Disentangling tropicalization and deborealization in marine ecosystems under climate change

Matthew McLean; David Mouillot; Aurore A. Maureaud; Tarek Hattab; M. Aaron MacNeil; Eric Goberville; Martin Lindegren; Georg Engelhard; Malin Pinsky; Arnaud Auber

doi:10.1016/j.cub.2021.08.034

Disentangling tropicalization and deborealization in marine ecosystems under climate change

Matthew McLean, David Mouillot, Aurore A. Maureaud, Tarek Hattab, M. Aaron MacNeil, Eric Goberville, Martin Lindegren, Georg Engelhard, Malin Pinsky, Arnaud Auber

Medicine

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63 Citas (Scopus)

Resumen

As climate change accelerates, species are shifting poleward and subtropical and tropical species are colonizing temperate environments.^1–3 A popular approach for characterizing such responses is the community temperature index (CTI), which tracks the mean thermal affinity of a community. Studies in marine,⁴ freshwater,⁵ and terrestrial⁶ ecosystems have documented increasing CTI under global warming. However, most studies have only linked increasing CTI to increases in warm-affinity species. Here, using long-term monitoring of marine fishes across the Northern Hemisphere, we decomposed CTI changes into four underlying processes—tropicalization (increasing warm-affinity), deborealization (decreasing cold-affinity), borealization (increasing cold-affinity), and detropicalization (decreasing warm-affinity)—for which we examined spatial variability and drivers. CTI closely tracked changes in sea surface temperature, increasing in 72% of locations. However, 31% of these increases were primarily due to decreases in cold-affinity species, i.e., deborealization. Thus, increases in warm-affinity species were prevalent, but not ubiquitous. Tropicalization was stronger in areas that were initially warmer, experienced greater warming, or were deeper, while deborealization was stronger in areas that were closer to human population centers or that had higher community thermal diversity. When CTI (and temperature) increased, species that decreased were more likely to be living closer to their upper thermal limits or to be commercially fished. Additionally, warm-affinity species that increased had smaller body sizes than those that decreased. Our results show that CTI changes arise from a variety of underlying community responses that are linked to environmental conditions, human impacts, community structure, and species characteristics.

Idioma original	English
Páginas (desde-hasta)	4817-4823.e5
Publicación	Current Biology
Volumen	31
N.º	21
DOI	https://doi.org/10.1016/j.cub.2021.08.034
Estado	Published - nov. 8 2021

Nota bibliográfica

Funding Information:
We acknowledge the MAESTRO group funded by the synthesis center CESAB of the French Foundation for Research on Biodiversity (FRB) and Filière France Pêche (FFP). M.M. and A.A. were supported by Electricité de France (RESTICLIM and ECLIPSE project), IFREMER (ECLIPSE project), Région Hauts-de-France , and the Foundation for Research on Biodiversity (ECLIPSE project, contract no. astre 2014-10824 ). M.M. and M.A.M. were supported by the Natural Sciences and Engineering Research Council of Canada (grant no. RGPBB/525590 ). M.A.M. was also supported by the Canada Research Chairs Program and the Ocean Frontier Institute . M.L. and A.A.M. were supported by VKR Centre for Ocean Life and a VILLUM research grant (no. 13159 ). M.L. was also supported by the European Union’s Horizon 2020 research and innovation program under grant agreement no. 862428 (MISSION ATLANTIC) and no. 869300 (FutureMARES). M.P. was supported by U.S. National Science Foundation # DEB-1616821 .

Funding Information:
We acknowledge the MAESTRO group funded by the synthesis center CESAB of the French Foundation for Research on Biodiversity (FRB) and Fili?re France P?che (FFP). M.M. and A.A. were supported by Electricit? de France (RESTICLIM and ECLIPSE project), IFREMER (ECLIPSE project), R?gion Hauts-de-France, and the Foundation for Research on Biodiversity (ECLIPSE project, contract no. astre 2014-10824). M.M. and M.A.M. were supported by the Natural Sciences and Engineering Research Council of Canada (grant no. RGPBB/525590). M.A.M. was also supported by the Canada Research Chairs Program and the Ocean Frontier Institute. M.L. and A.A.M. were supported by VKR Centre for Ocean Life and a VILLUM research grant (no. 13159). M.L. was also supported by the European Union's Horizon 2020 research and innovation program under grant agreement no. 862428 (MISSION ATLANTIC) and no. 869300 (FutureMARES). M.P. was supported by U.S. National Science Foundation #DEB-1616821. A.A. D.M. and M.M. designed the research; A.A.M. T.H. and M.M. collected and processed the data; M.M. and A.A. analyzed the data; and all authors contributed to conceptual development and writing. The authors declare no competing interests.

Publisher Copyright:
© 2021 Elsevier Inc.

