Towards process-oriented management of tropical reefs in the anthropocene

Raphael Seguin; David Mouillot; Joshua E. Cinner; Rick D. Stuart Smith; Eva Maire; Nicholas A.J. Graham; Matthew McLean; Laurent Vigliola; Nicolas Loiseau

doi:10.1038/s41893-022-00981-x

Towards process-oriented management of tropical reefs in the anthropocene

Raphael Seguin, David Mouillot, Joshua E. Cinner, Rick D. Stuart Smith, Eva Maire, Nicholas A.J. Graham, Matthew McLean, Laurent Vigliola, Nicolas Loiseau

Medicine

Résultat de recherche: Article › examen par les pairs

16 Citations (Scopus)

Résumé

Tropical reefs and the fish relying on them are under increasing pressure. Shallow-reef fish provide important ecological information in addition to sustaining fisheries, tourism and more. Although empirical metrics of fish biomass are widely used in fisheries management, metrics of biomass production—how much new biomass is produced over time—are rarely estimated even though such production informs potential fisheries yields. Here we estimate fish standing biomass (B), biomass production (P, the rate of biomass accumulation) and biomass turnover (P/B ratio, the rate of biomass replacement) for 1,979 tropical reef sites spanning 39 tropical countries. On the basis of fish standing biomass and biomass turnover, we propose a conceptual framework that splits reefs into three classes to visualize ecological and socio-economic risk and help guide spatial management interventions (for example, marine protected areas) to optimize returns on conservation efforts. At large scales, high turnover was associated with high human pressure and low primary productivity, whereas high biomass was associated with low human pressure and high primary productivity. Going beyond standing fish biomass to consider dynamic ecological processes can better guide regional coral reef conservation and sustainable fisheries management.

Langue d'origine	English
Journal	Nature Sustainability
DOI	https://doi.org/10.1038/s41893-022-00981-x
Statut de publication	Accepted/In press - 2022

Note bibliographique

Funding Information:
We thank the RLS divers and data management team for data provision. RLS data management is supported by Australia’s Integrated Marine Observing System, which is enabled by the National Collaborative Research Infrastructure Strategy. This research was partly funded through the 2017–2018 Belmont Forum and BiodivERsA REEF-FUTURES project under the BiodivScen ERA-Net COFUND programme and with funding from ANR, DFG, NSF, Royal Society, ERC and NSERC. E.M. was supported by an Early Career Fellowship from the Leverhulme Trust.

Publisher Copyright:
© 2022, The Author(s).

ASJC Scopus Subject Areas

Global and Planetary Change
Food Science
Geography, Planning and Development
Ecology
Renewable Energy, Sustainability and the Environment
Urban Studies
Nature and Landscape Conservation
Management, Monitoring, Policy and Law

ODD de l’ONU

Cette action contribue à la réalisation des objectifs de développement durable suivants

Accès au document

10.1038/s41893-022-00981-x

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abstract = "Tropical reefs and the fish relying on them are under increasing pressure. Shallow-reef fish provide important ecological information in addition to sustaining fisheries, tourism and more. Although empirical metrics of fish biomass are widely used in fisheries management, metrics of biomass production—how much new biomass is produced over time—are rarely estimated even though such production informs potential fisheries yields. Here we estimate fish standing biomass (B), biomass production (P, the rate of biomass accumulation) and biomass turnover (P/B ratio, the rate of biomass replacement) for 1,979 tropical reef sites spanning 39 tropical countries. On the basis of fish standing biomass and biomass turnover, we propose a conceptual framework that splits reefs into three classes to visualize ecological and socio-economic risk and help guide spatial management interventions (for example, marine protected areas) to optimize returns on conservation efforts. At large scales, high turnover was associated with high human pressure and low primary productivity, whereas high biomass was associated with low human pressure and high primary productivity. Going beyond standing fish biomass to consider dynamic ecological processes can better guide regional coral reef conservation and sustainable fisheries management.",

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N2 - Tropical reefs and the fish relying on them are under increasing pressure. Shallow-reef fish provide important ecological information in addition to sustaining fisheries, tourism and more. Although empirical metrics of fish biomass are widely used in fisheries management, metrics of biomass production—how much new biomass is produced over time—are rarely estimated even though such production informs potential fisheries yields. Here we estimate fish standing biomass (B), biomass production (P, the rate of biomass accumulation) and biomass turnover (P/B ratio, the rate of biomass replacement) for 1,979 tropical reef sites spanning 39 tropical countries. On the basis of fish standing biomass and biomass turnover, we propose a conceptual framework that splits reefs into three classes to visualize ecological and socio-economic risk and help guide spatial management interventions (for example, marine protected areas) to optimize returns on conservation efforts. At large scales, high turnover was associated with high human pressure and low primary productivity, whereas high biomass was associated with low human pressure and high primary productivity. Going beyond standing fish biomass to consider dynamic ecological processes can better guide regional coral reef conservation and sustainable fisheries management.

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Towards process-oriented management of tropical reefs in the anthropocene

Résumé

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ASJC Scopus Subject Areas

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