The upper limit of thermoneutrality is not indicative of thermotolerance in bats.

To assess the vulnerability of birds and mammals to climate change recent studies have used the upper critical limit of thermoneutrality (T) as an indicator of thermal tolerance. But, the association between T and thermal tolerance is not straightforward and most studies describe T based solely on a deviation in metabolism from basal levels, without also considering the onset of evaporative cooling. It was argued recently that certain torpor-using bat species who survived prolonged exposure to high ambient temperatures (i.

Non-Torpid Heterothermy in Mammals: Another Category along the Homeothermy-Hibernation Continuum.

Variability in body temperature is now recognized to be widespread among whole-body endotherms with homeothermy being the exception rather than the norm. A wide range of body temperature patterns exists in extant endotherms, spanning from strict homeothermy, to occasional use of torpor, to deep seasonal hibernation with many points in between. What is often lost in discussions of heterothermy in endotherms are the benefits of variations in body temperature outside of torpor.

High Body Temperature is an Unlikely Cause of High Viral Tolerance in Bats.

The global SARS-CoV-2 pandemic and the role of bats in zoonotic spillover have renewed interest in the flight-as-fever hypothesis, which posits that high body temperatures experienced by bats during flight contribute to their high viral tolerance. We argue that flight-as-fever is unlikely to explain why bats harbor more viruses than other mammals on the basis of two lines of reasoning. First, flight temperatures reported in the literature overestimate true flight temperatures because of methodologic limitations.

Transcriptional host-pathogen responses of and three species of bats with white-nose syndrome.

Understanding how context (e.g., host species, environmental conditions) drives disease susceptibility is an essential goal of disease ecology.