Support for the trophic theory of island biogeography across submarine banks in a predator-depleted large marine ecosystem

C. H. Stortini; K. T. Frank; W. C. Leggett; N. L. Shackell; D. G. Boyce

doi:10.3354/meps12799

Support for the trophic theory of island biogeography across submarine banks in a predator-depleted large marine ecosystem

C. H. Stortini, K. T. Frank, W. C. Leggett, N. L. Shackell, D. G. Boyce

Medicine

Medicine

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

5 Citas (Scopus)

Resumen

The trophic theory of island biogeography (TTIB) predicts that when predators are depleted, prey extinction rates decrease, leading to increases in prey alpha diversity and an increase in the slope of the species−area relationship (SAR). The TTIB has been tested and supported in a restricted set of systems at small spatial scales (0.25 m³ [reef patches] to 29 500 m² [terrestrial]). Across semi-insular fish communities on 10 offshore banks ranging in size from 534 to 10 537 km² on the Scotian Shelf (northwest Atlantic Ocean), we found support for the predictions of the TTIB. The prey SAR slope was significantly higher after the collapse of large predator populations than before the collapse, due largely to the immigration (or colonization) of many new prey species, principally on the largest banks. Coincident increases in core (resident) prey species densities, primarily on the largest banks, suggests that extinction risk decreased. The appearance of a strong SAR within the mesopredator trophic group in the post-predator collapse era (r² = 0.55 relative to 0.12 in the pre-collapse era) suggests that the TTIB may also apply to mesopredator release in insular marine communities. Increases in mesopredator densities coincident with the colonization of previously unoccupied banks by core mesopredator species suggests that range expansions contributed to the increased strength of the SAR. Our study contributes to our evolving understanding of island biogeography theory and suggests that TTIB may provide a useful framework for evaluating trophic alterations in large marine (and non-marine) ecosystems.

Idioma original	English
Páginas (desde-hasta)	155-169
Número de páginas	15
Publicación	Marine Ecology - Progress Series
Volumen	607
DOI	https://doi.org/10.3354/meps12799
Estado	Published - dic. 6 2018

Nota bibliográfica

Funding Information:
We thank Dr. Thierry Boulinier for advice concerning species detectability issues and species richness estimators, and Dr. Jonathan Fisher, Dr. Brian Petrie, and Kiyomi French for their constructive and insightful reviews. We also thank Dr. Nigel Yoccoz, Dr. Torkild Tveraa, Dr. Kari Ellingsen, Dr. Shelley Arnott, Dr. Bob Mont-gomerie, and Dr. Ryan Danby for helpful advice in both early and late stages of this project. We thank Fisheries and Oceans Canada, Queen’s University, the Natural Sciences and Engineering Research Council (Canada), and the Norwegian Institute for Nature Research DRIVEBANKS project (https://www.nina.no/english/Fields-of-research/Projects/ Drivebanks) for the funding that made this research possible.

Funding Information:
Acknowledgements. We thank Dr. Thierry Boulinier for advice concerning species detectability issues and species richness estimators, and Dr. Jonathan Fisher, Dr. Brian Petrie, and Kiyomi French for their constructive and insightful reviews. We also thank Dr. Nigel Yoccoz, Dr. Torkild Tveraa, Dr. Kari Ellingsen, Dr. Shelley Arnott, Dr. Bob Mont-gomerie, and Dr. Ryan Danby for helpful advice in both early and late stages of this project. We thank Fisheries and Oceans Canada, Queen’s University, the Natural Sciences and Engineering Research Council (Canada), and the Norwegian Institute for Nature Research DRIVEBANKS project (https://www.nina.no/english/Fields-of-research/ Projects/ Drivebanks) for the funding that made this research possible.

Publisher Copyright:
© The authors 2018. Open Access under Creative Commons by Attribution Licence. Use, distribution and reproduction are unrestricted. Authors and original publication must be credited.

ASJC Scopus Subject Areas

Ecology, Evolution, Behavior and Systematics
Aquatic Science
Ecology

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Este resultado contribuye a los siguientes Objetivos de Desarrollo Sostenible

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10.3354/meps12799

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title = "Support for the trophic theory of island biogeography across submarine banks in a predator-depleted large marine ecosystem",

abstract = "The trophic theory of island biogeography (TTIB) predicts that when predators are depleted, prey extinction rates decrease, leading to increases in prey alpha diversity and an increase in the slope of the species−area relationship (SAR). The TTIB has been tested and supported in a restricted set of systems at small spatial scales (0.25 m3 [reef patches] to 29 500 m2 [terrestrial]). Across semi-insular fish communities on 10 offshore banks ranging in size from 534 to 10 537 km2 on the Scotian Shelf (northwest Atlantic Ocean), we found support for the predictions of the TTIB. The prey SAR slope was significantly higher after the collapse of large predator populations than before the collapse, due largely to the immigration (or colonization) of many new prey species, principally on the largest banks. Coincident increases in core (resident) prey species densities, primarily on the largest banks, suggests that extinction risk decreased. The appearance of a strong SAR within the mesopredator trophic group in the post-predator collapse era (r2 = 0.55 relative to 0.12 in the pre-collapse era) suggests that the TTIB may also apply to mesopredator release in insular marine communities. Increases in mesopredator densities coincident with the colonization of previously unoccupied banks by core mesopredator species suggests that range expansions contributed to the increased strength of the SAR. Our study contributes to our evolving understanding of island biogeography theory and suggests that TTIB may provide a useful framework for evaluating trophic alterations in large marine (and non-marine) ecosystems.",

