of a community to ecological function and the delivery of ecosystem services for Mediterranean islands. Most of the works concern the biology of plants on large oceanic islands (eg. Bramwell & Caujapé-Castells, 2011), and there is indeed a serious need to identify the main functional drivers of biodiversity loss for continental and small Mediterranean islands because the magnitude of processes will be highly diferent among islands. he diversity of Mediterranean island situations should facilitate their integration as laboratories of testing grounds of extinction in relation to global change and human pressures. A worrying case is related to the disproportionate and detrimental efects of biological invasions on small islands. Despite several research projects, it appears still necessary to better evaluate the links between native species diversity and invasion by alien species and their consequences on ecosystem functions. Insular systems have probably sufered from several dramatic losses of community function incurred by species extinction, especially on trophicoversimpliied small islands that exhibit particularly low resilience. But very few studies have taken into account the magnitude of biological interactions for rare or threatened taxa, whereas this represents proactive research to mitigate mutual disruptions or species extinction. herefore, future research should identify key processes of biological interactions, quantify the loss of functional diversity and estimate the biogeography of functional diversity loss. iv) Considering the spatial congruence between biodiversity levels and protected areas he global taxonomic diversity of insular plants is now quite well-known for the largest Mediterranean islands, but serious gaps in knowledge persist for smaller islands; precise and current plant inventories (performed according a consistent taxonomic reference) are still scarce on some archipelagos, even for medium islands. hese approaches are useful but they are not suicient. To date, most past and current conservation strategies in the world have focused on taxonomic diversity (TD) in order to protect threatened, endemic or total species. But the most widely used TD indicator, i.e. species richness, is uninformative about functional and phylogenetic diferences among 339 he unique nature of Mediterranean island loras and the future of plant conservation species, whereas phylogenetic diversity (PD) and functional diversity (FD) are both recognized as important components of biodiversity, respectively for ensuring ecosystem functioning and for assessing an evolutionary history of conservation interest (Diaz et al., 2007). Phylogenetic diversity (PD) represents the accumulation of evolutionary adaptations in a group of species and may be related to evolutionary potential of those species. It is also oten positively correlated with ecosystem function such as primary productivity (Cadotte et al., 2009). Measuring PD in species assemblages appears to be a way to explain the role of species interactions and biogeographic history in community structures and composition. his refers to the fast-growing ield of ecophylogenetics (Mouquet et al., 2012). Functional diversity (FD) relects the diversity of morphological, physiological and ecological traits within communities and is a way to explain ecosystem functioning. Plant traits determine where a species can live, how species interact with one another and the contributions of species to ecosystem functioning. herefore, recent results highlight the need for efective conservation planning measures that rely not only on the maintenance of species, but also on functional and evolutionary processes at diferent scales, and that incorporate multiple and complementary conservation indicators (Pio et al., 2011). Gap analyses are also necessary to evaluate the proportion of each biodiversity component included and excluded from existing protected area networks. Areas of mismatch and congruence between biodiversity and protected areas will allow for the evaluation of short-term eiciency of current conservation policies and should include the deep uncertainties linked to global change on insular systems. Some proposals for the future monitoring and conservation of Mediterranean islands’ plants and habitats i) Developing long-term monitoring in relation to global change Because of an increase in key threats across the Mediterranean region (Underwood et al., 2009) and the detrimental consequences of climate change here (Klausmeyer & Shaw, 2009), it appears increasing necessary to observe, monitor, and analyse vegetation and plant biodiversity changes through ecological and biogeographical gradients. Networking long term research sites and observation plots should become an integral part of biodiversity management and this monitoring must be coupled with functionaldemographic studies, such as the analysis of consequences induced by extreme 340 Islands and plants: preservation and understanding of lora on Mediterranean islands climatic events on the recruitment of keystone tree species (Matías et al., 2011), or relict and threatened plants (eg. Hampe & Arroyo, 2002). Mediterranean islands, notably the small ones, form favourable sites for these long-term biodiversity observations and monitoring at various spatial scales. Since the ecological consequences of global changes are highly complex, “natural insular microcosms” constitute indeed relevant systems to study adaptation to climate change of taxa or communities. As proposed by the Small Mediterranean Islands Initiative (PIM), a network of “Sentinel islands” where environmental and biological parameters would be censused using common methodologies, could allow a better understanding of the rate of environmental change, in order to mitigate biodiversity loss (Renou, 2012). ii) Needs for a global insular ecology framework and to develop / reinforce cooperative networks In the context of the biome crisis of the Mediterranean basin (Hoekstra et al., 2005), islands constitute key biological systems to ensure both the preservation of plant biodiversity and the sustainable development of human activities. Because the most important changes in lora, vegetation and insular landscapes are, and will be, induced by human practices, the only sustainable solution depends on a systemic and interdisciplinary approach of biodiversity conservation considering the diverse socio-economic trajectories of each island. herefore, it is necessary to develop ambitious integrated programmes taking into account biodiversity and ecosystem preservation, human well-being, and socio-economic trajectories as stated in the Millenium Ecosystem Assessment (Wong et al., 2005). To perform integrated island systems management, a global ecology perspective is needed in order to prioritise actions in relation to the unicity and vulnerability of insular biodiversity but also according to the high economic vulnerability of Mediterranean islands (structural handicaps, low diversiication of production, and high exposure to international and local luctuations). It would be relevant to combine reactive approaches on the most threatened (oten largest) islands, and proactive approaches on relatively less threatened islands (notably small islands and islets). From a biological and socioeconomical point of view, it is necessary to launch international programmes to go beyond strict administrative frontiers. Ecologists and land-managers have to better consider the biogeographic dimension of insular biodiversity by developing trans-national actions of conservation biogeography deined as the « Application of biogeographical principles, theories, and analyses, being those concerned with the distributional dynamics of taxa individually and collectively, 341 he unique nature of Mediterranean island loras and the future of plant conservation to problems concerning the conservation of biodiversity » (Whittaker et al., 2005). Cooperative networks between insular stakeholders should be implemented, notably between the European conservationists and those from the southern and eastern part of the Mediterranean. hese tasks could be performed on a global biogeographical scale and on the island scale (Table 2). he Small Islands Initiative (PIM) of the French Coastal Protection Agency (“Conservatoire du Littoral”) is a good example of this kind of international network between scientists and site managers of these insular microcosms (Renoud, 2012). here was also an IUCN plant specialist group devoted to Mediterranean island plants (Montmollin & Strahm, 2005). Unfortunately, this group is going to be included within a larger one devoted to the whole Mediterranean region, but it would be important to maintain in the future some “insular speciicity” for this IUCN/ SSC group. Otherwise, as for species, IUCN launched a few years ago a global process to establish a Red List criteria for threatened ecosystems (Rodríguez et al., 2011), and this risk assessment system should be implemented between Mediterranean islands of the same biogeographical unit. For Mediterranean Europe, European projects, notably LIFE projects devoted to habitat and plant conservation, should be implemented like those successfully established in Crete (hanos & Fournaraki, 2013) or in Minorca (Cardona et al., 2013). On the island scale, several interesting tools exist on some islands, and they could be beneicial in other insular conditions: (i) the concept of plant micro-reserves (PMRs) proposed by the Generalitat Valenciana in 1993 is a relevant implementation to protect taxa with a limited distribution, notably narrow endemics. his was already performed in Western Crete (7 PMRs) and on several Croatian islands, and this approach is ongoing in Minorca (24 PMRs are selected according to Fraga et al., 2013) and in Cyprus (5 PMRs); (ii) the French coastline conservation authority “Conservatoire du Littoral”, created in 1975, is an eicient structure to purchase coveted coastal sites that become inalienable. In Corsica, 68 sites have already been acquired, representing more than 18,000 hectares and 295 km of coasts, i.e. 20% of the coastline of the whole island; (iii) under the French environment ministry, the network of the National Botanical Conservatories (“Conservatoires botaniques nationaux”) constitutes an eicient organisation devoted to the knowledge and the conservation (both in-situ and ex-situ) of local lora. In Corsica, the “Conservatoire botanique national de Corse” created in 2008, has undertaken several important actions in particular to increase the botanical knowledge of this highly heterogeneous island and to preserve the native lora. If insular systems still represent fascinating ecological systems, they also form 342 Islands and plants: preservation and understanding of lora on Mediterranean islands key entities to disentangling the role of environmental versus human pressures for the long-term maintenance and conservation of these biodiversity hotspots. herefore, due to their unicity and fragility, Mediterranean islands, even the smallest ones, urgently need comprehensive and ambitious conservation planning for the long-term preservation of this outstanding biotic heritage. If we consider with Ricklefs & Cox (1978) that «Each island population is an evolutionary unit with ecological changes occurring independently on each», conserving the unique lora of the Mediterranean islands constitutes a disproportionate and highly complex task, but of major priority. Insular biogeographical scale To perform an inter-island analysis of conservation priorities (with common databases), including comparative perspectives of territorial dynamics between islands To establish a IUCN Red List evaluation of threatened insular ecosystems at the relevant biogeographical scale To develop the PIM initiative together with an Important Plant Areas (IPAs) programme devoted specifically to the Mediterranean islands To develop European (LIFE) or transMediterranean projects for biogeographical conservation of insular plants and habitats between islands Island scale To include some medium-sized islands within the MAB Biosphere Reserve network (eg. the Gozo case in Malta) To develop integrative conservation frameworks between scientists and stakeholders To establish networks of insular Plant MicroReserves (PMRs) To extend some efficient national initiatives: - Protected coastal areas of the Conservatoire du Littoral in France - National botanical conservatories Table 2. 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In: Robert, T. Watson, R.T., Zakri, A.H. (eds.). Millennium Ecosystem Assessment. Ecosystems and human well-being: current state and trends, Volume 1. Island Press, Washington DC, p. 663-689. Whittaker, R.J., Fernández-Palacios, J.M. 2007. Island biogeography: ecology, evolution, and conservation. 2nd edn. Oxford University Press, Oxford. 