ABSTRACT
Ectotherm vulnerability to climate change is predicted to increase with temperature variation. Still, translating laboratory observations of organisms' heat-stress responses to the natural fluctuating environment remains challenging. In this study, we used an integrative framework combining insights from thermal death time (TDT) curves and physiological reaction norms to precisely capture Pinctada margaritifera’s thermal performance and tolerance landscape. We then applied this integrative model to predict individuals' cumulative heat injury as a function of actual temperature conditions documented at five contrasting islands across French Polynesia. Substantial injury was predicted for spats (ranging from 30.24% to 29.62%) when exposed to eight consecutive extreme low tide events in Nuku Hiva. Overall, this study highlights the potential of this framework to effectively quantify the impact of extreme events, such as marine heatwaves, and to guide resource management initiatives.
Footnotes
Author contributions
Conceptualization: K.L., J.L.L.; Data curation: K.L., E.V., M.S.K., J.L.L.; Investigation: K.L.; Methodology: K.L., J.L.L.; Supervision: C.J.M., J.L.L.; Validation: J.V.-D., G.M., J.L.L.; Writing – original draft: K.L., C.J.M., J.L.L.; Writing – review & editing: K.L., C.J.M., J.V.-D., J.L.L.
Funding
This study was supported by the PinctAdapt project.
Data availability
The dataset is available from the Dryad digital repository: https://doi.org/10.5061/dryad.hdr7sqvt2.
