Metabolic heat production and thermal conductance are mass-independent adaptations to thermal environment in birds and mammals

Fristoe, Trevor S.; Burger, Joseph R.; Balk, Meghan A.; Khaliq, Imran; Hof, Christian; Brown, James H.

doi:10.1073/pnas.1521662112

Cited by 83 publications

(117 citation statements)

References 33 publications

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“…Within the thermoneutral zone, metabolic heat production exactly balances the heat dissipated, which is chiefly a function of surface area. However, as the cross-surface temperature differential increases, the metabolic scaling slope should approach~0.45-0.55, as typically observed for the scaling of thermal conductance in birds and mammals [6,[79][80][81][82][83][84][85][86]. As predicted, when T a equals 0 • C (which is greater than 30 • C below T b ), the metabolic scaling exponents for mammals (0.40), passerine birds (0.52) and nonpasserine birds (0.53) ( [56,58]; Figures 3 and 4) all approach that observed for the scaling exponent of thermal conductance.…”

Section: Implications Of Results For Theorymentioning

confidence: 83%

Effects of Contingency versus Constraints on the Body-Mass Scaling of Metabolic Rate

Glazier

2018

Challenges

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I illustrate the effects of both contingency and constraints on the body-mass scaling of metabolic rate by analyzing the significantly different influences of ambient temperature (T a ) on metabolic scaling in ectothermic versus endothermic animals. Interspecific comparisons show that increasing T a results in decreasing metabolic scaling slopes in ectotherms, but increasing slopes in endotherms, a pattern uniquely predicted by the metabolic-level boundaries hypothesis, as amended to include effects of the scaling of thermal conductance in endotherms outside their thermoneutral zone. No other published theoretical model explicitly predicts this striking variation in metabolic scaling, which I explain in terms of contingent effects of T a and thermoregulatory strategy in the context of physical and geometric constraints related to the scaling of surface area, volume, and heat flow across surfaces. My analysis shows that theoretical models focused on an ideal 3/4-power law, as explained by a single universally applicable mechanism, are clearly inadequate for explaining the diversity and environmental sensitivity of metabolic scaling. An important challenge is to develop a theory of metabolic scaling that recognizes the contingent effects of multiple mechanisms that are modulated by several extrinsic and intrinsic factors within specified constraints.

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Section: Implications Of Results For Theorymentioning

confidence: 83%

Effects of Contingency versus Constraints on the Body-Mass Scaling of Metabolic Rate

Glazier

2018

Challenges

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“…) and basal metabolic rate (Fristoe et al. ). Specifically among rodents, kidney function (MacMillen and Lee ; Giorello et al.…”

Section: Discussionmentioning

confidence: 99%

Environment predicts repeated body size shifts in a recent radiation of Australian mammals*

2019

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Closely related species that occur across steep environmental gradients often display clear body size differences, and examining this pattern is crucial to understanding how environmental variation shapes diversity. Australian endemic rodents in the Pseudomys Division (Muridae: Murinae) have repeatedly colonized the arid, monsoon, and mesic biomes over the last 5 million years. Using occurrence records, body mass data, and Bayesian phylogenetic models, we test whether body mass of 31 species in the Pseudomys Division can be predicted by their biome association. We also model the effect of eight environmental variables on body mass. Despite high phylogenetic signal in body mass evolution across the phylogeny, we find that mass predictably increases in the mesic biome and decreases in arid and monsoon biomes. As per Bergmann's rule, temperature is strongly correlated with body mass, as well as several other variables. Our results highlight two important findings. First, body size in Australian rodents has tracked with climate through the Pleistocene, likely due to several environmental variables rather than a single factor. Second, support for both Brownian motion and predictable change at different taxonomic levels in the Pseudomys Division phylogeny demonstrates how the level at which we test hypotheses can alter interpretation of evolutionary processes.

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“…Those MR values reported in watts were converted to oxygen consumption assuming a factor of 179 ml O 2 h −1 W −1 , which corresponds to lipid metabolism (Schmidt‐Nielsen, ). Minimum conductance was estimated as the absolute value of the slope of the line connecting T lc at BMR to T b when metabolic rate is 0: C min = |(0‐BMR)/( T b − T lc )|(Fristoe et al, ; Scholander et al, ). This assumption is often violated by conductance continuing to decline below the T lc , but we feel that the estimate approach best balances accuracy and viability.…”

Section: Methodsmentioning

confidence: 99%

“…Here we leverage extensive metabolic, distribution, and phylogenetic datasets (Fristoe et al, ; Khaliq, Hof, Prinzinger, Böhning‐Gaese, & Pfenninger, ) to test the viability of using metabolic constraints to project bird and mammal distributions. Specifically, we estimate the factor by which metabolism is elevated at the cold range boundaries (metabolic expansibility, ME CRB ).…”

Section: Introductionmentioning

confidence: 99%

Does metabolism constrain bird and mammal ranges and predict shifts in response to climate change?

Buckley

Khaliq

Swanson

et al. 2018

Ecology and Evolution

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Mechanistic approaches for predicting the ranges of endotherms are needed to forecast their responses to environmental change. We test whether physiological constraints on maximum metabolic rate and the factor by which endotherms can elevate their metabolism (metabolic expansibility) influence cold range limits for mammal and bird species. We examine metabolic expansibility at the cold range boundary (MECRB) and whether species’ traits can predict variability in MECRB and then use MECRB as an initial approach to project range shifts for 210 mammal and 61 bird species. We find evidence for metabolic constraints: the distributions of metabolic expansibility at the cold range boundary peak at similar values for birds (2.7) and mammals (3.2). The right skewed distributions suggest some species have adapted to elevate or evade metabolic constraints. Mammals exhibit greater skew than birds, consistent with their diverse thermoregulatory adaptations and behaviors. Mammal and bird species that are small and occupy low trophic levels exhibit high levels of MECRB. Mammals with high MECRB tend to hibernate or use torpor. Predicted metabolic rates at the cold range boundaries represent large energetic expenditures (>50% of maximum metabolic rates). We project species to shift their cold range boundaries poleward by an average of 3.9° latitude by 2070 if metabolic constraints remain constant. Our analysis suggests that metabolic constraints provide a viable mechanism for initial projections of the cold range boundaries for endotherms. However, errors and approximations in estimating metabolic constraints (e.g., acclimation responses) and evasion of these constraints (e.g., torpor/hibernation, microclimate selection) highlight the need for more detailed, taxa‐specific mechanistic models. Even coarse considerations of metabolism will likely lead to improved predictions over exclusively considering thermal tolerance for endotherms.

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Metabolic heat production and thermal conductance are mass-independent adaptations to thermal environment in birds and mammals

Cited by 83 publications

References 33 publications

Effects of Contingency versus Constraints on the Body-Mass Scaling of Metabolic Rate

Effects of Contingency versus Constraints on the Body-Mass Scaling of Metabolic Rate

Environment predicts repeated body size shifts in a recent radiation of Australian mammals*

Does metabolism constrain bird and mammal ranges and predict shifts in response to climate change?

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