350 II Abstracts Islands and plants: preservation and understanding of lora on Mediterranean islands 351 he unique nature of Mediterranean island loras and the future of plant conservation 352 Islands and plants: preservation and understanding of lora on Mediterranean islands TECTONIC EVOLUTION OF THE MEDITERRANEAN DURING THE CENOZOIC Gerardo de Vicente1,2 Dpto. Geodinámica. F.C. Geológicas. Universidad Complutense de Madrid Instituto de Geociencias, IGEO, CSIC-UCM. Spain 1 2 he Mediterranean palaeogeography during Cenozoic times is exposed through the description of the tectonic features of the Aegean domain (Hellenic arc-trench system and Anatolian peninsula escape and extension of the AegeanWest-Anatolian region), the Central Mediterranean domain (Calabrian arc, Apennines and the Sicily Channel) and the Iberian domain (he Iberian microcontinent and the Betic-Balearic orogen). Deserving special attention is the reconstruction of the Western Mediterranean Subduction (WMSZ) and its relation to large displacements of the Balearic Islands, Corsica and Sardinia islands during the Tertiary. he type and characteristics of active stresses around the Mediterranean region, and their relationship with the seismic level of the area are then described. A further highlight is the opening and closing of marine gateways (Gibraltar, Marmara) that have played an important role in the Neogene and Quaternary history of the Mediterranean. Keywords: geology, marine gateways, Aegean, Central Mediterranean, Western Mediterranean, Iberian Gerardo de Vicente, Departamento de Geodinámica, Facultad de Ciencias Geológicas, Universidad Complutense de Madrid, C/ José Antonio Novais, 2, Ciudad Universitaria, 28040 Madrid (gdv@geo.ucm.es) 353 Abstracts THE EXCLUSIVE VASCULAR FLORA OF SARDINIA: UPDATE AND CONSERVATION ACTIONS G. Bacchetta, G. Fenu & E. Mattana Centro Conservazione Biodiversità (CCB), Dipartimento di Scienze della Vita e dell’Ambiente, Università degli Studi di Cagliari, v.le Sant’Ignazio da Laconi, 13, 09123 Cagliari (Italy). Sardinia is the second-largest island in the Mediterranean Sea and its isolation and high geological diversity have created a wide range of habitats with high levels of endemism, especially on its mountain massifs, where there are conditions of ecological insularity. In this study the exclusive endemic lora of Sardinia has been updated and it consists of 167 taxa, 139 of which are species, 23 subspecies, 4 varieties and 1 hybrid, belonging to 37 families and 72 genera. Despite this rich biodiversity and the threats to these species, few biological conservation studies have been carried out. herefore the “Regione Autonoma della Sardegna” funded in 2007 a conservation project for the most threatened exclusive endemic species of Sardinia. To categorize these species to be conserved, a priority list was created by applying 11 parameters based on rarity, threats and protection status. his work allowed the most threatened species of the Sardinian endemic lora to be identiied. Keywords: Endemics, IUCN, Mediterranean island, population monitoring, seed-banking, threatened vascular lora. Gianluigi Bacchetta (bacchet@unica.it) 354 Islands and plants: preservation and understanding of lora on Mediterranean islands CONSERVATION AND MANAGEMENT OF THE FLORA AND VEGETATION OF CRETE Costas A. hanos1 & Christina Fournaraki2 Faculty of Biology, National and Kapodistrian University of Athens Mediterranian Plant Conservation Unit, Mediterranean Agronomic Institute of Chania (MAICh) 1 2 Crete, the ith largest island of the Mediterranean, is a well known hotspot of plant diversity as a result of both its longstanding isolation from the Greek and Anatolian mainlands and its great variety of habitats and climates. It hosts 1,742 vascular plant species (ca. 2000 taxa) and shows a considerably high degree of single island endemism (159 species, 9.1%). On the other hand, the Greek lora is among the richest in Europe and the Mediterranean basin and comprises (according to a recently compiled checklist) 6,041 species (or 6,912 taxa); Greek endemics amount to 1,224-1,442 taxa, with an overall endemism at the country level in the range 17.7-20.9% (or 15.1-17.6% at species level). he contribution of the Cretan lora to the Greek one amounts to 28.8% while, among the 13 loristic regions of Greece, Crete and Karpathos is second (next to Peloponnese) in absolute number of Greek endemics and irst in local endemics. Furthermore, out of the 26 plant taxa growing in Greece (all of them angiosperms) that have been included as priority species in Annex II of the Directive 92/43/EEC, 8 plants are Cretan endemics, representing 5% of the total number of 158 embryophytes (among which 110 in the Mediterranean biogeographical region) of European priority on a continental level (while 17 taxa of Crete in total are among the 63 Greek plants included in the various annexes of the Habitats Directive). In the two Red Data Books of Greek lora (1995, 2009), Crete is represented by a signiicant number of threatened taxa (110 – of which 68 are Cretan endemics – out of a total of 476, or 23.1%); however, it is believed that this number will be at least doubled (on both island and country level) when the conservation status assessment is completed for the entire lora. Habitat diversity is also extremely rich in Crete, as illustrated by the long list of European habitat types (mapped by the Project LIFE94/NAT/GR/001201); 44 habitat types (among which 6 priority ones out of a total of 72 priority habitats for the entire European Union) are found within the boundaries of the 28 SCIs of Crete, which along with the 26 SPAs comprise 30-35% of the total 355 Abstracts land surface of the Island. Despite the legal proclamation of 54 protected areas for the Natura 2000 network in Crete, it is very unfortunate that a Management Authority has only been established in a single area, GR4340008 – Leka Ori, the largest mountainous wilderness of Crete, which also includes the Samaria Biosphere Reserve (Samaria Gorge) currently eiciently managed by the Forest Directorate of Chania. Several national and a few European projects have been implemented for the in situ plant and habitat conservation in Crete: LIFE95/NAT/GR/001143 (5 sites in western Crete), LIFE98/NAT/GR/005264 (Vai Palm Forest), LIFE99/NAT/ GR/006497 (Rouvas Forest), LIFE04/NAT/GR/000105 (*3170 Mediterranean temporary ponds), LIFE04/NAT/GR/000104 (6 priority plants and *9370 Palm groves of Phoenix) and LIFE07NAT/GR/000296 (*2250 Dune juniper thickets [Juniperus spp.]). In addition, through several national and European projects (e.g. ENSCONET, GENMEDOC, SEMCLIMED), ex situ conservation of ca. 200 Cretan plants has been achieved by safeguarding seed collections in the Seed Banks of MAICh and NKUA (accompanied by the elaboration of detailed germination protocols). Keywords: loristics, endemics, priority species, habitat diversity, LIFE projects Costas A. hanos, Faculty of Biology, National and Kapodistrian University of Athens, Panepistimiopolis, Athens 15784, Greece (cthanos@biol.uoa.gr) 356 Islands and plants: preservation and understanding of lora on Mediterranean islands THE FLORA OF CYPRUS: DIVERSITY, THREATS AND CONSERVATION Costas Kadis Frederick University, Nature Conservation Unit Cyprus hosts a great variety of habitat types. his is due to the varied environmental conditions, which can meet the speciic needs of a large number of plant species. So far, 1,978 taxa have been identiied, out of which 145 are endemic to Cyprus. he most important loristic areas of Cyprus are the Troodos mountain range and the Pendadaktylos range, which host 94 and 60 endemic plants of Cyprus, respectively. Many of the plant species of Cyprus are considered rare since they form few and small populations. he survival of many of these species is under immediate threat due to external anthropogenic pressures, such as urbanization, development (golf courses, tourism, etc.), military activities within natural areas, changes in agriculture, expansion of the mountainous road network, introduction of invasive species, climate change, etc. According to the Red Data Book of the Flora of Cyprus, which evaluates the conservation status of the Cyprus lora based on the criteria set by the IUCN, 23 taxa are characterized as Regionally Extinct, 46 as Critically Endangered, 64 as Endangered, 128 as Vulnerable, 45 as Data Deicient and 15 as Near hreatened. Moreover, 18 taxa are included in Annex II of the EU Habitats Directive, and require the establishment of protected areas for their conservation, and 26 taxa are included in Appendix I of the Bern Convention and are characterized as Strictly Protected. Over the last 20 years, several initiatives have been developed focusing on the conservation of the lora of Cyprus. hese include the ratiication of relevant legislation (e.g. the adoption of the EU Habitats Directive), the preparation and implementation of management plans for the Natura 2000 sites of Cyprus and the implementation of a series of projects focusing on the in situ and ex situ conservation of endemic, rare and threatened plants of Cyprus. Keywords: Cyprus lora, endemic species, plant conservation Costas Kadis, PhD, Associate Professor, Dean of the School of Education, Head of Nature Conservation Unit, Frederick University, P.O. Box 24729, 1303 Nicosia, Cyprus (pre.kc@it.ac.cy) 357 Abstracts FLORA OF THE ADRIATIC ISLANDS Toni Nikolić Department of Botany, Division of Biology, Faculty of Science, University of Zagreb he eastern Adriatic coast, besides the Greek coast, is one of the most diverse in the Mediterranean area. here are 1,151 islands, islets and reefs, and 80 additional reefs periodically appear above the sea level, depending on tides. During the Pleistocene the Adriatic basin was strongly inluenced by the Ice Ages. he recession and elevation of the sea level signiicantly inluenced the coastlines, causing various levels of island isolation and diferent encirclement for endemism development. For approximately 250 islands the lora is well known, but for the rest, the data is mostly incomplete or the lora is barely known. SAR extrapolation (Species-Area Relationships) shows that for the whole area of all Croatian islands (approximately 3300 km2), up to 2,600 species were estimated. he same models show that for the whole Mediterranean area along the east Adriatic coast (approximately 17,250 km2) the number of species comes to more than 4,000 taxa. From this total number of endemic taxa from within the Croatian Mediterranean area, there are 244 endemic taxa (66%), and the proportion of these endemics per island varies from 0% up to 28.6%. To deine the areas of particular botanical value, the Important Plant Area (IPA) concept is used. Using IPA criteria the total of 94 IPAs were identiied in Croatia with a total area of 9,543 km2, i.e., 17% of the country’s territory. he smallest land area covers only 0.022 km2 (island of Jabuka), and the largest as many as 2,013 km2 (Velebit mountain), while 75% of IPAs cover an area up to 100 km2. 66% of IPAs in Croatia are located in the Mediterranean area deined in a wider sense (i.e. including mountain chains in very close vicinity). In the majority of IPAs (60%) biodiversity threats and negative trends can be observed. Direct appliance of the National Ecological Network and Natura 2000 network in preparation, together with regular application of related legislation could favor the possibility of preservation. Keywords: diversity, lora, Adriatic islands, endemism, important plant area Toni Nikolić, Department of Botany, Division of Biology, Faculty of Science, University of Zagreb, Marulićev trg 9a, HR-10000 Zagreb, Croatia (toni@botanic.hr) 358 Islands and plants: preservation and understanding of lora on Mediterranean islands AEGEAN ISLAND FLORA AND ENDEMISMS Pinelopi Delipetrou Department of Botany, Faculty of Biology, National and Kapodistrian University of Athens he Aegean Sea is a continental archipelago with c. 1300 islands and islets ranging from 100 m2 to 8,260 km2. Regarding phytogeography, it includes 5 main insular loristic regions (North, West and East Aegean, and the Cardaegean area of the Kyklades and Kriti) and several islands, which belong to 2 mainland loristic regions (Peloponnisos and Sterea Ellada). Isolation time varies among the islands, from 9–10 mya to 1.8 mya, but some islands were isolated as recently as 10,000 years ago whilst others are oceanic (never connected to land). he extant lora and endemisms are the result of these complex paleogeographical circumstances, the rugged geomorphology and geographic position surrounded by 3 continents as well as the extensive human presence on the islands. he Aegean is one of the most studied areas in Greece and plant collectors and botanists have been compiling surveys since the 18th century, with a key study being the Flora Aegaea by K.H. Rechinger published in 1943. However, there are still some gaps in the loristic knowledge of the islands: there are complete loras for 41 out of the 145 larger islands (≥100 Km2) and for 185 out of more than 1000 islets. he insular loristic regions host 1600 – 2400 plants species each and endemism levels range from 1% (N Aegean) to 8% (Cretan Area). In total, the Aegean is home to c. 600 species (800 taxa) which are endemic to Greece, of which c. 380 species (580 taxa) are endemic to the Aegean only. On a regional loristic scale, simple area adequately explains total species numbers but not endemic species numbers, while species area curves indicate higher endemism in insular than in mainland regions in Greece. On an insular scale, both total and endemic species richness are signiicantly correlated to island area, but are driven by diferent biogeographical factors. here is adequate data for the conservation status of c. 800 of the Aegean plants (620 of them Greek endemics). According to such data, in the Aegean there are 242 threatened and 340 rare or near threatened plants. For most, the threat is mainly related to their highly restricted distribution. Tourism development and grazing and its management are identiied as the main causes of the decline of plant populations. Legal protection is quite adequate, including international conventions and national law. Moreover, the National List of Natura 2000 sites in Greece includes a total of 73 SCIs in the Aegean (25 of them on the 359 Abstracts largest islands of Evvoia and Kriti). However, the examples of actual in situ management for conservation and of application of the legal provisions are few. Keywords: Natura 2000, endemism, threats, conservation status, loristics Pinelopi Delipetrou, Department of Botany, Faculty of Biology, National and Kapodistrian University of Athens, Panepistimiopolis, GR-15784 Athens, Greece (pindel@biol.uoa.gr) 360 Islands and plants: preservation and understanding of lora on Mediterranean islands BALEARIC AND TYRRHENIAN FLORA AT THE BOTANICAL GARDEN OF BARCELONA Miriam Aixart Sahun & David Bertrán Chavarria Jardí Botànic de Barcelona Introduction and objectives he Botanical Garden of Barcelona possesses Mediterranean plant collections from around the world. Its main objectives include the preservation and documentation of Catalonia’s natural heritage and that of other surrounding territories. We take care of the plant collections in the garden and/or the seed bank and we try to study their growing patterns. he plants