author = "Stortini, {C. H.} and Frank, {K. T.} and Leggett, {W. C.} and Shackell, {N. L.} and Boyce, {D. G.}",

note = "Funding Information: We thank Dr. Thierry Boulinier for advice concerning species detectability issues and species richness estimators, and Dr. Jonathan Fisher, Dr. Brian Petrie, and Kiyomi French for their constructive and insightful reviews. We also thank Dr. Nigel Yoccoz, Dr. Torkild Tveraa, Dr. Kari Ellingsen, Dr. Shelley Arnott, Dr. Bob Mont-gomerie, and Dr. Ryan Danby for helpful advice in both early and late stages of this project. We thank Fisheries and Oceans Canada, Queen{\textquoteright}s University, the Natural Sciences and Engineering Research Council (Canada), and the Norwegian Institute for Nature Research DRIVEBANKS project (https://www.nina.no/english/Fields-of-research/Projects/ Drivebanks) for the funding that made this research possible. Funding Information: Acknowledgements. We thank Dr. Thierry Boulinier for advice concerning species detectability issues and species richness estimators, and Dr. Jonathan Fisher, Dr. Brian Petrie, and Kiyomi French for their constructive and insightful reviews. We also thank Dr. Nigel Yoccoz, Dr. Torkild Tveraa, Dr. Kari Ellingsen, Dr. Shelley Arnott, Dr. Bob Mont-gomerie, and Dr. Ryan Danby for helpful advice in both early and late stages of this project. We thank Fisheries and Oceans Canada, Queen{\textquoteright}s University, the Natural Sciences and Engineering Research Council (Canada), and the Norwegian Institute for Nature Research DRIVEBANKS project (https://www.nina.no/english/Fields-of-research/ Projects/ Drivebanks) for the funding that made this research possible. Publisher Copyright: {\textcopyright} The authors 2018. Open Access under Creative Commons by Attribution Licence. Use, distribution and reproduction are unrestricted. Authors and original publication must be credited.",

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doi = "10.3354/meps12799",

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AU - Shackell, N. L.

AU - Boyce, D. G.

N1 - Funding Information: We thank Dr. Thierry Boulinier for advice concerning species detectability issues and species richness estimators, and Dr. Jonathan Fisher, Dr. Brian Petrie, and Kiyomi French for their constructive and insightful reviews. We also thank Dr. Nigel Yoccoz, Dr. Torkild Tveraa, Dr. Kari Ellingsen, Dr. Shelley Arnott, Dr. Bob Mont-gomerie, and Dr. Ryan Danby for helpful advice in both early and late stages of this project. We thank Fisheries and Oceans Canada, Queen’s University, the Natural Sciences and Engineering Research Council (Canada), and the Norwegian Institute for Nature Research DRIVEBANKS project (https://www.nina.no/english/Fields-of-research/Projects/ Drivebanks) for the funding that made this research possible. Funding Information: Acknowledgements. We thank Dr. Thierry Boulinier for advice concerning species detectability issues and species richness estimators, and Dr. Jonathan Fisher, Dr. Brian Petrie, and Kiyomi French for their constructive and insightful reviews. We also thank Dr. Nigel Yoccoz, Dr. Torkild Tveraa, Dr. Kari Ellingsen, Dr. Shelley Arnott, Dr. Bob Mont-gomerie, and Dr. Ryan Danby for helpful advice in both early and late stages of this project. We thank Fisheries and Oceans Canada, Queen’s University, the Natural Sciences and Engineering Research Council (Canada), and the Norwegian Institute for Nature Research DRIVEBANKS project (https://www.nina.no/english/Fields-of-research/ Projects/ Drivebanks) for the funding that made this research possible. Publisher Copyright: © The authors 2018. Open Access under Creative Commons by Attribution Licence. Use, distribution and reproduction are unrestricted. Authors and original publication must be credited.

PY - 2018/12/6

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N2 - The trophic theory of island biogeography (TTIB) predicts that when predators are depleted, prey extinction rates decrease, leading to increases in prey alpha diversity and an increase in the slope of the species−area relationship (SAR). The TTIB has been tested and supported in a restricted set of systems at small spatial scales (0.25 m3 [reef patches] to 29 500 m2 [terrestrial]). Across semi-insular fish communities on 10 offshore banks ranging in size from 534 to 10 537 km2 on the Scotian Shelf (northwest Atlantic Ocean), we found support for the predictions of the TTIB. The prey SAR slope was significantly higher after the collapse of large predator populations than before the collapse, due largely to the immigration (or colonization) of many new prey species, principally on the largest banks. Coincident increases in core (resident) prey species densities, primarily on the largest banks, suggests that extinction risk decreased. The appearance of a strong SAR within the mesopredator trophic group in the post-predator collapse era (r2 = 0.55 relative to 0.12 in the pre-collapse era) suggests that the TTIB may also apply to mesopredator release in insular marine communities. Increases in mesopredator densities coincident with the colonization of previously unoccupied banks by core mesopredator species suggests that range expansions contributed to the increased strength of the SAR. Our study contributes to our evolving understanding of island biogeography theory and suggests that TTIB may provide a useful framework for evaluating trophic alterations in large marine (and non-marine) ecosystems.

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Support for the trophic theory of island biogeography across submarine banks in a predator-depleted large marine ecosystem

Resumen

Nota bibliográfica

ASJC Scopus Subject Areas

ODS de las Naciones Unidas

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