Ocean warming and novel species interactions boost growth and persistence of range-extending tropical fishes but challenge that of sympatric temperate species in temperate waters

IF 3.4 2区环境科学与生态学 Q2 ECOLOGY Journal of Biogeography Pub Date : 2024-08-11 DOI:10.1111/jbi.14983

Minami Sasaki, Cristián J. Monaco, David J. Booth, Ivan Nagelkerken

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Abstract

Aim

Climate change can have a broad range of impacts on the physiology and behaviour of animals. These effects can be mediated by the presence of other species in the community, but current forecasts of species responses to climate change largely ignore biological interactions. This is particularly true for novel interactions between range-extending and native species, as this is often considered as noise and excluded from predictive models. Here we simulate how a tropical range-extending and a local temperate fish species respond to the independent and combined effects of future ocean warming (RCPs 4.5 and 8.5) and novel ecological interactions in temperate ecosystems.

Location

East coast of Australia, along a ~ 2,000 km latitudinal gradient in a global climate warming hotspot.

Taxon

Abudefduf vaigiensis (tropical) and Atypicthys strigatus (temperate) fishes.

Methods

We use a dynamic energy budget model to simulate the length growth (i.e., increases in body length of individuals over time) and population persistence of juveniles of a tropical and a temperate fish species that form mixed-species shoals, under different climate scenarios with and without the effects of novel ecological interactions.

Results

Our model forecasts that length growth of the juvenile tropical species will increase under ocean warming across subtropical to temperate regions. This increased length growth will be more drastic in temperate regions than in the subtropics, as winter warming will allow the tropical species to overwinter more frequently and show positive growth throughout the year. In contrast, warmer summer temperatures in the subtropics will likely exceed the optimal temperature of the juvenile temperate species at their trailing edge, resulting in reduced length growth under climate warming. Novel species interactions increased length growth of the juvenile tropical species but did not affect its winter or summer survival. In contrast, novel species interactions with tropical species were forecast to reduce length growth of the juvenile temperate species.

Main Conclusions

Our study suggests that for some coastal fish species future warming will likely reverse body size dominance between temperate and tropical fish species, with increased novel interactions in temperate ecosystems (due to range extensions) but decreased novel interactions in the subtropics (due to range contractions). Novel species interactions and warming effects on body size and species survival are likely to reshuffle temperate fish communities and their competitive interactions.

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海洋变暖和新物种相互作用促进了热带鱼类的生长和持久性，但对温带水域中同域温带物种的生长和持久性提出了挑战

目的气候变化会对动物的生理和行为产生广泛的影响。这些影响可以通过群落中其他物种的存在而得到调节，但目前对物种对气候变化反应的预测在很大程度上忽视了生物之间的相互作用。这种情况在扩展分布区的物种与本地物种之间的新型相互作用中尤为明显，因为这种相互作用通常被视为噪音而被排除在预测模型之外。在此，我们模拟了一种热带广域鱼类和一种本地温带鱼类如何应对未来海洋变暖（RCPs 4.5 和 8.5）的独立和综合影响以及温带生态系统中的新型生态相互作用。地点澳大利亚东海岸，全球气候变暖热点地区约 2000 千米的纬度梯度上。方法我们使用动态能量预算模型模拟个体的长度增长（即体长随时间的增加）、结果我们的模型预测，在海洋变暖的情况下，从亚热带到温带地区，热带鱼类幼体的体长增长将增加。温带地区的长度增长将比亚热带地区更为剧烈，因为冬季变暖将使热带物种更频繁地越冬，并在全年呈现正增长。相反，亚热带地区夏季气温升高，可能会超过温带幼鱼后缘的最适温度，导致在气候变暖的情况下长度增长减少。新物种相互作用会增加热带物种幼体的长度增长，但不会影响其冬季或夏季存活率。我们的研究表明，对于一些沿海鱼类物种来说，未来气候变暖可能会扭转温带鱼类物种和热带鱼类物种之间的体型优势，温带生态系统中的新物种相互作用会增加（由于分布范围扩大），但亚热带地区的新物种相互作用会减少（由于分布范围缩小）。新物种间的相互作用以及气候变暖对体型和物种生存的影响可能会重新调整温带鱼类群落及其竞争性相互作用。

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来源期刊

Journal of Biogeography 环境科学-生态学

CiteScore

7.70

自引率

5.10%

发文量

203

审稿时长

2.2 months

期刊介绍： Papers dealing with all aspects of spatial, ecological and historical biogeography are considered for publication in Journal of Biogeography. The mission of the journal is to contribute to the growth and societal relevance of the discipline of biogeography through its role in the dissemination of biogeographical research.

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