are grouped according to the ive Mediterranean regions of the world, and within these areas, the plants are separated by their ecological ainity, i.e., they represent the natural landscapes. One of these areas is the Mediterranean Basin, the lands that surround the Mediterranean Sea. And one of the landscapes that we try to represent is called “Balearic Island and Tyrrhenian lora rock crevice community.” Balearic and Tyrrhenian rock crevice community lora A calcareous rock formation contains a representation of the most frequently found plants and endemic species from the coast, scrublands, oak forests and high mountains of the Balearic Islands. he predominant species in coastal areas are Astragalus balearicus and Launaea cervicornis, while holm oak predominates in the scrub and low woody species from the Lamiaceae and Leguminosae families, as well as many geophytes. In our landscape we have many Balearic and Tyrrhenian endemisms like: Dracunculus muscivorus, Erodium reichardii, Paeonia cambessedesii, Digitalis minor, Femeniasia balearica and Lysimachia minoricensis, among others. Germination tests In the seed bank of the Botanical Garden we have been testing if there are germination diferences between diferent species of hypericum growing on the Iberian Peninsula and the endemic hypericum of the Balearic Islands. Keywords: Balearic-Tyrrhenian lora, botanical garden, endemism, germination, hypericum Miriam Aixart Sahun, Banc de Llavors, Jardí Botànic de Barcelona, C/ Doctor Font i Quer, 2, 08038 Barcelona (maixart@bcn.cat) 361 Abstracts ENVIRONMENTAL RESTORATION ACTIVITIES IN THE SCIS OF BINIMEL·LÀ AND ES ALOCS WITHIN THE LIFE + RENEIX PROJECT Eva Cardona Pons, Mireia Comas Casademont, Pere Fraga i Arguimbau, Irene Estaún Clarisó, Carme Garriga Sintes, M. Josepa González Piris & Josep Guardia Pons LIFE+ RENEIX project, Island Council of Menorca he main goal of the LIFE+ RENEIX project is to recover four deteriorated areas that hold some communities of interest and priority species of the Menorcan lora included in the Habitats Directive. All of them are found within the Natura 2000 Network area on the island. Two of those areas, Es Alocs and Binimel·là, on the north coast, are threatened by severe degradation processes. Both areas underwent substantial change when projects to develop these areas began in the 1970s. Fortunately, these projects were not carried out, and the construction of more than 4,000 apartments was interrupted. Four decades later, the degradation persists in both areas, now caused also by motor vehicles of the established roads, the practice of motocross and pressure from tourism. his is the framework of the LIFE+ RENEIX project, which includes the recovery of both areas. Hence, some of the scheduled activities are the restitution of original geomorphology, the recovering of ancient dry stone structures to mark out paths using traditional techniques, and the recovery of original plant communities. Beyond the island of Menorca, the results and experiences of this project may have an added value for other Mediterranean regions. he combination of landscape and habitat restoration with threatened plant species management and a wide social implication in activity can give to this project an innovative scope. Keywords: LIFE Nature, Menorca, habitat restoration, priority species, Eva Cardona Pons, Consell Insular de Menorca, Plaça de la Biosfera, 5, 07703 Maó, Menorca, Illes Balears, Spain (eva.cardona@cime.es) 362 Islands and plants: preservation and understanding of lora on Mediterranean islands THE LIFE + RENEIX PROJECT AND SOCIAL AWARENESS ABOUT THE PRESERVATION OF BIODIVERSITY IN MENORCA Eva Cardona Pons, Irene Estaún Clarisó, Pere Fraga i Arguimbau & Mireia Comas Casademont LIFE+ RENEIX project, Island Council of Menorca One of LIFE Nature projects’ main goals is to raise social awareness on major issues and preservation objectives on which they operate. he LIFE+ RENEIX project aims to provide the basis for ecological restoration of natural sites on the island that have been diminished due to several attempts for development, road opening, excessive human pressure and proliferation of motor vehicle access. herefore, in order to achieve increased awareness among the general population, we have focused on two major aspects: irstly, to prevent the misuse of the natural environment (i.e. motor vehicles of the established roads, the practice of motocross, excessive pedestrian pressure, etc..), and secondly, to promote increased awareness among the general population regarding the value of the biodiversity and ecosystem services it provides, and the need to recover, maintain and protect unique natural areas on the island which have undergone signiicant pressure since the 1970s. Some of the scheduled activities are the dissemination of project objectives and results through a website and the publishing of educational materials, creating educational botanical routes, developing speciic campaigns to raise motorcyclists’ awareness and involving the general population in the habitat restoration taking part in volunteer activities. Keywords: LIFE Nature, Menorca, habitat recovery, social awareness, involvement Eva Cardona Pons, Consell Insular de Menorca, Plaça de la Biosfera, 5, 07703 Maó, Menorca, Illes Balears, Spain (eva.cardona@cime.es) 363 Abstracts THE RECOVERY OF THE PAS D’EN REVULL UNDER THE LIFE+ RENEIX PROJECT Mireia Comas Casademont, Pere Fraga i Arguimbau, Eva Cardona Pons, Irene Estaún Clarisó, Carme Garriga Sintes, Josep Guàrdia Pons & Maria González Piris LIFE+ RENEIX project, Island Council of Menorca One of the areas covered by the LIFE+ RENEIX project is the Pas d’en Revull, which is a stretch of the Camí Reial, an ancient route that once connected the two main villages of the island until the eighteenth century, which runs through the Algendar gorge. his is one of the most famous scenic spots on the island, originated following signiicant karstic activity. It holds a high diversity of habitats and species in a conined space, in addition to human inluence since ancient times. he recovering of the Pas d’en Revull has been carried out to restore the ancient dry stone wall structures that delimit and protect this area, using the traditional techniques of dry stone wall construction, and posting signage along the route in order to raise awareness on the ecological and botanical values of the area and fulill the important role of social awareness that can be developed in this area. Diferent social groups and volunteers from the municipality of Ferreries, who are concerned about the conservation of this unique trail, have taken an active role in the process of clearing and recovery. Keywords: LIFE Nature, Menorca, habitat restoration, dry stone wall, social awareness, involvement Mireia Comas Casademont, Consell Insular de Menorca, Plaça de la Biosfera, 5, 07703 Maó, Menorca, Illes Balears, Spain (life.reneix@cime.es) 364 Islands and plants: preservation and understanding of lora on Mediterranean islands LEAF SHAPE VARIATION IN TWO SYMPATRIC RUPICOLOUS SPECIES OF HELICHRYSUM (ASTERACEAE) FROM THE BALEARIC ISLANDS, ASSESSED BY GEOMETRIC MORPHOMETRY Miquel Àngel Conesa1, Maurici Mus1 & Josep Antoni Rosselló2,3 Departament de Biologia, Universitat de les Illes Balears, Palma de Mallorca, Spain. Jardí Botànic, Universitat de València, c/Quart 80, E-46008, València, Spain. 3 Marimurtra Bot. Garden, Carl Faust Fdn., PO Box 112, E-17300 Blanes, Catalonia, Spain. 1 2 he selection of useful morphological traits to discern closely related species has not always succeeded, especially when qualitative characters are scarce, like with the western Mediterranean Helichrysum sect. Stoechadina. he Balearic endemic H. crassifolium (L.) D. Don, is a rather variable species in terms of leaf size and shape, and it is frequently diferentiated from the remaining taxa of this section based on ambiguous qualitative traits and on leaf width measurements. hus, the goals of this study are (i) to characterize leaf morphological variation between the two rupicolous species of Helichrysum in the Balearic Islands: the endemic H. crassifolium and the sympatric and widespread Mediterranean H. pendulum (C. Presl) C. Presl, to ascertain to what extent leaf shape is a good taxonomic feature to discriminate between these rupicolous species; and (ii) to outline the underlying causes in the observed leaf variation. A geometric morphometric approach was used to characterize leaf size and shape of both species, using Relative Warp Analysis. Both species were sampled in the entire distribution area in the Gymnesic islands, and linear and geometric morphometric measurements were correlated between species. Also, morphology was correlated towards several climatic variables from each sampled locality using two-block partial least squares analysis. Results show that there is a continuous range of leaf variation between H. crassifolium and H. pendulum, besides both species can be discriminated depending on leaf traits. Variation between populations of either or both species do not respond to abiotic factors. Recurrent natural hybridization events do however seem to better explain this situation. Also data suggest that other Helichrysum species are involved in such hybridization events. herefore, the preservation of the endemic H. crassifolium must be linked to the preservation of the whole genus species of the Archipelago. 365 Abstracts Keywords: Balearic Islands, geometric morphometrics, Helichrysum crassifolium, Helichrysum pendulum, leaf variation, natural hybridization. Miquel Àngel Conesa Muñoz, Departament de Biologia, Universitat de les Illes Balears, Carretera de Valldemossa, km 7,5. E-07122, Palma de Mallorca, Illes Balears, Spain (ma.conesa@uib.es) 366 Islands and plants: preservation and understanding of lora on Mediterranean islands THE CONTRIBUTION OF THE E+M / PESI PROJECTS TO THE VASCULAR FLORA OF THE MEDITERRANEAN ISLANDS Gianniantonio Domina & Francesco M. Raimondo Dipartimento di Scienze ambientali e Biodiversità e Orto Botanico dell’Università di Palermo. he Euro+Med PlantBase (http://www.emplantbase.org) has provided an updated and critically evaluated on-line database and information system for the vascular plants of Europe and the Mediterranean region. he irst stage of this project was funded by the European Union under Framework V, for three years (2000-2003). he irst result was a rough taxa list with detailed distribution including the major strictly Mediterranean islands, the Canary islands, the Azores and Madeira, but never completely checked above all for extra European territories. his list has been critically reviewed in part by editors and appointed experts by certain countries or groups. One of the irst tangible results of this project was the publishing of Med-Checklist vol. 2, which includes the treatment of the Compositae for all Mediterranean countries. Under the Euro+Med PlantBase project, 62 families have been conirmed. he review of the remaining families is currently being done with the support of the PESI. PESI (http://www.eu-nomen.eu) is a three-year project, started in May 2008, funded by the European Union within Framework VII. Led by the University of Amsterdam, PESI comprises 40 partner organizations from 26 countries in the ields of botany, zoology, mycology and phycology. PESI is intended to facilitate access to taxonomic information using standardized records of names and synonyms for the beneit of experts responsible for the management of biodiversity in Europe. PESI coordinates the integration of various taxonomic and nomenclatural systems in use in Europe and involves the establishment of a common interface to allow users to get the information they need. A key element of this initiative is the critical evaluation of the database. A mechanism for interregional cooperation enables the gradual review of the taxonomy of families, genera, species and subspecies described in the EuroMediterranean region. Currently, 140 families make up only around the 85% of the whole lora. Keywords: Checklist, databasing, nomenclature. Gianniantonio Domina, Dipartimento di Scienze ambientali e Biodiversità e Orto Botanico dell’Università, via Archirai, 38. I-90123 Palermo (gdomina@unipa.it) 367 Abstracts ENDANGERED TAXA OF THE SICILIAN FLORA AND CONSERVATION PERSPECTIVES Gianniantonio Domina, Vivienne Spadaro, Giuseppe Bazan & Francesco M. Raimondo Dipartimento di Scienze ambientali e Biodiversità e Orto Botanico dell’Università di Palermo Sicily is one of the phytodiversity hotspots in the Mediterranean area. Its lora includes 322 strictly endemic species and 180 taxa shared with some nearby territories (9.91% and 5.54% of the entire lora, respectively). his without considering several taxa for which Sicily represents their southern or western distribution boundary. Several of them occur in few or a single populations oten limited to a restricted area. Some species have already been the subject of speciic studies (Abies nebrodensis, Betula aetnensis, Brassica sp. pl., Calendula maritima, Cytisus aeolicus, Petagnaea gussonei, Silene hicesiae, Zelkova sicula). Others, recently discovered or taxonomically re-evaluated, are still deicient in an accurate monitoring. Examples are: Acinos minae, Adenostyles alpina subsp. nebrodensis, Anthyllis hermanniae subsp. sicula, Centaurea erycina, C. saccensis, Erica sicula subsp. sicula, Hieracium sp. pl., Isoetes todaroana, Ptilostemon greuteri, Rhamnus lojaconoi; a majority being data deicient regarding population size and trends necessary to deine the IUCN categories. he occurrence of protected areas (Natural parks and reserves) plays an important role in in situ conservation of these taxa. But this action is oten only indirect since local managers are unaware of the rarities to be protected. So these taxa need speciic conservation projects starting from a careful population study. Taking into account the low number of individuals, in several cases ex situ conservation interventions are needed including micropropagation techniques starting from cell cultures. Particular attention must be paid to popular sciences to inform public