Deep-sea diversity patterns are shaped by energy availability

Skipton N.C. Woolley; Derek P. Tittensor; Piers K. Dunstan; Gurutzeta Guillera-Arroita; José J. Lahoz-Monfort; Brendan A. Wintle; Boris Worm; Timothy D. O'Hara

doi:10.1038/nature17937

Deep-sea diversity patterns are shaped by energy availability

Skipton N.C. Woolley, Derek P. Tittensor, Piers K. Dunstan, Gurutzeta Guillera-Arroita, José J. Lahoz-Monfort, Brendan A. Wintle, Boris Worm, Timothy D. O'Hara

Medicine

Producción científica: Contribución a una revista › Artículo › revisión exhaustiva

220 Citas (Scopus)

Resumen

The deep ocean is the largest and least-explored ecosystem on Earth, and a uniquely energy-poor environment. The distribution, drivers and origins of deep-sea biodiversity remain unknown at global scales. Here we analyse a database of more than 165,000 distribution records of Ophiuroidea (brittle stars), a dominant component of sea-floor fauna, and find patterns of biodiversity unlike known terrestrial or coastal marine realms. Both patterns and environmental predictors of deep-sea (2,000-6,500 m) species richness fundamentally differ from those found in coastal (0-20 m), continental shelf (20-200 m), and upper-slope (200-2,000 m) waters. Continental shelf to upper-slope richness consistently peaks in tropical Indo-west Pacific and Caribbean (0-30°) latitudes, and is well explained by variations in water temperature. In contrast, deep-sea species show maximum richness at higher latitudes (30-50°), concentrated in areas of high carbon export flux and regions close to continental margins. We reconcile this structuring of oceanic biodiversity using a species-energy framework, with kinetic energy predicting shallow-water richness, while chemical energy (export productivity) and proximity to slope habitats drive deep-sea diversity. Our findings provide a global baseline for conservation efforts across the sea floor, and demonstrate that deep-sea ecosystems show a biodiversity pattern consistent with ecological theory, despite being different from other planetary-scale habitats.

Idioma original	English
Páginas (desde-hasta)	393-396
Número de páginas	4
Publicación	Nature
Volumen	533
DOI	https://doi.org/10.1038/nature17937
Estado	Published - may. 11 2016

Nota bibliográfica

Funding Information:
We thank all collectors and taxonomists involved for providing biodiversity data. This work is an output of the project 'National maps of biodiversity and connectivity' of the Marine Biodiversity Research Hub and Environmental Decisions Hub, funded through the Commonwealth National Environmental Research Program (NERP) and administered through the Australian Government's Department of Environment. This work is also a product of the International Network for Scientific Investigations of Deep-Sea Ecosystems (INDEEP) working group on biogeography. We also thank the Centre of Excellence for Environmental Decisions (CEED) for travel funding that enabled collaboration between the University of Melbourne, Museum Victoria and Dalhousie University.

Publisher Copyright:
© 2016 Macmillan Publishers Limited. All rights reserved.

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title = "Deep-sea diversity patterns are shaped by energy availability",

abstract = "The deep ocean is the largest and least-explored ecosystem on Earth, and a uniquely energy-poor environment. The distribution, drivers and origins of deep-sea biodiversity remain unknown at global scales. Here we analyse a database of more than 165,000 distribution records of Ophiuroidea (brittle stars), a dominant component of sea-floor fauna, and find patterns of biodiversity unlike known terrestrial or coastal marine realms. Both patterns and environmental predictors of deep-sea (2,000-6,500 m) species richness fundamentally differ from those found in coastal (0-20 m), continental shelf (20-200 m), and upper-slope (200-2,000 m) waters. Continental shelf to upper-slope richness consistently peaks in tropical Indo-west Pacific and Caribbean (0-30°) latitudes, and is well explained by variations in water temperature. In contrast, deep-sea species show maximum richness at higher latitudes (30-50°), concentrated in areas of high carbon export flux and regions close to continental margins. We reconcile this structuring of oceanic biodiversity using a species-energy framework, with kinetic energy predicting shallow-water richness, while chemical energy (export productivity) and proximity to slope habitats drive deep-sea diversity. Our findings provide a global baseline for conservation efforts across the sea floor, and demonstrate that deep-sea ecosystems show a biodiversity pattern consistent with ecological theory, despite being different from other planetary-scale habitats.",

author = "Woolley, {Skipton N.C.} and Tittensor, {Derek P.} and Dunstan, {Piers K.} and Gurutzeta Guillera-Arroita and Lahoz-Monfort, {Jos{\'e} J.} and Wintle, {Brendan A.} and Boris Worm and O'Hara, {Timothy D.}",

note = "Funding Information: We thank all collectors and taxonomists involved for providing biodiversity data. This work is an output of the project 'National maps of biodiversity and connectivity' of the Marine Biodiversity Research Hub and Environmental Decisions Hub, funded through the Commonwealth National Environmental Research Program (NERP) and administered through the Australian Government's Department of Environment. This work is also a product of the International Network for Scientific Investigations of Deep-Sea Ecosystems (INDEEP) working group on biogeography. We also thank the Centre of Excellence for Environmental Decisions (CEED) for travel funding that enabled collaboration between the University of Melbourne, Museum Victoria and Dalhousie University. Publisher Copyright: {\textcopyright} 2016 Macmillan Publishers Limited. All rights reserved.",

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AU - Lahoz-Monfort, José J.

AU - Wintle, Brendan A.

AU - Worm, Boris

AU - O'Hara, Timothy D.

N1 - Funding Information: We thank all collectors and taxonomists involved for providing biodiversity data. This work is an output of the project 'National maps of biodiversity and connectivity' of the Marine Biodiversity Research Hub and Environmental Decisions Hub, funded through the Commonwealth National Environmental Research Program (NERP) and administered through the Australian Government's Department of Environment. This work is also a product of the International Network for Scientific Investigations of Deep-Sea Ecosystems (INDEEP) working group on biogeography. We also thank the Centre of Excellence for Environmental Decisions (CEED) for travel funding that enabled collaboration between the University of Melbourne, Museum Victoria and Dalhousie University. Publisher Copyright: © 2016 Macmillan Publishers Limited. All rights reserved.

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Deep-sea diversity patterns are shaped by energy availability

Resumen

Nota bibliográfica

ASJC Scopus Subject Areas

ODS de las Naciones Unidas

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