Use of Habitats as Surrogates of Biodiversity for Efficient Coral Reef Conservation Planning in Pacific Ocean Islands |
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Authors: | MAYEUL DALLEAU SERGE ANDRÉFOUËT COLETTE C.C. WABNITZ CLAUDE PAYRI LAURENT WANTIEZ MICHEL PICHON KIM FRIEDMAN LAURENT VIGLIOLA FRANCESCA BENZONI |
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Affiliation: | 1. Institut de Recherche pour le Développement, Centre de Nouméa, B.P. A5, 98848, Nouméa, New‐Caledonia;2. Dipartimento de Biotecnologie e Bioscienze, University of Milano‐Bicoccca, Piazza della Scienza, 2 20126 Milano, Italy;3. Sea Around Us Project, Fisheries Centre, Aquatic Ecosystems Research Laboratory, University of British Columbia, 2202 Main Mall, Vancouver, BC V6T 1Z4, Canada;4. LIVE, Université de la Nouvelle‐Calédonie, B.P. R4 98851 Nouméa Cedex, New Caledonia;5. Museum of Tropical Queensland, 70–102 Flinders Street, Townsville, QLD 4810, Australia;6. Secretariat of the Pacific Community, BP D5, 98848 Nouméa, New Caledonia;7. Department of Environment and Conservation, 17 Dick Perry Avenue, Kensington, WA 6151, Australia;8. Institut de Recherche pour le Développement, Centre de Bretagne, B.P. 70, 29280 Plouzané, France |
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Abstract: | Abstract: Marine protected areas (MPAs) have been highlighted as a means toward effective conservation of coral reefs. New strategies are required to more effectively select MPA locations and increase the pace of their implementation. Many criteria exist to design MPA networks, but generally, it is recommended that networks conserve a diversity of species selected for, among other attributes, their representativeness, rarity, or endemicity. Because knowledge of species’ spatial distribution remains scarce, efficient surrogates are urgently needed. We used five different levels of habitat maps and six spatial scales of analysis to identify under which circumstances habitat data used to design MPA networks for Wallis Island provided better representation of species than random choice alone. Protected‐area site selections were derived from a rarity–complementarity algorithm. Habitat surrogacy was tested for commercial fish species, all fish species, commercially harvested invertebrates, corals, and algae species. Efficiency of habitat surrogacy varied by species group, type of habitat map, and spatial scale of analysis. Maps with the highest habitat thematic complexity provided better surrogates than simpler maps and were more robust to changes in spatial scales. Surrogates were most efficient for commercial fishes, corals, and algae but not for commercial invertebrates. Conversely, other measurements of species‐habitat associations, such as richness congruence and composition similarities provided weak results. We provide, in part, a habitat‐mapping methodology for designation of MPAs for Pacific Ocean islands that are characterized by habitat zonations similar to Wallis. Given the increasing availability and affordability of space‐borne imagery to map habitats, our approach could appreciably facilitate and improve current approaches to coral reef conservation and enhance MPA implementation. |
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Keywords: | accumulation curves biodiversity surrogacy marine protected area Millennium Coral Reef Mapping Project remote sensing richness congruence Wallis á rea marina protegida congruencia de riqueza curvas de acumulació n percepció n remota Proyecto Milenio de Mapeo de Arrecifes de Coral sustitució n de biodiversidad Wallis |
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