opinion about plant diversity richness in their area and its fragility. he Department of Environmental Science and Biodiversity (formerly Botanical Sciences) of the University of Palermo has been working for several years in this direction organizing round tables and meetings also in peripheral structures (the Laboratory Sistema Madonie and the Nebrodi Seedbank). Keywords: Sicily, micropropagation, popular science. Gianniantonio Domina, Dipartimento di Scienze ambientali e Biodiversità e Orto Botanico dell’Università, via Archirai, 38. I-90123 Palermo (gdomina@unipa.it) 368 Islands and plants: preservation and understanding of lora on Mediterranean islands GERMINATION BEHAVIOUR OF FIVE THREATENED ENDEMIC PLANT SPECIES FROM WESTERN MEDITERRANEAN ISLANDS AND COASTAL CLIFFS M.C. Escribá, I. Ferrando, P.P. Ferrer, F. Albert, A. Navarro & E. Laguna CIEF (Centro para la Investigación y la Experimentación Forestal). he CIEF’s Germplasm Bank of Valencian Wild Flora evaluates the germination rates (G) of ive steno-Mediterranean (SM) or Iberian-Balearic (IB) endemic plant species living on islands, and strictly protected (PR) by the Valencian Community (Spain) laws: Diplotaxis ibicensis (IB, PR), Lavatera mauritanica (SM, unprotected), Medicago citrina (IB, PR), Reseda hookeri (SM, PR) and Silene hifacensis (IB, PR). Seeds were collected on the Columbretes Islands and along the complex of plant microreserves placed on small islands and coastal clifs of north-eastern Alicante. Germination protocols have followed the current ISTA rules. Seeds were sown in a sterile environment provided by a laminar lux chamber, using Petri dishes (9 cm in diameter), and two Albet ilter papers, damped with distilled water up to saturation level. Each lot held 4 replication plates holding 25 seeds per dish. he germination tests where made using an incubator chamber programmed to hold several culture conditions: 10/20ºC, 20ºC, 15ºC y 10ºC, with balanced photoperiod (12/12h light/shade). Only Reseda hookeri shows low germination values, maximum G=3% at 15 and 10ºC (T50=39±22,63 and 41.6±0.70 days for n=7 diferent tests). Diplotaxis ibicensis reached G=96±3,23% at 10/20ºC , T50= 8,23±0,38 (n=3). Both for M. citrina and L. mauritanica, the maximum values are obtained at 20ºC: G=90±8,3% (T50=3,1±0,95; n= 3) in Medicago and G=83±13,22% (T50=4,67±0,53; n=3) in Lavatera. In the case of S. hifacensis (n=32), germination rate was from G=58±12,4 to 100%, except for 2 accessions only yielding G=5% -apparently caused by immature seeds. On the germination speed the extreme values obtained ranged between T50=2,58±0,53 (at 20ºC; G=98±2,3%) and 16,25±1,7 (at 10/20ºC; G=79±8,8%); the average value for the whole treatment was 5,74±0,54 days (n=32). Except for the Critically Endangered Reseda hookeri, the results show that the insular threatened species usually have good and quick germination response under controlled conditions. Keywords: Germination, Endemic species, Endangered Species, Mediterranean islands, Valencian Community. Emilio Laguna, CIEF, Servicio de Biodiversidad, Generalitat Valenciana, Avda. Comarques del País Valencià 114, E-46930 Quart de Poblet, Valencia, Spain (laguna_emi@gva.es) 369 Abstracts EXPERIENCIES AND RESULTS OF THE CONSERVATION OF PLANT SPECIES THROUGH LIFE NATURE PROJECTS IN MENORCA Irene Estaún Clarisó, Eva Cardona Pons, Mireia Comas Casademont, Carme Garriga Sintes & Pere Fraga i Arguimbau LIFE + RENEIX project, Island Council of Menorca LIFE Nature projects focus on the conservation of habitats and species within the Nature 2000 network. hese projects should be understood not only as proposals developed within a limited period of time , but also as a starting point of conservation and management that should persist beyond the project itself. Required follow-ups, such as the Post-LIFE action plan, are clearly related to the longer-term duration of the project’s objectives. In the particular case of Menorca, a retrospective examination of the results achieved by three consecutive LIFE Nature projects, more or less related to plant conservation, can be seen as an example of continuity of objectives and goals ater the formal completion of each one. LIFE2000NAT/E/7355 (http://lifelora.cime.es) was devoted to long-term management of those plant species on Menorca included in the Habitats Directive. Diferent actions were carried out including the elaboration of individual management and investigation plans into the threats and conservation needs of these species. Noteworthy intervention within this project was the eradication of the invasive alien species Carpobrotus, which has become a demonstrative case study of alien plant control within a whole territory. LIFE05/NAT/ES/000058 (www.cime.es/lifebasses) had as its main objective the conservation and management of Mediterranean temporary ponds, a priority habitat that stands out for the high diversity of plants it supports, most of them restricted to this type of habitat and rare within their distribution range. Some outstanding features of this project were the use of traditional techniques to restore and preserve such habitats and the cooperation of landowners and stakeholders. Some actions of the project are still ongoing and positive results have been clearly achieved with preservation of local populations and habitats. LIFE07NAT/E/000756 (http://lifereneix.cime.es) is currently being developed and is focused on the restoration of complex areas that hold a high diversity of habitats and species. Some results, mainly regarding social participation, are already visible. 370 Islands and plants: preservation and understanding of lora on Mediterranean islands Keywords: LIFE Nature, invasive species, habitat conservation, biodiversity, long-term management Irene Estaún Clarisó, Consell Insular de Menorca, plaça de la Biosfera, 5, 07703 Maó, Menorca, Illes Balears, Spain (life.reneix@cime.es) Fig. 1. Binimel·là, on the north coast of Menorca, is one of the areas of environmental restoration of the LIFE07NAT/E/000756 project. 371 Abstracts CARTOGRAPHY OF RIPARIAN VEGETATION AND ASSESSMENT OF ITS ECOLOGICAL STATUS IN MENORCA (WESTERN MEDITERRANEAN, SPAIN). Sònia Estradé Niubó1, Rafel Quintana Fortuny1, Alexandre Franquesa i Balcells1, Pere Fraga Arguimbau2, Eva Marsinyach Perarnau1, Catalina Pons Fábregas1 & David Carreras Martí1 Social and Environmental Observatory of Menorca (OBSAM)-Institut Menorquí d’Estudis. 2 Island Council of Menorca. 1 he riparian vegetation has an important function in the maintenance of a good ecological status of rivers and streams: stabilization of river banks, maintenance of water quality and water low, habitats for aquatic species, and maintenance of biological diversity are some of its main functions. he mapped area corresponds to a bufer of 100 meters along 19 primary streams in Menorca using phytosociological classiication. he cartography of the vegetation communities shows that the streams and the associated vegetation have been modiied and altered. he largest area covered in the riparian zone contained in a bufer of 30 meters is farmland. he riversides are occupied by farming and pastures in 45% of the total bufer surface, 29% are forest climax communities: Prasio-oleetum (wild olive maquis), CyclaminiQuercetum ilicis (holm oak forest) or mixed forest, and 8% is Rubo-Crataegetum brevispinae (bramble patch). he bufers of 10 meters are still mainly occupied (28%) by farmland and pastures, another 28% are forest climax communities and Rubo-Crataegetum brevispinae increases its percentage, in this case 17%. he riparian climax communities are less abundant but of high value. Tamaricetum represents 3,4% of the bufers of 10 meters. Priority habitats of European interest, Scirpetum maritimo-litoralis and hypho-Schoenoplecteteum tabernaemontani represent 3.2% and 1.8% respectively. In 2.3% of the surface of those bufers we ind Arundo donax, a community with strong invasive power. he presence of European interest and protection, threatened and high interest species like Vitex agnus-castus, Alisma plantago-aquatica, Eleocharis palustris, Iris pseudacorus and Aristolochia rotunda among others is remarkable. hus most of the stream banks are extremely humanized. In many cases, farming to the edge of the riverbed and mechanical clearing have almost completely removed the vegetation. he canalization and excavation of the riverbeds, along with the ephemeral conditions of the streams, make the 372 Islands and plants: preservation and understanding of lora on Mediterranean islands settlement of vegetation with higher water demand diicult. he abundance of bramble highlights that the riparian vegetation is deteriorated, and the vegetal cover is dominated by secondary communities with an important presence of invasive species. Particularly alarming is the presence of Arundo donax. Keywords: riparian vegetation, priority habitats of European interest, invasive species. References Llorens, Ll., Gil, Ll. & Tébar, F.J. 2007. La vegetació de l’illa de Mallorca. Bases per a la interpretació i gestió d’hàbitats. Govern de les Illes Balears. Bolós, O. 1996. La vegetació de les Illes Balears. Comunitats de plantes. Institut d’Estudis Catalans. Sònia Estradé Niubó, Observatori Socioambiental de Menorca (OBSAM) - Institut Menorquí d’Estudis, Camí des Castell, 28, 07703 Maó, Menorca, Illes Balears, Spain (sig.obsam@cime.es) 373 Abstracts THE HERBARIUM GENERALE MINORICAE I. Fernández Rebollar1, S. Pons Fábregas1, P. Fraga i Arguimbau1, C. Mascaró Sintes2, D. Carreras Martí1, O. Garcia Febrero1, X. Pallicer Allès2, M. Pons Gomila2, M. Seoane Barber2 & M. Truyol Olives1 1 2 Institut Menorquí d’Estudis, Camí des Castell, 28, 07702 Maó, Menorca GOB-Menorca, Camí des Castell, 53, 07702 Maó, Menorca Ater the historic Rodríguez Femenías Herbarium, now preserved in the Institut Menorquí d’Estudis, the Herbarium Generale Minoricae (HGM) is the second most important botanical collection of vascular plants that is carried out on the Balearic island of Menorca. his herbarium was founded in 1999 by the initiative of the Commission of Botany, belonging to the Balearic Ornithological Group (GOB) in Menorca, and the Institut Menorquí d’Estudis, in response to the need for a basic tool for further study and knowledge of the island’s lora. From its inception, it has seen steady growth with some peaks of activity that have taken the HGM to house currently 1,031 records that include 577 diferent taxa distributed in 309 genera and 83 families of vascular plants, mostly native to Menorca. All these records are fully computerized using the new 3.7 version of HERBAR, an application sotware designed by Francisco Pando of the Royal Botanical Garden of Madrid, which has been adopted as standard by the AHIM (Association of Ibero-Macaronesian Herbariums) and which is recommended and supported by the Spanish Node of GBIF (Global Biodiversity Information Facility). his fact perfectly matches with one of the main future goals of the HGM: to introduce this collection of vascular plants in the large database of the GBIF network with the aim of providing adequate dissemination and international relevance. Beyond the digitization of the collection, currently the management and conservation tasks of the HGM also includes a labeling process of the diferent documents that contain the specimens recorded. Once labeled, these documents will be stored in boxes already arranged alphabetically by families and genera. Meanwhile the HGM collection continues to grow thanks to the research and collecting work of the Commission of Botany’s scientists. Keywords: Herbarium, Menorca, HERBAR, computerization, GBIF Iván Fernández Rebollar, Observatori Socioambiental de Menorca (OBSAM), Institut Menorquí d’Estudis (IME), Camí des Castell, 28, 07702 Maó, Menorca, Illes Balears, Spain (agro.obsam@cime.es) 374 Islands and plants: preservation and understanding of lora on Mediterranean islands MANAGEMENT OF ENDANGERED PLANT SPECIES WITHIN THE LIFE+ RENEIX PROJECT Pere Fraga i Arguimbau, Irene Estaún Clarisó, Eva Cardona Pons, Mireia Comas Casademont & Carmen Garriga Sintes LIFE+ RENEIX project, Island Council of Menorca he long-term management of habitats and plant species is a main objective of the Habitats Directive of the European Union. Menorca, like other Mediterranean islands, has a signiicant endemic lora with plant species of narrow distribution that likely require legal protection to assure successful conservation. Moreover, it is well known that in most cases the conservation of a single species cannot be implemented with positive results without taking into account the whole habitat where it grows. Under this premise, some years ago a LIFE Natura proposal (LIFE 2000NAT/E/7355) was developed in order to manage Menorca’s endangered plant species. Unlike other projects, LIFE+ RENEIX (LIFE07 NAT/E/000756) proposes to proceed with conservation from a comprehensive approach - that is, considering the whole context where targeted plant species are growing. hus, in the island’s particular case, this means not only developing actions designed to work on individuals (i.e. reinforcing populations, increasing knowledge about ecology, control of speciic threats), but also working in a multidisciplinary fashion: preceding situation, habitat restoration, social awareness, etc. In order to clarify actions and results, four areas of the island have been selected that have the following common features: a high concentration of habitats and plant species of conservation interest, the presence of active threats that urgently need restoration actions and can be easily recognized by locals and tourists. With this approach it is expected that the project will develop with evident positive results, not only on plant species included in the Habitats Directive, but also on many others that are of interest for conservation due to their narrow distribution (endemic) or to their signiicance for locals. Taken together, these experiences and results may be exportable to other regions with similar problems of habitat and species conservation. Keywords: LIFE+ RENEIX, Habitats Directive, Menorca, endemic lora, habitat