Metabolic plasticity improves lobster’s resilience to ocean warming but not to climate-driven novel species interactions

Marine species not only suffer from direct effects of warming oceans but also indirectly via the emergence of novel species interactions. While metabolic adjustments can be crucial to improve resilience to warming, it is largely unknown if this improves performance relative to novel competitors. We...

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Bibliographic Details
Published in:Scientific reports 2022-03, Vol.12 (1), p.4412-4412, Article 4412
Main Authors: Oellermann, Michael, Fitzgibbon, Quinn P., Twiname, Samantha, Pecl, Gretta T.
Format: Article
Language:English
Subjects:
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Acclimation
Acclimatization
Animals
Australia
Climate Change
Crustaceans
Environmental impact
Geographical distribution
Global Warming
Humanities and Social Sciences
Jasus edwardsii
Metabolic rate
Metabolism
multidisciplinary
Ocean warming
Oceans
Oceans and Seas
Palinuridae
Palinuridae - physiology
Sagmariasus verreauxi
Science
Science (multidisciplinary)
Shellfish
Species
Summer
Temperature
Temperature effects
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Summary:Marine species not only suffer from direct effects of warming oceans but also indirectly via the emergence of novel species interactions. While metabolic adjustments can be crucial to improve resilience to warming, it is largely unknown if this improves performance relative to novel competitors. We aimed to identify if spiny lobsters—inhabiting a global warming and species re-distribution hotspot—align their metabolic performance to improve resilience to both warming and novel species interactions. We measured metabolic and escape capacity of two Australian spiny lobsters, resident Jasus edwardsii and the range-shifting Sagmariasus verreauxi, acclimated to current average—(14.0 °C), current summer—(17.5 °C) and projected future summer—(21.5 °C) habitat temperatures. We found that both species decreased their standard metabolic rate with increased acclimation temperature, while sustaining their scope for aerobic metabolism. However, the resident lobster showed reduced anaerobic escape performance at warmer temperatures and failed to match the metabolic capacity of the range-shifting lobster. We conclude that although resident spiny lobsters optimise metabolism in response to seasonal and future temperature changes, they may be unable to physiologically outperform their range-shifting competitors. This highlights the critical importance of exploring direct as well as indirect effects of temperature changes to understand climate change impacts.
ISSN:2045-2322
2045-2322
DOI:10.1038/s41598-022-08208-x