ASJC Scopus Subject Areas

General Neuroscience
General Biochemistry,Genetics and Molecular Biology
General Agricultural and Biological Sciences

PubMed: MeSH publication types

Journal Article
Research Support, Non-U.S. Gov't
Research Support, U.S. Gov't, Non-P.H.S.

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title = "Disentangling tropicalization and deborealization in marine ecosystems under climate change",

abstract = "As climate change accelerates, species are shifting poleward and subtropical and tropical species are colonizing temperate environments.1–3 A popular approach for characterizing such responses is the community temperature index (CTI), which tracks the mean thermal affinity of a community. Studies in marine,4 freshwater,5 and terrestrial6 ecosystems have documented increasing CTI under global warming. However, most studies have only linked increasing CTI to increases in warm-affinity species. Here, using long-term monitoring of marine fishes across the Northern Hemisphere, we decomposed CTI changes into four underlying processes—tropicalization (increasing warm-affinity), deborealization (decreasing cold-affinity), borealization (increasing cold-affinity), and detropicalization (decreasing warm-affinity)—for which we examined spatial variability and drivers. CTI closely tracked changes in sea surface temperature, increasing in 72% of locations. However, 31% of these increases were primarily due to decreases in cold-affinity species, i.e., deborealization. Thus, increases in warm-affinity species were prevalent, but not ubiquitous. Tropicalization was stronger in areas that were initially warmer, experienced greater warming, or were deeper, while deborealization was stronger in areas that were closer to human population centers or that had higher community thermal diversity. When CTI (and temperature) increased, species that decreased were more likely to be living closer to their upper thermal limits or to be commercially fished. Additionally, warm-affinity species that increased had smaller body sizes than those that decreased. Our results show that CTI changes arise from a variety of underlying community responses that are linked to environmental conditions, human impacts, community structure, and species characteristics.",

author = "Matthew McLean and David Mouillot and Maureaud, {Aurore A.} and Tarek Hattab and MacNeil, {M. Aaron} and Eric Goberville and Martin Lindegren and Georg Engelhard and Malin Pinsky and Arnaud Auber",

note = "Funding Information: We acknowledge the MAESTRO group funded by the synthesis center CESAB of the French Foundation for Research on Biodiversity (FRB) and Fili{\`e}re France P{\^e}che (FFP). M.M. and A.A. were supported by Electricit{\'e} de France (RESTICLIM and ECLIPSE project), IFREMER (ECLIPSE project), R{\'e}gion Hauts-de-France , and the Foundation for Research on Biodiversity (ECLIPSE project, contract no. astre 2014-10824 ). M.M. and M.A.M. were supported by the Natural Sciences and Engineering Research Council of Canada (grant no. RGPBB/525590 ). M.A.M. was also supported by the Canada Research Chairs Program and the Ocean Frontier Institute . M.L. and A.A.M. were supported by VKR Centre for Ocean Life and a VILLUM research grant (no. 13159 ). M.L. was also supported by the European Union{\textquoteright}s Horizon 2020 research and innovation program under grant agreement no. 862428 (MISSION ATLANTIC) and no. 869300 (FutureMARES). M.P. was supported by U.S. National Science Foundation # DEB-1616821 . Funding Information: We acknowledge the MAESTRO group funded by the synthesis center CESAB of the French Foundation for Research on Biodiversity (FRB) and Fili?re France P?che (FFP). M.M. and A.A. were supported by Electricit? de France (RESTICLIM and ECLIPSE project), IFREMER (ECLIPSE project), R?gion Hauts-de-France, and the Foundation for Research on Biodiversity (ECLIPSE project, contract no. astre 2014-10824). M.M. and M.A.M. were supported by the Natural Sciences and Engineering Research Council of Canada (grant no. RGPBB/525590). M.A.M. was also supported by the Canada Research Chairs Program and the Ocean Frontier Institute. M.L. and A.A.M. were supported by VKR Centre for Ocean Life and a VILLUM research grant (no. 13159). M.L. was also supported by the European Union's Horizon 2020 research and innovation program under grant agreement no. 862428 (MISSION ATLANTIC) and no. 869300 (FutureMARES). M.P. was supported by U.S. National Science Foundation #DEB-1616821. A.A. D.M. and M.M. designed the research; A.A.M. T.H. and M.M. collected and processed the data; M.M. and A.A. analyzed the data; and all authors contributed to conceptual development and writing. The authors declare no competing interests. Publisher Copyright: {\textcopyright} 2021 Elsevier Inc.",