restoration, species conservation Pere Fraga i Arguimbau, Consell Insular de Menorca, Plaça de la Biosfera, 5, 07703 Maó, Menorca, Illes Balears, Spain (pfa.life@cime.es) 375 Abstracts NEW PLANT SPECIES RECENTLY DESCRIBED IN THE FLORA OF MENORCA: THE IMPORTANCE OF NEGLECTED HABITATS Pere Fraga i Arguimbau1 & Josep A. Rosselló2,3 LIFE+ RENEIX project, Island Council of Menorca Jardín Botánico, ICBiBE, Universidad de Valencia 3 Marimurtra Bot. Garden, Carl Faust Fdn. 1 2 he islands of the Mediterranean area are usually considered to be among the richest points of conservation interest, as they hold a high concentration of unique and restricted biodiversity among their autochthonous lora. Endemicity on insular territories can be related, besides insularity itself, to other factors favoring plant diferentiation like mountain ranges, geological diversity and soil singularities or harsh environmental conditions. In the particular case of Menorca, despite the absence of tall mountains (the maximum altitude is 350 m a.s.l.), some particularities like extreme environmental conditions caused mainly by persistent, strong north winds and a diversiied geology seem to be the major forces driving local speciation processes. Recently, a group of up to four new species have been described from habitats sharing several common environmental features, viz Bellium artrutxensis, Coronilla montserratii, Euphorbia nurae and Polycarpon dunense. hey grow on sandy calcareous soils derived from coastal sand dune systems, but with a diferent degree of consolidation. hus, they range from small patches of mobile sands of inland progressing dune systems (e.g., P. dunense) to thin sandy soils originated by erosion of fossilized limestone dunes (e.g., B. artrutxensis and E. nurae). Soil characteristics of these habitats favor a vegetation of small annual plants with a high degree of species diversity, showing some physiognomic similarities with Isoetes communities of sandy siliceous soils. What is shown ater years of studying these miniature grasslands is that even habitats apparently are not favourable for speciation they can hold diferent plant communities. Some of them can be linked to very local environmental conditions that are singular and thus favor plant diversiication and ultimately speciation. Keywords: sandy soils, speciation, Bellium, Coronilla, Euphorbia, Polycarpon Josep Antoni Rosselló, Jardí Botànic, Universitat de València, C/ Quart, 80, 46008 València, Spain (josep.rossello@uv.es) 376 Islands and plants: preservation and understanding of lora on Mediterranean islands FOREST HABITAT MAP OF MENORCA 2007. A TOOL FOR FOREST MANAGEMENT AND BIODIVERSITY PRESERVATION A. Franquesa Balcells1, D. Carreras Martí1, A. Canals Bassedas2 & M. Truyol Olives2 Institut Menorquí d’Estudis LIFE+ BOSCOS project, Consell Insular de Menorca 1 2 LIFE+ BOSCOS (LIFE+07ENV/E/000824) is a project developed by the Menorcan government (CIMe) with the co-funding of the European Union’s LIFE+ program, which aims to develop tools and sustainable management strategies to deal with climate change efects on Mediterranean forests. A new forest habitat map of Menorca (the second largest island of the Balearic Islands) has been developed at the Institut Menorquí d’Estudis (IME), as an analysis and management tool to deine forest management guidelines for the adaptation to climate change, as well as to simplify and facilitate forest planning on both local and regional levels. his Forest Habitat Map of Menorca is currently the most detailed habitat map (scale 1:25000) ever made in Menorca and one of the irst in the Iberian Peninsula. he map focuses exclusively on forest habitats and covers 51% of island’s surface (358 km2). he map uses two of the most widely used habitat classiications: (1) the Habitat types of Community Interest developed by Council directive 92/43/CEE and listed under Interpretation Manual of European Union Habitats (version EUR27), as well as (2) the Corine biotopes developed by EU CORINE program’s CORINE Biotopes project. he map has been digitalized using Geographic Information System’s techniques and has also been extensively validated by ield campaigns (over 40% of its surface has been visited). he resulting cartography includes 30 diferent forest habitats (according to CORINE Biotopes project classiication) distributed in nine Habitat types of Community Interest. he map contains almost 4,000 landscape units, each of which holds a maximum of three diferent habitats. hanks to its detail and thoroughness, the forest habitat map will be a helpful tool when drating the guidelines for forest management of Menorca and, at the same time, will allow drawing forest management plans of the properties of the island. Keywords: Mapping, forest habitat, Habitat types of Community Interest, HIC, CORINE Biotopes Project, Menorca, LIFE+ Alexandre Franquesa, OBSAM-IME, C. des Castell, 28, 07702 Maó, Menorca, Spain (carto.obsam@cime.es) 377 Abstracts ENDANGERED PLANT SPECIES OF MARETTIMO ISLAND (SICILY, ITALY) Lorenzo Gianguzzi, Dario Cusimano, Pasquale Cuttonaro & Vincenzo Ilardi Department of Environmental Biology and Biodiversity, University of Palermo Marettimo Island (Egadian Archipelago, NW Sicily), unlike the surrounding areas of Levanzo and Favignana, and also of Sicily itself, has not been afected by the Quaternary glaciations (Francini & Messeri, 1956), hence the vegetation physiognomy is quite diferent; we could just think of e.g. the Rosmarinus oicinalis and Erica multilora macchia-garrigue, very common here, but residual elsewhere and located within restricted geographical areas. he peculiarity of lora, represented by 612 infrageneric taxa (Gianguzzi et al., 2006), is the result of the vicissitudes that have afected phytogeographic lows in this sector of the Mediterranean Sea. here are diferent endemic species, some of which paleoendemic, or entities of phytogeographic signiicance, with small populations and therefore “at risk”. he study investigates these entities, highlighting the problems related to their conservation. Among the exclusive endemic species to the Island, there are Allium franciniae, Helichrysum errerae var. messerii, Limonium tenuiculum, Bupleurum dianthifolium, Oncostema hughii, hymus richardii subsp. nitidus and Anthemis secundiramea var. cosyrensis; a species endemic to the Egadian Archipelago (Brassica macrocarpa). Moreover, many other taxa are to be mentioned: some of them are endemic to Sicily, i.e. Asperula rupestris, Bellevalia dubia, Euphorbia papillaris, Plantago afra subsp. zwierleinii, Pseudoscabiosa limonifolia and Ranunculus spicatus subsp. rupestris, or to the Central Mediterranean area, such as Crocus longilorus, Dianthus rupicola subsp. rupicola, Iberis semperlorens, Pimpinella anisoides, etc. Many other plants are absent or very rare/threatened at a regional level, such as Aristolochia navicularis, Daphne sericea, Erodium maritimum, Lagurus ovatus subsp. vestitus, Periploca laevigata subsp. angustifolia, Reichardia tingitana, Simethis mattiazzi, hymelaea tartonraira, etc. Other entities, rather frequent on the nearby Sicilian coast, retain only one or few relict stations in Marettimo, e.g. Hedera helix, Teucrium fruticans, Chamaerops humilis, Phillyrea latifolia, Cyclamen hederifolium, Ephedra fragilis, locally represented by very few individuals, for which therefore protection actions would be necessary. 378 Islands and plants: preservation and understanding of lora on Mediterranean islands Keywords: Vascular lora, conservation of species, Marettimo Island (Channel of Sicily), phytogeography. References Francini E., Messeri A. 1956. L’Isola di Marettimo nelle Egadi e la sua vegetazione. Webbia, 11 [1955]: 607–846. Gianguzzi, L., Scuderi, L., Pasta, S. 2006. La lora vascolare dell’Isola di Marettimo (Arcipelago delle Egadi, Canale di Sicilia): aggiornamento ed analisi itogeograica. – Webbia 61 (2) 359-402. Lorenzo Gianguzzi, Department of Environmental Biology and Biodiversity, University of Palermo, Via Archirai, 38, 90123 Palermo, Italy (gianguzz@unipa.it) 379 Abstracts INVESTIGATIONS INTO THE DISTRIBUTION OF FLORISTIC EMERGENCIES OF PANTELLERIA ISLAND (CHANNEL OF SICILY, ITALY) Lorenzo Gianguzzi, Dario Cusimano, Pasquale Cuttonaro & Salvatore Romano Department of Environmental Biology and Biodiversity, University of Palermo Pantelleria Island is the emerged part of an imposing volcano that rises along the “contact rit” between Africa and Europe. It’s dominated by Montagna Grande summit (836 m), followed by Monte Gibele (700 m) and other inactive volcanic cones. According to the most recent contributions, the vascular lora is composed of approximately 600 infrageneric entities (Brullo et al., 1977; Gianguzzi, 1999a, 1999b), a rather small number compared to the territory surface area, being due to its young geological age and to geographic isolation in the Channel of Sicily. his study focuses on the loristic emergencies of the island, which include several endemic species, all neogenic, among which are exclusive: Limonium cosyrense, Matthiola incana subsp. pulchella, Medicago truncatula var. cossyrensis, Trifolium nigrescens subsp. nigrescens var. dolychodon and Serapias cossyrensis. Among other endemic species, which are present in nearby areas, are the Anthemis secundiramea var. cosyrensis, Filago lojaconoi and Senecio leucanthemifolius subsp. crassifolius. here are, furthermore, several elements of certain phytogeographical signiicance, almost all from the South, like Pinus pinaster subsp. hamiltonii, Periploca laevigata subsp. angustifolia, Genista aspalathoides, Carex illegitima, Andryala rothia subsp. cossyrensis, Limodorum trabutianum, Ophrys sphegifera, Brassica insularis, Tillaea alata, etc. Among the most vulnerable biotopes, for their peculiarity and limited distribution, are fumaroles and “Specchio di Venere” lake. In the fumarolic series it is possible to ind rare species, such as Radiola linoides, Kickxia cirrhosa, Isoetes duriei and Ranunculus parvilorus. Along the sides of “Specchio di Venere”, located within a calderic depression, there is Schoenoplectus litoralis s.l., whose insular population is considered critical, in addition to the very rare Limonium secundirameum, considered seriously threatened. On this basis, therefore, the factors of the human pressure on the biotope are not to be neglected, especially pronounced during the summer, becoming one of the most signiicant threats. 380 Islands and plants: preservation and understanding of lora on Mediterranean islands Keywords: Vascular lora, conservation of species, Pantelleria Island (Channel of Sicily), phytogeography. References Brullo, S., Di Martino, A, Marcenò, C. 1977. La vegetazione di Pantelleria (Studio itosociologico). – Pubbl. Ist. Bot. Univ. Catania, pp. 111. Gianguzzi, L. 1999b. Vegetazione e bioclimatologia dell’Isola di Pantelleria (Canale di Sicilia). – Blanquetia, 22: 1-70 + 1 carta (scala 1:20.000). Gianguzzi, L. 1999a. Il paesaggio vegetale dell’Isola di Pantelleria. – Collana Sicilia Foreste 8, Azienda Foreste Demaniali della Regione Siciliana, pp. 192. Palermo. Lorenzo Gianguzzi, Department of Environmental Biology and Biodiversity, University of Palermo, Via Archirai, 38, 90123 Palermo, Italy (gianguzz@unipa.it) 381 Abstracts PHYLOGEOGRAPHY OF QUERCUS COCCIFERA S.L. IN THE MEDITERRANEAN BASIN M. Guara1, M.J. Ciurana1, E. Laguna2, A. Aguilella3, F. Boisset1, R. Currás1, P.P. Ferrer2, A. Marzo2, J. Pedrola4, M.F. Puche1 & I. Mateu-Andrés4 Departamento de Botánica, Universidad de Valencia CIEF, Generalitat Valenciana 3 ICBIBE, Jardín Botánico, Universidad de Valencia 4 ICBIBE, Departamento de Botánica, Universidad de Valencia 1 2 In the context of compared phylogeography of Mediterranean species, Quercus coccifera L. is studied through cpSSR markers. Plant material was collected in 66 natural populations from around the Mediterranean Basin, including the most relevant archipelagos. Five out of the six universal primers tested were variable with a total of 18 diferent alleles, giving 34 haplotypes. A map of haplotypes in the sampled populations is presented. he analysis using Permut sotware shows high levels of genetic variability and structure (Rst = 0.982 > Gst = 0.87, p = 0.000). Two AMOVA analyses were performed based on geographical and bayesian distribution. In the irst, most of the variability (65.5%) was among groups, being lower among populations within groups (33.4%), while in the second analysis both of them were similar (50.6% and 45.6%, respectively). Bayesian analysis with BAPS sotware distributed the populations into 3 groups, one of them (37 populations, 11 haplotypes), found mainly in the west of the Mediterranean Basin, and the Cyrenaic region, the second one in the Middle East, Turkey and Cyprus (13 populations, 11 haplotypes) and the third (16 populations, 13 haplotypes) present in most of the main islands (except Cyprus), Southern France, Balkans and Northern Africa (Argelia and Tunisia). All these results, together to the haplotypes network constructed with TCS sotware, suggest 2 diferent migration routes from the Iberian Peninsula where the basal haplotype is located, one through the SiculoTuniasian Strait and the other one through Northern Africa to the Middle East and Turkey. Keywords: Quercus coccifera, Kermes oak, cpSSR markers, phylogeography, migration routes Author for workshop presentation: Dr. Emilio Laguna, CIEF, Generalitat Valenciana, Avda. Comarques del País Valencià, 114, E-46930 Quart de Poblet, València (laguna_emi@gva.es) Main author for post-congress correspondence: Dr. Miguel Guara, Departamento de Botánica, Universidad de Valencia, C/ Dr. Moliner 50, E-46100 Burjassot, Valencia, Spain (miguel.guara@uv.es) 382 Islands and plants: preservation and understanding of lora on Mediterranean islands IN SITU CONSERVATION STRATEGIES OF A THREATENED SPECIES: THE CASE OF CAREX PANORMITANA GUSS. IN SICILY Vincenzo Ilardi, Dario Cusimano, Lorenzo Gianguzzi & Salvatore Romano Department of Environmental Biology and Biodiversity, University of Palermo Carex panormitana Guss. (Cyperaceae) is a species distributed in Sicily and Sardinia, which, according to Arrigoni (1984), represents a neoendemic vicariant of Carex acuta Good. In Sicily it can only be found in one place in the north-west, near Palermo. his rhizomatous geophyte, sciaphiloushygrophilous, typical of river banks, is a species of community interest listed in the Habitats Directive 92/43/EEC under annex II as priority species and under annex IV; it is also found on a national red list (Conti et al., 1997), indicated as vulnerable (VU), unlike the Sicilian subpopulation considered threatened (Raimondo et al., 1994). Carex panormitana is actually located in the downstream section of the Ponte delle Grazie in the Oreto river, whose station is also the locus classicus of the species. According to the investigation carried out, the subpopulation, rather fragmentary, is particularly threatened with extinction. he main causes of this threat are three: 1 - Extreme simpliication of the original river morphology with straightening of the river channel and deletion of bends, meanders, river beds, etc. 2 - Signiicant reduction of radiation under the canopy, since the ripisilva oten tends to occupy the entire loodplain area; this leads to a change in the habitus of the species, from heliophilous to sub-sciaphilous. 