Hydric effects on thermal tolerances influence climate vulnerability in a high-latitude beetle

Eric A Riddell; Marko Mutanen; Cameron K Ghalambor

doi:10.1111/gcb.16830

Hydric effects on thermal tolerances influence climate vulnerability in a high-latitude beetle

Glob Chang Biol. 2023 Sep;29(18):5184-5198. doi: 10.1111/gcb.16830. Epub 2023 Jun 27.

Authors

Eric A Riddell¹, Marko Mutanen², Cameron K Ghalambor^{3

4}

Affiliations

¹ Department of Ecology, Evolutionary, and Organismal Biology, Iowa State University, Ames, Iowa, USA.
² Ecology and Genetics Research Unit, University of Oulu, Oulu, Finland.
³ Department of Biology and Graduate Degree Program in Ecology, Norwegian University of Science and Technology, Trondheim, Norway.
⁴ Department of Biology, Colorado State University, Fort Collins, Colorado, USA.

PMID: 37376709
DOI: 10.1111/gcb.16830

Abstract

Species' thermal tolerances are used to estimate climate vulnerability, but few studies consider the role of the hydric environment in shaping thermal tolerances. As environments become hotter and drier, organisms often respond by limiting water loss to lower the risk of desiccation; however, reducing water loss may produce trade-offs that lower thermal tolerances if respiration becomes inhibited. Here, we measured the sensitivity of water loss rate and critical thermal maximum (CT_max ) to precipitation in nature and laboratory experiments that exposed click beetles (Coleoptera: Elateridae) to acute- and long-term humidity treatments. We also took advantage of their unique clicking behavior to characterize subcritical thermal tolerances. We found higher water loss rates in the dry acclimation treatment compared to the humid, and water loss rates were 3.2-fold higher for individuals that had experienced a recent precipitation event compared to individuals that had not. Acute humidity treatments did not affect CT_max , but precipitation indirectly affected CT_max through its effect on water loss rates. Contrary to our prediction, we found that CT_max was negatively associated with water loss rate, such that individuals with high water loss rate exhibited a lower CT_max . We then incorporated the observed variation of CT_max into a mechanistic niche model that coupled leaf and click beetle temperatures to predict climate vulnerability. The simulations indicated that indices of climate vulnerability can be sensitive to the effects of water loss physiology on thermal tolerances; moreover, exposure to temperatures above subcritical thermal thresholds is expected to increase by as much as 3.3-fold under future warming scenarios. The correlation between water loss rate and CT_max identifies the need to study thermal tolerances from a "whole-organism" perspective that considers relationships between physiological traits, and the population-level variation in CT_max driven by water loss rate complicates using this metric as a straightforward proxy of climate vulnerability.

Keywords: climate change; climate vulnerability; mechanistic niche model; precipitation; thermal tolerance; water loss rates.

MeSH terms

Acclimatization
Animals
Climate
Climate Change
Coleoptera*
Temperature
Water

Substances

Water

Grants and funding

201710256/Kone Foundation