The biogeography of thermal risk for terrestrial ectotherms: Scaling of thermal tolerance with body size and latitude
- PMID: 31990044
- DOI: 10.1111/1365-2656.13181
The biogeography of thermal risk for terrestrial ectotherms: Scaling of thermal tolerance with body size and latitude
Abstract
Many organisms are shrinking in size in response to global warming. However, we still lack a comprehensive understanding of the mechanisms linking body size and temperature of organisms across their geographical ranges. Here we investigate the biophysical mechanisms determining the scaling of body temperature with size across latitudes in terrestrial ectotherms. Using biophysical models, we simulated operative temperatures experienced by lizard-like ectotherms as a function of microclimatic variables, body mass and latitude and used them to generate null predictions for the effect of size on temperature across geographical gradients. We then compared model predictions against empirical data on lizards' field body temperature (Tb ) and thermal tolerance limits (CTmax and CTmin ). Our biophysical models predict that the allometric scaling of operative temperatures with body size varies with latitude, with a positive relationship at low latitudes that vanishes with increasing latitude. The analyses of thermal traits of lizards show a significant interaction of body size and latitude on Tb and CTmax and no effect of body mass on CTmin , consistent with model's predictions. The estimated scaling coefficients are within the ranges predicted by the biophysical model. The effect of body mass, however, becomes non-significant after controlling for the phylogenetic relatedness between species. We propose that large-bodied terrestrial ectotherms exhibit higher risk of overheating at low latitudes, while size differences in thermal sensitivity vanish towards higher latitudes. Our work highlights the potential of combining mechanistic models with empirical data to investigate the mechanisms underpinning broad-scale patterns and ultimately provide a null model to develop baseline expectations for further empirical research.
Keywords: Bergmann's rule; biophysical modelling; body size gradients; macrophysiology; mechanistic modelling.
© 2020 British Ecological Society.
References
REFERENCES
-
- Angilletta, M. J. Jr, & Dunham, A. E. (2003). The temperature-size rule in ectotherms: Simple evolutionary explanations may not be general. The American Naturalist, 162, 332-342. https://doi.org/10.1086/377187
-
- Bakken, G. S. (1992). Measurement and application of operative and standard operative temperatures in ecology. American Zoologist, 32, 194-216. https://doi.org/10.1093/icb/32.2.194
-
- Bakken, G. S., & Gates, D. M. (1975). Heat-transfer analysis of animals: Some implications for field ecology, physiology, and evolution. In D. M. Gates & R. B. Schmerl (Eds.), Perspectives of biophysical ecology (pp. 255-290). Berlin, Heidelberg: Springer.
-
- Baudier, K. M., Mudd, A. E., Erickson, S. C., & O'Donnell, S. (2015). Microhabitat and body size effects on heat tolerance: Implications for responses to climate change (army ants: Formicidae, Ecitoninae). Journal of Animal Ecology, 84, 1322-1330. https://doi.org/10.1111/1365-2656.12388
-
- Bennett, J. M., Calosi, P., Clusella-Trullas, S., Martínez, B., Sunday, J., Algar, A. C., … Morales-Castilla, I. (2018). GlobTherm, a global database on thermal tolerances for aquatic and terrestrial organisms. Scientific Data, 5, 180022. https://doi.org/10.1038/sdata.2018.22
Publication types
MeSH terms
Associated data
LinkOut - more resources
Full Text Sources
Other Literature Sources