3 - Eutrophication of water body, as result of the urbane sewage from the upstream areas. In order to elaborate a speciic plan for the in situ conservation of the considered subpopulation, preventing its further regression, which could also lead to the extinction in the medium term, we suggest the following actions: 1 - restoration of the typical riverine morphology of the terminal stretch of the river; 2 - periodic cleaning interventions of the riverbanks, aimed at the restoration of the typical environmental balance of Carex panormitana; 3 - reduction of organic load. 383 Abstracts Keywords: Oreto River (Palermo), Habitats Directive 92/43/EEC, Conservation of species, Phytogeography. References Arrigoni, P.V. 1984. Le piante endemiche della Sardegna. – Boll. Soc. Sarda Sci. Nat. 23: 225-228. Raimondo, F.M., Gianguzzi, L., Ilardi, V. 1994. Inventario delle specie “a rischio” nella lora vascolare nativa della Sicilia. Quad. Bot. Ambientale Appl., 3 (1992): 65132. Conti, F., Manzi, A., Pedrotti, F. 1997. Liste Rosse Regionali delle Piante d’Italia. – WWF Italia. Società Botanica Italiana. Università di Camerino. Camerino. 139 pp. Vincenzo Ilardi, Department of Environmental Biology and Biodiversity, University of Palermo, Via Archirai, 38, 90123 Palermo, Italy (vincenzo.ilardi@unipa.it) 384 Islands and plants: preservation and understanding of lora on Mediterranean islands ESTABLISHMENT OF A PLANT MICRO-RESERVE NETWORK IN CYPRUS FOR THE CONSERVATION OF PRIORITY SPECIES AND HABITATS Costas Kadis1, Christina Pantazi2, Takis Tsintides3, Charalampos Christodoulou3, Minas Papadopoulos3, Costas A. hanos4, Kyriacos Georghiou4, Constantinos Kounnamas1, Constantinos Constantinou1, Marios Andreou1 & Nicolas-George Eliades1 Nature Conservation Unit, Frederick University Dep. of Environment, Ministry of Agriculture, Natural Resources and Environment 3 Dep. of Forests, Ministry of Agriculture, Natural Resources and Environment 4 Dep. of Botany, Faculty of Biology, National and Kapodistrian University of Athens 1 2 he project titled ‘Establishment of a Plant Micro-reserve Network in Cyprus for the Conservation of Priority Species and Habitats’ (PLANT-NET CY) is implemented under the EU LIFE+ programme. Its main objective is to improve the conservation status of four priority plant species and two priority habitat types of the EU Habitats’ Directive that are found exclusively in Cyprus, through the establishment, monitoring and management of a network of ive Plant MicroReserves (PMRs). he PMRs approach was initially developed about 15 years ago in Valencia (Spain) and since then it has been successfully implemented in several other parts of Europe. his concept is now widely accepted as one of the most efective practices towards the conservation of plant diversity in small land areas that are of peak value in terms of plant richness, endemism or rarity. he project introduces an integrated approach for the conservation of the targeted species and habitats through monitoring of all environmental parameters afecting the targeted species and their habitats, implementing speciic in situ conservation actions, implementing complementary ex situ conservation actions and promoting public awareness and controlled public involvement in the conservation activities. he project is expected to secure the protection and sound management of the targeted species and habitats and increase the participation of local people/stakeholders in the design and implementation of conservation initiatives. Moreover, PLANT-NET CY brings together scientists who have been involved in the PMRs approach over the last 15 years to facilitate networking and exchange of scientiic information and best practices. Keywords: Plant Micro-Reserves, priority species, priority habitats, plant conservation, Cyprus. C. Kadis, Frederick Univ., 7 Yianni Frederickou St., Pallouriotissa, 1036, Nicosia, Cyprus. (pre.kc@it.ac.cy) 385 Abstracts ENDEMIC TAXA OF ASPERULA L. SECT. CYNANCHICAE (DC.) BOISS. ON THE MEDITERRANEAN ISLANDS Tamara Kirin¹, Marco Cosimo Simeone¹, Sandro Bogdanović² & Bartolomeo Schirone¹ ¹Dipartimento Ambiente e Foreste (D.A.F.), Università della Tuscia ²Department of Botany and Botanical Garden, Faculty of Science, University of Zagreb Recent research on molecular phylogeny (based on cpDNA) of the family Rubiaceae conirmed that the genus Asperula is not monophyletic (Soza & Olmstead, 2010). Asperula L. sect. Cynanchicae (DC.) Boiss consists of approximately 60 taxa with a hotspot of diversity in the Adriatic and Aegean Basin. Around the Adriatic Basin several endemic taxa of the Asperula sect. Cynanchicae ser. Paleomediterraneae have been recorded based on morphological, caryological ecological and geographical diferences. he most interesting taxa are those that belong to the Asperula staliana complex (Korica, 1979, 1981, 1986, 1992) such as A. staliana, A. woloszczakii, A. visianii, A. borbasiana, A. staliana ssp. arenaria, A. staliana ssp. issaea, A. staliana ssp. diomedea. Morphologically closely related taxa are A. garganica, A. calabra, A. crassifolia from the Apennine peninsula, A. deiciens from Sardinia, A. pauii from Balearic Islands (Peruzzi et al. 2004), A. gussoneii and A. peloritana from Sicily (Brullo et. al 2009), A. naufraga and A. samia from Greek islands (Ehrendorfer & Guterman, 2000, Christodoulakis & Georgiadis, 1983), A. suberosa from Northern Greece and A. idea from Crete (Schönbeck-Temesy & Ehrendorfer 1991). Geographical vicinity and punctiform distribution of these taxa in the Mediterranean makes the story of their diversiication especially interesting. he main goal of this research is to solve taxonomic incongruences among endemic taxa, discover species-area biogeographic relationships between islands and main lands (Italian and Balkan peninsula), and assess their genetic diversity as well as phylogenetic relationships. Phylogenetic relationships were inferred from plastid DNA sequences (trnH-psbA and matK) and nuclear sequences (ITS). Tested populations were sampled on some Croatian islands and in Italy. Preliminary results indicate the existence of great variability among the investigated taxa. We found interesting patterns of inter-/intra-speciic polymorphism which will be further assessed in future research involving taxa from Greece and other Mediterranean islands. 386 Islands and plants: preservation and understanding of lora on Mediterranean islands Keywords: Asperula sect. Cynanchicae, phylogeny, endemism, trnH-psbA, matK, ITS References Korica, B. (1986). Endemične svojte srodstvene skupine Asperula staliana (Rubiaceae) Jadranskih otoka. PhD hesis, JAZU 424 (21), p. 357 – 400. Brullo, C., Brullo S., del Galdo G.P.G., Scuderi L. (2009). Taxonomical notes on the Sicilian populations of Asperula gussonei (Rubiaceae): A. peloritana sp. nov. Anales del Jardín Botánico de Madrid 66(1), p. 85-92. Korica, B., Lausi, D., Ehrendorfer, F. (1992). A new subspecies of the transAdriatic Asperula staliana from the Isole Tremiti: subsp. diomedea, and its ecology. Flora Mediteranea 2. p. 65-76. Christodoulakis D. & Georgiadis T. (1983). Eine neue Asperula – Art (Rubiaceae) von der Insel Samos, Griechenland. Willdenowia 13, p. 341 – 344. Peruzzi, L., Gargano, D., Passalacqua, NG. (2004). Considerazioni tassonomiche su Asperula L. sect. Cynanchicae (Rubiaceae) nell’Italia meridionale. Informatore botanico italiano 36, p. 154-157. Ehrendorfer F., Gutermann W. (2000). Asperula naufraga (Rubiaceae), a new species from Zakinthos (Ionian Islands, Greece), with notes on its ecology, karyology and relationships. (Materials towards a Flora Ionica, 1). Botanika Chronika 13, p. 61-70. Schönbeck – Temesy, E. & Ehrendorfer, F. (1991). Asperula L. In. Strid A. & Tan K.. Mountain lora of Greece (Vol. 2.), p. 281 – 300. Korica, B. (1979). Asperula visianii, nova spec., und A. staliana (Rubiaceae), Endemiten der Insel Mitteldalmatiens. Plant Systematics and Evolution 133, p. 7176. Soza, V.L. & Olmstead, R.G. (2010). Molecular systematics of tribe Rubieae (Rubiaceae): Evolution of major clades, development of leaf-like whorls, and biogeography. Taxon 59 (3), p. 755 – 771. Korica, B. (1981). Beitrag zur Kenntnis der endemischen Asperula – Sippen (Rubiaceae) der Adriatischen Inseln. Botanische Jahrbücher für Systematik 102 (1-4), p. 339 – 457. Tamara Kirin, Dipartimento Ambiente e Foreste (D.A.F.), Università della Tuscia (D.A.F.), Via S.Camillo de Lellis, 01100 Viterbo, Italy (tamara.kirin@unitus.it) 387 Abstracts WILD PHOENIX IN THE MEDITERRANEAN: PALEONTOLOGICAL AND ARCHAEOBOTANICAL EVIDENCE E. Laguna1, D. Rivera2, C. Obón3 & F. Alcaraz2 CIEF, Servicio de Biodiversidad. Generalitat Valenciana Dep. de Biologia Vegetal, Universidad de Murcia 3 Dep. de Biología Aplicada, Esc. Politécnica Sup. de Orihuela, Univ. Miguel Hernández 1 2 he number of wild palm species in the Mediterranean is restricted to Chamaerops humilis L. in numerous loras and monographs. However in the second half of the 20th century, the discovery of Phoenix theophrastii in several areas on the island of Crete (Greece), which was later found in the Aegean coasts of Turkey, and the description of Phoenix iberica from SE Spain raised the question on the origins of these palm trees and the possibility of wild palm species in the Mediterranean other than Chamaerops humilis. In addition, several Phoenix microspecies were described since the 18th century but usually considered as varieties of P. dactylifera (e.g. P. excelsior from Eastern Spain). Are these merely subspontaneous date palms escaped from cultivation which reverted to the wild phenotypes, or remnants of ancient Phoenix populations which persisted during the Holocene in refuge zones, including some Mediterranean islands? If the latter option was true, how could they participate in the domestication processes of Phoenix dactylifera along the Southern Mediterranean side? Is the similarity of the external macrocharacters and appearance amongst all these taxa the expression of local phenotypes of P. dactylifera or a possible evidence of the introgression and genetic displacement caused by this AfroAsian species on a rich group of Mediterranean taxa currently in extinction? Here we comment on the morphology of fossilized and non-fossilized remains from diferent sites and periods in the Mediterranean, Europe and North Africa, which can be compared with the extant Mediterranean Phoenix. he results here obtained advises to describe and characterize in a close future all the Mediterranean microspecies, in order to better discriminate between native and current Phoenix and their remnant morphological inluence in the P. dactylifera complex. Keywords: Phoenix theophrastii, Phoenix iberica, Phoenix dactylifera, Mediterranean palms, Paleobotany, Archaeobotany Author for workshop presentation: Dr. Emilio Laguna, CIEF, Generalitat Valenciana, Avda. Comarques del País Valencià, 114. E-46930 Quart de Poblet, València, Spain (laguna_emi@gva.es) Main author for post-congress correspondence: Dr. Diego Rivera, Departamento de Biologia Vegetal, Universidad de Murcia, Campus de Espinardo, E-30500 Murcia, Spain (drivera@um.es) 388 Islands and plants: preservation and understanding of lora on Mediterranean islands PSAMMOPHYTE VEGETATION ON THE DUNE FRONT OF ES COMÚ DE MURO (MALLORCA, BALEARIC ISLANDS). FROM CONSERVATION STATUS TO THE NEED FOR MANAGEMENT Miquel Mir-Gual & Guillem X. Pons Departament de Ciències de la Terra, Universitat de les Illes Balears he beach-dune ecosystems’ situation in the Balearic Islands is characterized by its high fragmentation, mainly due to anthropogenic pressure and the coastal management policies made by the local administration. Economic interests have prevailed over ecological ones, generating serious environmental impacts. Fragmentation signs are clear in both geomorphic and ecological features, mainly along the irst line of dune systems. Although there are many variables to consider, the ecological status should be considered as an important feature to take into account. he existing relationship among geomorphic, ecological and management conditions is vital to understand the current situation of Es Comú. In this way, it is important to observe the role that vegetation plays here. In fact, the disappearance of the herbaceous vegetation on the front line has implied a high loss of sediment, increasing the erosion rate. Hence, we propose contributing to the knowledge of the dune beach-system of Es Comú de Muro (Mallorca, Balearic Islands) by carrying out an exhaustive characterization of its ecological conditions present along its dune front, with the purpose of establishing a representative explanation of its fragmented situation through the blowout erosive shapes and fore-dune status. For this, 58 loristic inventories corresponding to each analyzed blowout have been sampled taking into account ecological variables in order to establish and propose new management tools. A Cluster analysis has been made through Bray Curtis similarity index to show the ield work results, taking into account the 19 main herbaceous species detected along the dune front. Ecological conditions are taken out from both herbaceous and bush vegetation. In fact, the geomorphologic front dune degradation has been analyzed as well, starting with the roots of Juniperus oxycedrus subsp. macrocarpa outcrops, showing a strong correlation with the system fragmentation. 