Mokhatla M et al. (2019), The role of ambient temperature and body mass o...

XB-ART-56424

PeerJ 2019 May 01;7:e7885. doi: 10.7717/peerj.7885.

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The role of ambient temperature and body mass on body temperature, standard metabolic rate and evaporative water loss in southern African anurans of different habitat specialisation.

Mokhatla M , Measey J , Smit B .

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Temperature and water availability are two of the most important variables affecting all aspects of an anuran's key physiological processes such as body temperature (Tb), evaporative water loss (EWL) and standard metabolic rate (SMR). Since anurans display pronounced sexual dimorphism, evidence suggests that these processes are further influenced by other factors such as vapour pressure deficit (VPD), sex and body mass (Mb). However, a limited number of studies have tested the generality of these results across a wide range of ecologically relevant ambient temperatures (Ta), while taking habitat use into account. Thus, the aim of this study was to investigate the role of Ta on Tb, whole-animal EWL and whole-animal SMR in three wild caught African anuran species with different ecological specialisations: the principally aquatic African clawed frog (Xenopus laevis), stream-breeding common river frog (Amietia delalandii), and the largely terrestrial raucous toad (Sclerophrys capensis). Experiments were conducted at a range of test temperatures (5-35 °C, at 5 °C increments). We found that VPD better predicted rates of EWL than Ta in two of the three species considered. Moreover, we found that Tb, whole-animal EWL and whole-animal SMR increased with increasing Ta, while Tb increased with increasing Mb in A. delalandii and S. capensis but not in X. laevis. Whole-animal SMR increased with increasing Mb in S. capensis only. We did not find any significant effect of VPD, Mb or sex on whole-animal EWL within species. Lastly, Mb did not influence Tb, whole-animal SMR and EWL in the principally aquatic X. laevis. These results suggest that Mb may not have the same effect on key physiological variables, and that the influence of Mb may also depend on the species ecological specialisation. Thus, the generality of Mb as an important factor should be taken in the context of both physiology and species habitat specialisation.

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	Figure 1. Increasing body temperature as a function of ambient temperature in African anurans.Relationship between Ta and Tb of different functional groups over a range of different test ambient temperatures (Ta). The solid line indicates Y = X relationship representing a typical 1:1 Ta vs Tb relationship depicting an amphibian incapable of regulating Tb through physiological or behavioural means. This highlights how Tb deviates from Ta particularly at low and high Ta.
	Figure 2. Increasing rates of evaporative water loss (EWL) as a function of temperature in african anurans.Data points represents the relationship between whole-animal EWL (as represented by VH2O) and body temperature (Tb ) at each of the test temperatures. Vertical error bars represents the variation (Standard Error: SE) in whole-animal EWL and the horizontal error bars represents the variation (SE) in body temperature.
	Figure 3. Increasing standard metabolic rates (measured as oxygen consumption, VO2) as a function of temperature in African anurans.Data points represents the relationship between whole-animal SMR and body temperature (Tb) at each of the test temperatures. Vertical error bars represents the variation (Standard Error: SE) in whole-animal SMR and the horizontal error bars represents the variation (SE) in Tb.