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N1 - Funding Information: We acknowledge the MAESTRO group funded by the synthesis center CESAB of the French Foundation for Research on Biodiversity (FRB) and Filière France Pêche (FFP). M.M. and A.A. were supported by Electricité de France (RESTICLIM and ECLIPSE project), IFREMER (ECLIPSE project), Région Hauts-de-France , and the Foundation for Research on Biodiversity (ECLIPSE project, contract no. astre 2014-10824 ). M.M. and M.A.M. were supported by the Natural Sciences and Engineering Research Council of Canada (grant no. RGPBB/525590 ). M.A.M. was also supported by the Canada Research Chairs Program and the Ocean Frontier Institute . M.L. and A.A.M. were supported by VKR Centre for Ocean Life and a VILLUM research grant (no. 13159 ). M.L. was also supported by the European Union’s Horizon 2020 research and innovation program under grant agreement no. 862428 (MISSION ATLANTIC) and no. 869300 (FutureMARES). M.P. was supported by U.S. National Science Foundation # DEB-1616821 . Funding Information: We acknowledge the MAESTRO group funded by the synthesis center CESAB of the French Foundation for Research on Biodiversity (FRB) and Fili?re France P?che (FFP). M.M. and A.A. were supported by Electricit? de France (RESTICLIM and ECLIPSE project), IFREMER (ECLIPSE project), R?gion Hauts-de-France, and the Foundation for Research on Biodiversity (ECLIPSE project, contract no. astre 2014-10824). M.M. and M.A.M. were supported by the Natural Sciences and Engineering Research Council of Canada (grant no. RGPBB/525590). M.A.M. was also supported by the Canada Research Chairs Program and the Ocean Frontier Institute. M.L. and A.A.M. were supported by VKR Centre for Ocean Life and a VILLUM research grant (no. 13159). M.L. was also supported by the European Union's Horizon 2020 research and innovation program under grant agreement no. 862428 (MISSION ATLANTIC) and no. 869300 (FutureMARES). M.P. was supported by U.S. National Science Foundation #DEB-1616821. A.A. D.M. and M.M. designed the research; A.A.M. T.H. and M.M. collected and processed the data; M.M. and A.A. analyzed the data; and all authors contributed to conceptual development and writing. The authors declare no competing interests. Publisher Copyright: © 2021 Elsevier Inc.

PY - 2021/11/8

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N2 - As climate change accelerates, species are shifting poleward and subtropical and tropical species are colonizing temperate environments.1–3 A popular approach for characterizing such responses is the community temperature index (CTI), which tracks the mean thermal affinity of a community. Studies in marine,4 freshwater,5 and terrestrial6 ecosystems have documented increasing CTI under global warming. However, most studies have only linked increasing CTI to increases in warm-affinity species. Here, using long-term monitoring of marine fishes across the Northern Hemisphere, we decomposed CTI changes into four underlying processes—tropicalization (increasing warm-affinity), deborealization (decreasing cold-affinity), borealization (increasing cold-affinity), and detropicalization (decreasing warm-affinity)—for which we examined spatial variability and drivers. CTI closely tracked changes in sea surface temperature, increasing in 72% of locations. However, 31% of these increases were primarily due to decreases in cold-affinity species, i.e., deborealization. Thus, increases in warm-affinity species were prevalent, but not ubiquitous. Tropicalization was stronger in areas that were initially warmer, experienced greater warming, or were deeper, while deborealization was stronger in areas that were closer to human population centers or that had higher community thermal diversity. When CTI (and temperature) increased, species that decreased were more likely to be living closer to their upper thermal limits or to be commercially fished. Additionally, warm-affinity species that increased had smaller body sizes than those that decreased. Our results show that CTI changes arise from a variety of underlying community responses that are linked to environmental conditions, human impacts, community structure, and species characteristics.

AB - As climate change accelerates, species are shifting poleward and subtropical and tropical species are colonizing temperate environments.1–3 A popular approach for characterizing such responses is the community temperature index (CTI), which tracks the mean thermal affinity of a community. Studies in marine,4 freshwater,5 and terrestrial6 ecosystems have documented increasing CTI under global warming. However, most studies have only linked increasing CTI to increases in warm-affinity species. Here, using long-term monitoring of marine fishes across the Northern Hemisphere, we decomposed CTI changes into four underlying processes—tropicalization (increasing warm-affinity), deborealization (decreasing cold-affinity), borealization (increasing cold-affinity), and detropicalization (decreasing warm-affinity)—for which we examined spatial variability and drivers. CTI closely tracked changes in sea surface temperature, increasing in 72% of locations. However, 31% of these increases were primarily due to decreases in cold-affinity species, i.e., deborealization. Thus, increases in warm-affinity species were prevalent, but not ubiquitous. Tropicalization was stronger in areas that were initially warmer, experienced greater warming, or were deeper, while deborealization was stronger in areas that were closer to human population centers or that had higher community thermal diversity. When CTI (and temperature) increased, species that decreased were more likely to be living closer to their upper thermal limits or to be commercially fished. Additionally, warm-affinity species that increased had smaller body sizes than those that decreased. Our results show that CTI changes arise from a variety of underlying community responses that are linked to environmental conditions, human impacts, community structure, and species characteristics.

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Disentangling tropicalization and deborealization in marine ecosystems under climate change

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