389 Abstracts hus, the main species of each type have been identiied to determine their presence/absence index, distribution, and conservation state, in order to get a clear perspective about the current situation of this area, and the potential management tools suitable to apply. Keywords: beach-dune ecosystems, conservation, management, Mallorca, Balearic Islands. Miquel Mir-Gual, Departament de Ciències de la Terra, Universitat de les Illes Balears, Cra. Valldemossa, km. 7,5, Palma de Mallorca 07122 (miquel.mir@uib.es) 390 Islands and plants: preservation and understanding of lora on Mediterranean islands ECOLOGICAL QUALITY OF RIPARIAN HABITAT ASSESSMENT BY MEANS OF QBR INDEX (MUNNÉ ET AL., 2003) IN EPHEMERAL STREAMS OF MENORCA (WESTERN MEDITERRANEAN, SPAIN). Rafel Quintana Fortuny, Sònia Estradé Niubó, Alexandre Franquesa i Balcells & David Carreras Martí Social and Environmental Observatory of Menorca (OBSAM). Institut Menorquí d’Estudis (IME). In response to the increasing ecological impacts related to human activities and the greater social environmental concerns, policy-makers of developed countries are implementing initiatives aimed at reducing those impacts in aquatic ecosystems to restore water quality levels found in pristine ecological status. hus, the General Directorate of Freshwater Resources of the Balearic Islands Government, in order to implement the European Water Framework Directive (WFD; 2000/60/EC) requested that OBSAM carry out a vegetation communities cartography and a riparian habitat assessment. Riparian vegetation is contained in landscapes where terrestrial and aquatic ecosystems meet, such as streams, river banks and river loodplains, wetlands and areas surrounding lakes. Native riparian vegetation plays an important role in providing ecosystem services. hese services include stabilization of river banks, maintenance of water quality and water lows, habitat for aquatic species, and maintenance of biological diversity in remnant habitats. To assess the ecological quality of riparian areas, a visual index (QBR, Munné et al., 2003; ACA, 2006) was used. his methodology developed for Mediterranean stream catchments is based on 4 categories of riparian habitats (vegetation cover, cover structure, cover quality and channel alterations). Scores for each category range from 0 to 100, with the value 100 assigned as the highest quality and founding 5 groups. For this purpose, 19 major streams within 12 drainage basins were chosen. he streams were divided into 4 uniform geomorphological-depending categories (reaches) and each reach was divided into stretches according to fertile lowland loodplains land use. None of the streams obtained very good ecological quality; 2, good ecological quality; 6, moderate ecological quality; 8, poor ecological quality; and 1 obtained bad ecological quality. he main threats detected were riparian vegetation clearance and its replacement with pastures, animal waste, sewage input and the introduction of non-native species. 391 Abstracts Keywords: European Water Framework Directive, QBR, riparian vegetation, ephemeral streams. References Munné, A., N. Prat, C. Solà, N. Bonada, M. Rieradevall. 2003. A simple method for assessing the ecological quality of riparian habitat in rivers and streams: QBR index. Aquatic Conserv: Mar. Freshw. Ecosyst. 13: 147-163. Agència Catalana de l’Aigua. 2006. Protocol HIDRI. Protocol d’avaluació de la qualitat hidromorfològica dels rius. Rafel Quintana Fortuny, Observatori Socioambiental de Menorca (OBSAM), Institut Menorquí d’Estudis, Camí des Castell, 28, 07703 Maó, Menorca, Illes Balears, Spain (vec.obsam@cime.es) 392 Islands and plants: preservation and understanding of lora on Mediterranean islands DETAILED MAPPING OF THE DISTRIBUTION OF THE PLANT SPECIES OF INTEREST TO THE PROJECT LIFE+RENEIX IN MENORCA (PHASE I) Cristina Rosique1, Albert Ferré1, Jordi Carreras1 & Pere Fraga2 Grup de Geobotànica i Cartograia de la Vegetació (GEOVEG), Facultat de Biologia, Universitat de Barcelona 2 LIFE+ RENEIX project, Island Council of Menorca 1 We present the methodology and results of the irst phase of the detailed mapping of plant species considered of interest for the project LIFE+RENEIX (LIFE+07/NAT/E/000756). he species studied are: Anthyllis histrix, Astragalus balearicus, Cneorum tricoccon, Cymbalaria aequitriloba, Cymbalaria fragilis, Echinophora spinosa, Femeniasia balearica, Orobanche foetida (Ononis crispa parasite), Paeonia cambessedesii, Pastinaca lucida, Teucrium asiaticum, Teucrium marum, hymelaea velutina and Viola stolonifera. he areas of study are: Alocs-El Pilar, Binimel·là, Sa Mesquida-Es Murtar, Pas d’en Revull (Barranc d’Algendar). he data from the irst ield survey (conducted during the autumn of 2010) are structured in a geographic information system, in polygons and point maps. Where the populations exceed 400 m2 they have been digitized as polygons (in some cases, when it has been considered of interest and possible, a smaller minimum area has been used). he ieldwork was carried out over recent printed orthoimages in scales between 1:2,500 and 1:4,500 and the inal GIS demarcation of the polygons has been done in more detailed scales. For smaller populations or isolated individuals the mapping information is a point layer (from captures in the ield with the GPS). he database associated with the mapping contains the following information: number of individuals (adults, young, seedlings and dead), number of populations (individuals or groups of individuals), surface, conservation status (good, medium, bad) and observations. he poster describes the species found in each of the studied areas and its population data, as well as some conservation problems detected during the ieldwork. In the second phase (scheduled for 2013) the data from this irst session will be updated and the mapping of species that have not been properly studied due to their phenology (Orobanche foetida and Serapias nurrica) will be carried out. Keywords: LIFE+ RENEIX, lora of interest, GIS, detailed mapping Cristina Rosique Esplugas, GEOVEG, Departament de Biologia Vegetal, Universitat de Barcelona, Av. Diagonal, 645, E-08028 Barcelona (crristinaa@hotmail.com) http://www.ub.edu/geoveg/ 393 Abstracts SYSTEMATICS OF THE NARROW ENDEMIC SPECIES BRIMEURA DUVIGNEAUDII (HYACINTHACEAE) Llorenç Sáez1, Joan Rita2, Gabriel Bibiloni2, Cristina Roquet3, Xavier Rotllan4 & Javier López Alvarado5 Unitat de Botànica, Facultat de Biociències, Universitat Autònoma de Barcelona Departament de Biologia, Universitat de les Illes Balears 3 Laboratoire d’Ecologie Alpine, UMR-CNRS 5553, Université Joseph Fourier 4 IMEDEA-CSIC 5 Institut Botànic de Barcelona (IBB-CSIC-ICUB) 1 2 Brimeura is an endemic genus of the western Mediterranean region which includes three species: B. amethystina (L.) Salisb., endemic to the north-eastern Iberian Peninsula (mountains bordering the Ebro basin), B. fastigiata (Viv.) Chouard, endemic to Western Mediterranean islands (Corsica, Sardinia, Majorca and Menorca), and the Majorcan endemic Brimeura duvigneaudii (L. Llorens) Rosselló, Mus & Mayol. Brimeura duvigneaudii was described on the basis of specimens collected in Penyal Fumat, Formentor (northern Majorca). Intraspeciic morphological variation in B. duvigneaudii has been noted, and two groups of populations that correspond to separate areas in which plants show morphological diferences (scape and lower length) could be deined. hese diferences were attributed to phenotypic adaptations to a humid and shady microhabitat in Coma Freda karst gorge. Indeed, variation in lower features in this species has been observed by us during the last decade, which seems to be clearly related to the geographic origin of the plants. To clarify these relationships, we carried out a morphological study of Brimeura duvigneaudii (Hyacinthaceae). Morphological analyses showed noticeable variability which is correlated with geographic distribution and some ecological factors. hese data led us to propose a new subspecies of Brimeura duvigneaudii, which is endemic to a single locality from the middle range of Serra de Tramuntana. he new taxon, which has been recently described (Brimeura duvigneaudii subsp. occultata), difers from B. duvigneaudii subsp. duvigneaudii in several vegetative (leaf anatomy and leaf width) and lower features (corolla size, corolla lobe length and shape, scape length). Data on the local distribution and ecology of the new taxon have been reported. he new subspecies is restricted to a karst gorge and is in danger of extinction, due to its small population size. Keywords: Brimeura, Majorca, morphometric analysis, subspecies Llorenç Sáez, Univ. Autònoma de Barcelona, E-08193, Bellaterra, Barcelona (gymnesicum@yahoo.es) 394 Islands and plants: preservation and understanding of lora on Mediterranean islands THE THYMELAEA TARTONRAIRA (L.) ALL. VARIATION IN SARDINIA (ITALY) Malvina Urbani Dipartimento di Scienze Botaniche, Ecologiche e Geologiche, University of Sassari he hymelaea tartonraira L. All. (hymelaeaceae) is a very interesting species group and can be a good model to study morphological population variation. T. tartonraira is a Mediterranean species with a complex nature of variation diicult to deine, as already observed by Aymonin (1971, 1974). A quite varying intra speciic taxonomy was carried out by diferent authors, among them Tan (1980) and Galicia Herbada, (1995, 2006). All the Italian populations (among them Capri, Marettimo and Sardinia) are named T. tartonraira subsp. tartonraira, the main taxon of the W Mediterranean. T. tartonraira in Sardinia is a quite common species present in diferent coastal and mountain sites on sand dunes (e.g.: Porto Ferro), on consolidated sands of fossil dunes (e.g.: Porto Palmas) on rocks/clifs (e.g.: Porticciolo) and on Mesozoic calcareous lime-stones (all the mountain sites in this project). he variety of habitats and the presence of this taxon in a great number of sites, make Sardinia a good study site to test and, possibly, to quantify the morphological variation in T. tartonraira subsp. tartonraira. he objective of this study is to evaluate the intra and inter population morphological variation of nine Sardinian sites and to test the possible discontinuities among this variation. Preliminary data from morphological analysis of vegetative and reproductive structures of T. tartonraira (e.g.: leaves, lowers, fruits and seeds) are taken into account, elaborated and discussed. Keywords: hymelaeaceae, morphology, systematics. hymelaea tartonraira subsp. tartonraira, M. Urbani, Dip. di Sci. Bot., Ecol. e Geol., via Piandanna 4, 07100 Sassari, Italy (urbani@uniss.it) 395 Abstracts ESSENTIAL OIL COMPOSITION OF SOME CENTAUREA SP. (ASTERACEAE), FROM DIFFERENT ITALIAN ISLANDS L. Viegi1, A. Tava2, R. Cecotti2 & R. Vangelisti1 1 2 Department of Biology, Botany Unit, Pisa University, via L. Ghini 5, I-56126 Pisa, Italy C.R.A. - Experimental Fodder Crop Institute, viale Piacenza 29, I-26900 Lodi, Italy Introduction he genus Centaurea (Cardueae tribe, Asteraceae) contains a very large number of species (400-700) predominantly distributed in the Old World (Greuter, 2008). Several papers on secondary metabolites of Centaurea species are available in the literature (Baykan-Erel et al., 2010), a few on volatile constituents (Rosselli et al.,2009; Tava et al., 2010; Viegi et al., 2010). Objectives Taxonomically this genus is complex and warrants further study by new cytological and chemical techniques. Extending our study of Centaurea species in Italy, the aim of this research was to look into the essential oil composition of some species from diferent Italian islands. Methodology he aerial parts (fresh and dry lower heads and leaves) of Centaurea veneris (Sommier) Bég. from Palmaria island, in the Ligurian Sea, C. gymnocarpa Moris & De Not. from Capraia island, C. ilvensis (Sommier) Arrigoni and C. aetaliae (Somm.) Bég. from Elba island in the north Tyrrhenian Sea, were collected during their lowering period (April-July) in 2006 and 2007 [nomenclature follows Greuter (2006-09)]. Voucher specimens of these plants were deposited in PI (Herbarium Horti Pisani, Pisa University). For each population, a sample of 20 individuals was collected. he volatile components of all samples were obtained by hydrodistillation and identiied by GC and GC/MS. he essential oil from these four species has never previously been researched. Results and conclusion he volatile oils of the four Centaurea species contained several compounds, the most abundant of which were sesquiterpenes (34.4-61.7% of the total), followed by aldehydes (6.5-10.3%), alcohols (0.6-7.9%), monoterpenes (0.62.2%), hydrocarbons (1.7-14.7%), ketones (0.3-2.4%), acids (0.8-4.0%) and esters (0.1-4.7%). Several unidentiied compounds were also detected as in other Centaurea sp. (Tava et al., 2010; Viegi et al., 2010). he results are discussed on the basis of the taxonomical implications of these species. 