Phylogenetic differences of mammalian basal metabolic rate are not explained by mitochondrial basal proton leak

Polymeropoulos, Elias T.; Heldmaier, Gerhard; Frappell, Peter B.; McAllan, Bronwyn M.; Withers, Kerry; Klingenspor, Martin; White, Craig R.; Jastroch, Martin

doi:10.1098/rspb.2011.0881

Cited by 30 publications

(30 citation statements)

References 49 publications

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“…This is due to a decrease in the mitochondrial proton conductance in the heaviest individuals. Interestingly, the negative relationship found between mitochondrial proton leak and M b in frogs is similar to that in endothermic groups such as mammals (Porter and Brand, 1993), including marsupials (Polymeropoulos et al, 2012), and birds . Finally, and in contrast to our prediction, we found that liver mitochondria from the larger individuals produced significantly lower levels of ROS than those from the smaller animals.…”

Section: Discussionmentioning

confidence: 51%

“…However, such interspecific correlation between mammalian M b and mitochondrial ROS generation is not systematically found, being mostly revealed when isolated mitochondria oxidize succinate in the absence of rotenone (Lambert et al, 2007) or when cells are metabolically stressed (Csiszar et al, 2012). However, it is apparent that the negative relationship reported between M b and proton leak (Porter and Brand, 1993;Porter et al, 1996;Polymeropoulos et al, 2012) cannot be associated with a positive allometric variation in ROS generation (Sohal et al, 1989(Sohal et al, , 1990Ku et al, 1993;Lambert et al, 2007;Csiszar et al, 2012). A similar result has been found in birds, with M b shown to be negatively correlated with both proton leak and ROS generation in liver mitochondria respiring on succinate (Lambert et al, 2007;Montgomery et al, 2012).…”

Section: Discussionmentioning

confidence: 66%

“…The differences in results between studies may simply reflect the disparate nature of the ectotherm species used in each study (fishes, toads, lizards, crocodiles, snails) in addition to the temperature and tissue studied (kidney, liver, skeletal muscle). Although the data were collected from a small number of frog species, they suggest that the negative relationship between proton conductance and M b that is seen in endotherms (Porter and Brand, 1993;Porter et al, 1996;Polymeropoulos et al, 2012) may also occur in frogs. However, this may not necessarily be the case for all groups of ectotherms (Hulbert et al, 2002), as suggested in reptiles, where proton conductance of liver mitochondria from crocodiles appears greater than that of smaller reptiles (Brookes et al, 1998;Hulbert et al, 2002).…”

Section: Discussionmentioning

confidence: 99%

“…Allometric relationships of proton leak and oxidative activity with animal body size have been observed in the liver mitochondria of endotherms Porter and Brand, 1993;Porter et al, 1996;Polymeropoulos et al, 2012). Proton leak refers to the mechanism where motive force is dissipated through the mitochondrial inner membrane proton conductance pathways independently of ATP synthase.…”

Section: Introductionmentioning

confidence: 99%

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Oxidative phosphorylation efficiency, proton conductance and reactive oxygen species production of liver mitochondria correlates with body mass in frogs

Roussel

Salin

Dumet

et al. 2015

Journal of Experimental Biology

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Body size is a central biological parameter affecting most biological processes (especially energetics) and the mitochondrion is a key organelle controlling metabolism and is also the cell's main source of chemical energy. However, the link between body size and mitochondrial function is still unclear, especially in ectotherms. In this study, we investigated several parameters of mitochondrial bioenergetics in the liver of three closely related species of frog (the common frog Rana temporaria, the marsh frog Pelophylax ridibundus and the bull frog Lithobates catesbeiana). These particular species were chosen because of their differences in adult body mass. We found that mitochondrial coupling efficiency was markedly increased with animal size, which led to a higher ATP production (+70%) in the larger frogs (L. catesbeiana) compared with the smaller frogs (R. temporaria). This was essentially driven by a strong negative dependence of mitochondrial proton conductance on body mass. Liver mitochondria from the larger frogs (L. catesbeiana) displayed 50% of the proton conductance of mitochondria from the smaller frogs (R. temporaria). Contrary to our prediction, the low mitochondrial proton conductance measured in L. catesbeiana was not associated with higher reactive oxygen species production. Instead, liver mitochondria from the larger individuals produced significantly lower levels of radical oxygen species than those from the smaller frogs. Collectively, the data show that key bioenergetics parameters of mitochondria (proton leak, ATP production efficiency and radical oxygen species production) are correlated with body mass in frogs. This research expands our understanding of the relationship between mitochondrial function and the evolution of allometric scaling in ectotherms.

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Section: Discussionmentioning

confidence: 51%

Section: Discussionmentioning

confidence: 66%

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Oxidative phosphorylation efficiency, proton conductance and reactive oxygen species production of liver mitochondria correlates with body mass in frogs

Roussel

Salin

Dumet

et al. 2015

Journal of Experimental Biology

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“…Recent investigators have implicated membrane composition and function [89,167,179,234], mitochondrial activity and number [97,179,[235][236][237], intracellular transport costs [130], DNA content [182,190], and other biochemical factors [238], as importantly involved in the intrinsic cellular control of metabolic scaling. Evidence for and against various specific aspects of this approach can be found in [19,20,89,[91][92][93][94]130,167,169,[235][236][237][238][239][240][241][242][243]. A major limitation of the cell-based RD approach is that it cannot explain by itself why the hypometric scaling of cellular metabolic rate is lost in cells cultured in vivo (reviewed in [20,97]).…”

Section: Resource-demand Modelsmentioning

confidence: 99%

Rediscovering and Reviving Old Observations and Explanations of Metabolic Scaling in Living Systems

Glazier

2018

Systems

112

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Why the rate of metabolism varies (scales) in regular, but diverse ways with body size is a perennial, incompletely resolved question in biology. In this article, I discuss several examples of the recent rediscovery and (or) revival of specific metabolic scaling relationships and explanations for them previously published during the nearly 200-year history of allometric studies. I carry out this discussion in the context of the four major modal mechanisms highlighted by the contextual multimodal theory (CMT) that I published in this journal four years ago. These mechanisms include metabolically important processes and their effects that relate to surface area, resource transport, system (body) composition, and resource demand. In so doing, I show that no one mechanism can completely explain the broad diversity of metabolic scaling relationships that exists. Multi-mechanistic models are required, several of which I discuss. Successfully developing a truly general theory of biological scaling requires the consideration of multiple hypotheses, causal mechanisms and scaling relationships, and their integration in a context-dependent way. A full awareness of the rich history of allometric studies, an openness to multiple perspectives, and incisive experimental and comparative tests can help this important quest.

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Adding Fuel to the “Fire of Life”: Energy Budgets across Levels of Variation in Ectotherms and Endotherms

Careau

Killen

Metcalfe

2014

Integrative Organismal Biology

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Phylogenetic differences of mammalian basal metabolic rate are not explained by mitochondrial basal proton leak

Cited by 30 publications

References 49 publications

Oxidative phosphorylation efficiency, proton conductance and reactive oxygen species production of liver mitochondria correlates with body mass in frogs

Oxidative phosphorylation efficiency, proton conductance and reactive oxygen species production of liver mitochondria correlates with body mass in frogs

Rediscovering and Reviving Old Observations and Explanations of Metabolic Scaling in Living Systems

Adding Fuel to the “Fire of Life”: Energy Budgets across Levels of Variation in Ectotherms and Endotherms

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