AI Article Synopsis
- Marine environments have warmed by an average of 1°C since the 1850s, affecting the distribution of marine species based on their thermal tolerances.
- A global analysis of 304 marine species shows that abundance is increasing in cooler, poleward areas, while it is declining toward the warmer equatorial regions.
- This trend indicates that future temperature rises (up to 1.5°C by 2050) will further push marine species to shift their distributions, potentially impacting coastal communities reliant on these species.
Article Abstract
Marine environments have increased in temperature by an average of 1°C since pre-industrial (1850) times [1]. Given that species ranges are closely allied to physiological thermal tolerances in marine organisms [2], it may therefore be expected that ocean warming would lead to abundance increases at poleward side of ranges and abundance declines toward the equator [3]. Here, we report a global analysis of abundance trends of 304 widely distributed marine species over the last century, across a range of taxonomic groups from phytoplankton to fish and marine mammals. Specifically, using a literature database, we investigate the extent that the direction and strength of long-term species abundance changes depend on the sampled location within the latitudinal range of species. Our results show that abundance increases have been most prominent where sampling has taken place at the poleward side of species ranges, and abundance declines have been most prominent where sampling has taken place at the equatorward side of species ranges. These data provide evidence of omnipresent large-scale changes in abundance of marine species consistent with warming over the last century and suggest that adaptation has not provided a buffer against the negative effects of warmer conditions at the equatorward extent of species ranges. On the basis of these results, we suggest that projected sea temperature increases of up to 1.5°C over pre-industrial levels by 2050 [4] will continue to drive latitudinal abundance shifts in marine species, including those of importance for coastal livelihoods.
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| http://dx.doi.org/10.1016/j.cub.2020.02.043 | DOI Listing |
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