396 Islands and plants: preservation and understanding of lora on Mediterranean islands Keywords: Centaurea veneris, Centaurea gymnocarpa, Centaurea ilvensis, Centaurea aetaliae, Asteraceae, essential oils References Tava A., Esposti S., Boracchia M., Viegi L., 2010. Volatile constituents of Centaurea paniculata subsp. carueliana and C. rupestris s.l. (Asteraceae) from Mt. Ferrato (Tuscany, Italy). J. Essential Oil Res, 22: 1-5. Baykan-Erel S., Bedir E., Khan I.A., Karaalp C., 2010. Secondary metabolites from Centaurea ensiformis P.H. Davis. Biochemical Systematic and Ecology, 38: 1056-1058. Greuter W., 2006-2009. Compositae (pro parte majore). In: Greuter, W. & Raab-Straube, E. von (ed.): Compositae. Euro+Med Plantbase - the information resource for Euro-Mediterranean plant diversity. Viegi L., Boracchia M., Cecotti R., Tava A., 2010. Volatile components of two endemic species from the Apuan Alps (Tuscany, Italy) Centaurea arachnoidea and C. montis-borlae. (Asteraceae). NPC Natural Product Communications, 5(8): 1285-1290. Greuter, W., 2008. Med-Checklist. A critical inventory of vascular plants of the circummediterranean countries, 2. Dicotyledones (Compositae). Eds. W. Greuter, E. von Raab-Straube. Palermo, Genève & Berlin. Rosselli S., Bruno M., Maggio A., Raccuglia R.A., Bancheva S., Senatore F., Formisano C., 2009. Essential oils from the aerial parts of Centaurea cuneifolia Sibth. & Sm. and C. euxina Velen., two species growing wild in Bulgaria. Biochemical Systematic and Ecology, 37: 426-431. Lucia VIEGI, Department of Biology, Botany Unit, Pisa University, via L. Ghini 5, I-56126 Pisa, Italy (lviegi@biologia.unipi.it) 397 Abstracts 398 Attendants Islands and plants: preservation and understanding of lora on Mediterranean islands 399 Attendants. Contact list. 400 Islands and plants: preservation and understanding of lora on Mediterranean islands Aixart Sahun, Miriam Jardí Botànic de Barcelona maixart@bcn.cat s’Albufera des Grau rborras@espaisnb.caib.es Bravo Lodeizen, José Antonio Lithica shostal@lithica.es Anglada Ferrer, Gibet bet_anglada@hotmail.com Brondo Moll, Magdalena mayalen_7@hotmail.com Bacchetta, Gianluigi Università di Cagliari. Centro Conservazione Biodiversità bacchet@unica.it Brullo, Salvatore University of Catania brullo@mbox.dipbot.unict.it Beith, Andrew Mediterrannean Garden Society ajbeith@telefonica.es Cardona Pons, Eva Consell Insular de Menorca eva.cardona@cime.es Beith, Marianne Mediterrannean Garden Society ajbeith@telefonica.es Cardona Moll, Noelia Universitat de les Illes Balears noeliacardonamoll@gmail.com Berg, Brigitte Jardí Botànic de Barcelona Carreras Martí, David Observatori Socioambiental de Menorca smn.obsam@cime.es Bertran Chavarria, David davidbertran@telefonica.net Blondel, Jacques Centre d’Ecologie Fonctionnelle et Evolutive jacques.blondel@cefe.cnrs.fr Carta, Angelino Pisa University. Dept. of Biology. Botanic Garden acarta@biologia.unipi.it Bonafonte Trench, Eloi Lithica shostal@lithica.es Castro Delisle, José Maria jose.m.castro@gmail.com Borràs Tejedor, Ricardo Espais de Natura - Parc Natural Cerdà March, Maria Antònia mariantonia86@gmail.com 401 Attendants. Contact list. Cursach Seguí, Joana Universitat de les Illes Balears joana.cursach@uib.es Biodiversità. Univ. Palermo gdomina@unipa.it Domínguez Lozano, Felipe Universidad Complutense de Madrid felipe.dominguez@bio.ucm.es Cusimano, Dario Università degli Studi di Palermo. Dipartimento di Biologia Ambientale e Biodiversità cusimanodario@yahoo.it Espinosa, Jaime Conselleria de Medi Ambient, Govern de les Illes Balears je.noguera67@gmail.com Cuttonaro, Pasquale Università degli Studi di Palermo. Dipartimento di Biologia Ambientale e Biodiversità lino.cutt@gmail.com Espinosa, Cinderita Mediterranean Garden Society cindycourey@gmail.com de Montmollin, Bertrand International Union for Conservation of Nature (UICN) montmollin@biolconseils.ch Estaún Clarisó, Irene Consell Insular de Menorca iec.cime@silme.es de Vicente, Gerardo Universidad Complutense de Madrid gdv@geo.ucm.es Estradé Niubó, Sònia Observatori Socioambiental de Menorca sig.obsam@cime.es Delanoe, Olivia INEA delanoe@inea.fr Fàbregas Carenas, Jordi Stipa Jardineria stipajardineria@vodafone.es Delipetrou, Pinelopi National and Kapodistrian University of Athens pindel@biol.uoa.gr Fabregat Llueca, Carlos Jardí Botànic de la Universitat de València cfabrega@uv.es Domina, Gianniantonio Dip. Scienze Ambientali a Fernández Rebollar, Iván Observatori Socioambiental de 402 Islands and plants: preservation and understanding of lora on Mediterranean islands Ilardi, Vincenzo Università degli Studi di Palermo. Dipartimento di Biologia Ambientale e Biodiversità vincenzo.ilardi@unipa.it Menorca agro.obsam@cime.es Fraga Arguimbau, Pere Consell Insular de Menorca pfa.life@cime.es Jury, Stephen University of Reading Biology Sciences-Harborne s.l.jury@reading.ac.uk Franquesa Balcells, Alexandre Observatori Socioambiental de Menorca carto.obsam@cime.es Kadis, Costas Fredericki University pre.kc@it.ac.cy Garcia Febrero, Óscar Conselleria de Medi Ambient, Govern de les Illes Balears oscargfebrero@gmail.com Kirin, Tamara Università della Tuscia tamara.kirin@unitus.it Garcia Roca, Vicent Universitat de les Illes Balears vgroca@gmail.com Laguna Lumbreras, Emili Generalitat Valenciana laguna_emi@gva.es Gervilla García, Cristina Universitat de les Illes Balears cristinagervilla@gmail.com Lanfranco, Sandro Dep. of Biology, University of Malta sandro.lanfranco@um.edu.mt Gianguzzi, Lorenzo Università degli Studi di Palermo. Dipartimento di Biologia Ambientale e Biodiversità gianguzz@unipa.it Levinson, Di Mediterranean Garden Society dilevinson@terra.es Homs Vinent, Francisco Javier jahovi@gmail.com Limoncelli, Marta University of Milano Bicocca marta.limoncelli@gmail.com Hugot, Laetitia National Botanic Conservatoire of Corsica hugot@oec.fr 403 Attendants. Contact list. López Alvarado, Javier Institut Botànic de Barcelona al.loja2@gmail.com Nikolic, Toni University of Zagreb toni@botanic.hr Martínez Bernárdez, Andrés Universitat de les Illes Balears andmabe@gmail.com Oliveira de Alencar, Ricardo rioparis1@hotmail.com Orbaneja Desvalls, Iñigo Predio Sant Antoni iorbaneja@hotmail.com Martorell Ramis, Marc Universitat de les Illes Balears marc.mr@hotmail.com Pallicer Allés, Francesc AL21 de Ferreries pallicerpons@terra.es Mascaró Sintes, Tòfol GOB Menorca cmascaro@gobmenorca.com Patnisa, Maria University of Ionnina, Agrinio mpanitsa@cc.uoi.gr Mateu Amengual, Antoni Universitat de les Illes Balears toni.mateu2@gmail.com Pons Buades, Guillem X. Dept. de Ciències de la Terra, Universitat de les Illes Balears guillemx.pons@uib.es Mayol Serra, Joan Conselleria de Medi Ambient, Govern de les Illes Balears Quintana Fortuny, Rafel Observatori Socioambiental de Menorca vec.obsam@cime.es Médail, Frédéric Imep, Aix-Marseille University f.medail@univ-cezanne.fr Michaud, Henri Conservatoire Botanique National Méditerranéen h.michaud@cbnmed.fr Rita Larrucea, Joan Universitat de les Illes Balears jrita@uib.es Rodríguez Calero, José josecalero2@hotmail.com Moragues Botey, Eva Conselleria de Medi Ambient, Govern de les Illes Balears emoragues@dgcapea.caib.es 404 Islands and plants: preservation and understanding of lora on Mediterranean islands hanos, Costas National and Kapodistrian University of Athens cthanos@biol.uoa.gr Rodríguez Fernández, Alfonso Universitat de les Illes Balears alfonso.jose@terra.es Romand-Monnier, Florence f.romandmonnier@yahoo.co.uk Urbani, Malvina Dip. di Sci. Botaniche, Ecologiche e Geologiche urbani@uniss.it Romano, Salvatore Università degli Studi di Palermo. Dipartimento di Biologia Ambientale e Biodiversità toto.romano@unipa.it Véla, Errol University of Montpellier errol.vela@cirad.fr Rosselló, Josep Antoni Universitat de València. Jardí Botànic Fundació Carl Faust rossello@uv.es josep.rossello@uv.es Viegi, Lucia Pisa University. Dep. of Biology, Botany Unit lviegi@biologia.unipi.it Rovira Vidal, Paula Universitat de Barcelona paularov@hotmail.com Ryan, Marcus Lambley Nursery marcus@red-fox.com.au marco@ballarattelco.net.au Schwartz-Tzachor, Rachel Ramat Hanadiv racheli@ramathanadiv.org.il Sintes Carreras, Eladio Universitat de les Illes Balears eladiosintescarreras@gmail.com 405 Attendants. Contact list. 406 Author index Islands and plants: preservation and understanding of lora on Mediterranean islands 407 Author Index 408 Islands and plants: preservation and understanding of lora on Mediterranean islands Estradé, S. ............................ 372, 391 Fabregat, C................................... 297 Fenu, G. ........................................ 354 Fernández, I................................. 374 Ferrando, I. .................................. 369 Ferré, A. ....................................... 393 Ferrer, P.P. ............................ 369, 382 Foggi, B. ...................................... 157 Fournaraki, C. ............................. 355 Fraga, P. .................91, 123, 362, 363, 364, 370, 372, 374, 375, 376, 393 Franquesa, A. ..............372, 377, 391 Garcia, O. ..................................... 374 Garriga, C. .. 123, 362, 364, 370, 375 Georghiou, K............................... 385 Gianguzzi, L. ...............378, 380, 383 Giusso, G...................................... 177 González, M.J. .............123, 362, 364 Guara, M. ..................................... 382 Guardia, J. ............................ 362, 364 Guidi, T ........................................ 157 Ilardi, V................................. 378, 383 Iliadou, E. .................................... 243 Kadis, C. ............................... 357, 385 Kirin, T. ........................................ 386 Kounnamas, C. ........................... 385 La Mantia, T. .............................. 201 Laguna, E. ........... 297, 369, 382, 388 Lanfranco, E. ............................... 261 Lanfranco, S. ............................... 261 López-Alvarado, J. ........................ 91 Marsinyach, E.............................. 372 Marzo, A. ..................................... 382 Mascaró, C. .................................. 374 Mateu-Andrés, I.......................... 382 Mattana, E.................................... 354 Mayol, J. ....................................... 105 Aguilella, A. ................................. 382 Aixart, M. .................................... 361 Albert, F. ...................................... 369 Alcaraz, F. .................................... 388 Andreou, M. ................................ 385 Baccheta, G. ................................ 354 Bazan, G. ...................................... 368 Bedini, G. ..................................... 157 Bertrán, D. ................................... 361 Bibiloni, G. .......................... 309, 394 Blondel, J. ....................................... 37 Bogdanovic, S. ............................. 386 Boisset, F. ..................................... 382 Brullo, C. ...................................... 177 Brullo, S. ..................................... 177 Canals, A...................................... 377 Cardona, E. .................123, 362, 363, 364, 370, 375 Carreras, D. ........ 372, 374, 377, 391 Carreras, J. ................................... 393 Carta, A. ....................................... 157 Cecotti, R. .................................... 396 Christodolou, C. ......................... 385 Ciurana, M.J. ............................... 382 Comas, M. ..................123, 362, 363, 364, 370, 375 Conesa, M. À............................... 365 Constantinou, C.......................... 385 Currás, R. ..................................... 382 Cusimano, D................378, 380, 383 Cuttonaro, P. ........................ 378, 380 Delipetrou, P. ............................... 359 Domina, G. .......................... 367, 368 Domínguez, F. ............................... 63 Eliades, N-G. ............................... 385 Escribá, M.C. ............................... 369 Estaún, I. .... 123, 362, 363, 364, 370, 375 409 Author Index Tava, A. ........................................ 396 hanos, C.A. ........................ 355, 385 Truyol, M. ............................ 374, 377 Tsintides, T................................... 385 Urbani, M. ................................... 395 Vangelisti, R................................. 396 Vela, E. ......................................... 271 de Vicente, G. .............................. 353 Viegi, L. ........................................ 396 Westermeier, R. ........................... 261 Xiberras, J. .................................. 261 Zammit, M-A. ............................. 261 Médail, F....................................... 325 Michaud, H.................................. 289 Mifsud, M-A. ............................. 261 Mir-Gual, M. ............................... 389 de Montmollin, B. ........................ 51 Moragues, E. ................................ 105 Mus, M. ........................................ 365 Navarro, A. .................................. 369 Nikolić, T. .................................... 358 Obón, C. ...................................... 388 Pallicer, X. .................................... 374 Panitsa, M. ................................... 243 Pantazi, C. .................................... 385 Papadopoulos, M. ....................... 385 Pasta, S. ........................................ 201 Pavon, D. ...................................... 271 Pedrola, J. ..................................... 382 Pons, C. ........................................ 372 Pons, S. ......................................... 374 Pons, M. ....................................... 374 Pons, G.X. .................................... 389 Puche, M.F. .................................. 382 Quintana, R. ........................ 372, 391 Raimondo, F.M. .................. 367, 368 Rita, J. .................................. 309, 394 Rivera, D. ..................................... 388 Romano, S............................ 380, 383 Roquet, C. .................................... 394 Rosique, C.................................... 393 Rosselló, J.A. ..................21, 365, 376 Rotllan, X. .................................... 394 Saatkamp, A................................. 271 Sáez, Ll. ................................. 91, 394 Schirone, B................................... 386 Seoane, M. ................................... 374 Simeone, M.C. ............................ 386 Spadaro, V. ................................... 368 410 Islands and plants: preservation and understanding of lora on Mediterranean islands 411 Author Index L’edició d’una obra col·lectiva és una feina que suposa reptes i vencer diicultats. Tanmateix, aquest esforç enriqueix i genera bones experiències. Altrament, els obstacles que la fan perillar, son aliens als autors i editors. Menorca, març de 2014 412