Multigenerational Exposure to Warming and Fishing Causes Recruitment Collapse, but Size Diversity and Periodic Cooling Can Aid Recovery

Overview

Journal Proc Natl Acad Sci U S A

Specialty Science

Date 2021 Apr 27

PMID 33903250

Citations 10

Authors

Henry F Wootton

Asta Audzijonyte

John Morrongiello

Affiliations

Soon will be listed here.

Abstract

Global warming and fisheries harvest are significantly impacting wild fish stocks, yet their interactive influence on population resilience to stress remains unclear. We explored these interactive effects on early-life development and survival by experimentally manipulating the thermal and harvest regimes in 18 zebrafish () populations over six consecutive generations. Warming advanced development rates across generations, but after three generations, it caused a sudden and large (30-50%) decline in recruitment. This warming impact was most severe in populations where size-selective harvesting reduced the average size of spawners. We then explored whether our observed recruitment decline could be explained by changes in egg size, early egg and larval survival, population sex ratio, and developmental costs. We found that it was most likely driven by temperature-induced shifts in embryonic development rate and fishing-induced male-biased sex ratios. Importantly, once harvest and warming were relaxed, recruitment rates rapidly recovered. Our study suggests that the effects of warming and fishing could have strong impacts on wild stock recruitment, but this may take several generations to manifest. However, resilience of wild populations may be higher if fishing preserves sufficient body size diversity, and windows of suitable temperature periodically occur.

Citing Articles

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Does size-selective harvesting erode adaptive potential to thermal stress?.

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Audzijonyte A, Delius G, Stuart-Smith R, Novaglio C, Edgar G, Barrett N PLoS Biol. 2023; 21(12):e3002392.

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Thermal sensitivity of field metabolic rate predicts differential futures for bluefin tuna juveniles across the Atlantic Ocean.

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