Abstract
Due to their highly permeable skin and ectothermy, terrestrial amphibians are challenged by compromises between water balance and body temperature regulation. The way in which such compromises are accommodated, under a range of temperatures and dehydration levels, impacts importantly the behavior and ecology of amphibians. Thus, using the terrestrial toad Rhinella schneideri as a model organism, the goals of this study were twofold. First, we determined how the thermal sensitivity of a centrally relevant trait—locomotion—was affected by dehydration. Secondly, we examined the effects of the same levels of dehydration on thermal preference and thermal tolerance. As dehydration becomes more severe, the optimal temperature for locomotor performance was lowered and performance breadth narrower. Similarly, dehydration was accompanied by a decrease in the thermal tolerance range. Such a decrease was caused by both an increase in the critical minimal temperature and a decrease in the thermal maximal temperature, with the latter changing more markedly. In general, our results show that the negative effects of dehydration on behavioral performance and thermal tolerance are, at least partially, counteracted by concurrent adjustments in thermal preference. We discuss some of the potential implications of this observation for the conservation of anuran amphibians.
Highlights
In common with other ectotherms, amphibians often engage in activities in temperatures that may not allow optimal performance
For the determination of the thermal performance curves, we focused on locomotor performance because foraging, reproduction, escape from predators, and many other ecologically relevant activities are inextricably associated with locomotion in anuran amphibians (Prates et al 2013 and references therein)
Optimal temperatures for locomotor performance (To) and performance breadth (B80) both decreased with dehydration
Summary
The influence of temperature and hydration state on behavioral performance can be investigated by determining thermal performance curves (TPCs) at different levels of body hydration (Huey & Stevenson 1979; Beuchat, Pough & Stewart 1984; Huey & Kingsolver 1989; Preest & Pough 1989; Angilletta, Huey & Frazier 2010). Toads exhibited a decrease in their preferred body temperature (Tpref) associated with dehydration (Williams & Wygoda 1993) or even with the exposition to dry air (Malvin & Wood 1991) This dehydration-driven hypothermic response is thought to be of functional and ecological relevance because the potential for evaporative water loss is diminished at low body temperatures (Bundy & Tracy 1977; Tracy et al 1993; Mitchell & Bergmann 2016).
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