Global warming impairs stock-recruitment dynamics of corals

Journal Publication ResearchOnline@JCU
Hughes, Terry P.;Kerry, James T.;Baird, Andrew H.;Connolly, Sean R.;Chase, Tory J.;Dietzel, Andreas;Hill, Tessa;Hoey, Andrew S.;Hoogenboom, Mia O.;Jacobson, Mizue;Kerswell, Ailsa;Madin, Joshua S.;Mieog, Abbie;Paley, Allison S.;Pratchett, Morgan S.;Torda, Gergely;Woods, Rachael M.
Abstract

Changes in disturbance regimes due to climate change are increasingly challenging the capacity of ecosystems to absorb recurrent shocks and reassemble afterwards, escalating the risk of widespread ecological collapse of current ecosystems and the emergence of novel assemblages(1-3). In marine systems, the production of larvae and recruitment of functionally important species are fundamental processes for rebuilding depleted adult populations, maintaining resilience and avoiding regime shifts in the face of rising environmental pressures(4,5). Here we document a regional-scale shift in stock-recruitment relationships of corals along the Great Barrier Reef-the world's largest coral reef system-following unprecedented back-to-back mass bleaching events caused by global warming. As a consequence of mass mortality of adult brood stock in 2016 and 2017 owing to heat stress(6), the amount of larval recruitment declined in 2018 by 89% compared to historical levels. For the first time, brooding pocilloporids replaced spawning acroporids as the dominant taxon in the depleted recruitment pool. The collapse in stock-recruitment relationships indicates that the low resistance of adult brood stocks to repeated episodes of coral bleaching is inexorably tied to an impaired capacity for recovery, which highlights the multifaceted processes that underlie the global decline of coral reefs. The extent to which the Great Barrier Reef will be able to recover from the collapse in stock-recruitment relationships remains uncertain, given the projected increased frequency of extreme climate events over the next two decades(7).

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Nature

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Volume

568

ISBN/ISSN

1476-4687

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Issue

7752

Pages Count

14

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Publisher

Nature Publishing Group

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DOI

10.1038/s41586-019-1081-y