Individual (Co)variation in Resting and Maximal Metabolic Rates in Wild Mice.

AbstractBasal metabolic rate (BMR) represents the lowest level of aerobic metabolism in a resting, postabsorptive endotherm as measured within the thermoneutral zone. By contrast, maximal metabolic rate ([Formula: see text]max) reflects the upper limit of aerobic metabolism achieved during intensive exercise. As BMR and [Formula: see text]max define the boundaries of the possible levels of aerobic metabolism expressed by a normothermic individual, a key question is whether BMR and [Formula: see text]max are correlated. In the present study, we took repeated paired measurements of thermoneutral resting metabolic rate (RMRt) and [Formula: see text]max on 165 white-footed mice (Peromyscus leucopus). Over a single summer (May-October), repeatability (R ± SE) was low but statistically significant ([Formula: see text]) for both RMRt and [Formula: see text]max ([Formula: see text] for RMRt; [Formula: see text] for [Formula: see text]max). Willingness to run during the forced-exercise trials was also significantly repeatable ([Formula: see text]). At the residual level (within individual), RMRt and [Formula: see text]max tended to be positively correlated ([Formula: see text], [Formula: see text]), suggesting the presence of correlated phenotypic plasticity. By contrast, RMRt and [Formula: see text]max were significantly negatively correlated at the among-individual level ([Formula: see text]). To the extent that variation in RMRt reflects variation in BMR, the negative among-individual correlation does not corroborate the idea that a costly metabolic machinery is needed to support a high [Formula: see text]max. Future research should investigate the (genetic) relationship between RMRt (and BMR) and other energetically expensive behaviors and activities to better understand how energy is allocated within individuals.

Phylogenetic analysis of macroecological patterns of home range area in snakes.

A home range is the area animals use to carry out routine activities such as mating, foraging, and caring for young. Thus, the area of a home range is an important indicator of an animal's behavioural and energetic requirements. While several studies have identified the factors that influence home range area (HRA), none of them has investigated global patterns of HRA among and within snake species. Here, we used a phylogenetic mixed model to determine which factors influence HRA in 51 snake species. We analysed 200 HRA estimates to test the influence of body mass, sex, age, diet, precipitation, latitude, winter and summer temperature, while controlling for the duration of the study and sample size. We found that males had larger HRA than females, that adults had larger HRA than juveniles, and that snake species with fish-based diets had smaller HRA than snake species with terrestrial vertebrate-based and invertebrate-based diets. We also found that HRA tended to increase as mean winter temperature decreases and tended to decrease with precipitation. After accounting for these factors, the phylogenetic heritability of HRA in snakes was low (0.21 ± 0.14). Determining the factors that dictate macroecological patterns of space use has important management implications in an era of rapid climate change.