Allometry of mitochondrial efficiency is set by metabolic intensity

Boël Mélanie, Romestaing Caroline, Voituron Yann, Roussel Damien
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引用次数: 20

Abstract

Metabolic activity sets the rates of individual resource uptake from the environment and resource allocations. For this reason, the relationship with body size has been heavily documented from ecosystems to cells. Until now, most of the studies used the fluxes of oxygen as a proxy of energy output without knowledge of the efficiency of biological systems to convert oxygen into ATP. The aim of this study was to examine the allometry of coupling efficiency (ATP/O) of skeletal muscle mitochondria isolated from 12 mammal species ranging from 6 g to 550 kg. Mitochondrial efficiencies were measured at different steady states of phosphorylation. The efficiencies increased sharply at higher metabolic rates. We have shown that body mass dependence of mitochondrial efficiency depends on metabolic intensity in skeletal muscles of mammals. Mitochondrial efficiency positively depends on body mass when mitochondria are close to the basal metabolic rate; however, the efficiency is independent of body mass at the maximum metabolic rate. As a result, it follows that large mammals exhibit a faster dynamic increase in ATP/O than small species when mitochondria shift from basal to maximal activities. Finally, the invariant value of maximal coupling efficiency across mammal species could partly explain why scaling exponent values are very close to 1 at maximal metabolic rates.
线粒体效率异速测定是由代谢强度决定的
代谢活动决定了个体从环境中摄取资源的速率和资源分配。由于这个原因,从生态系统到细胞,与体型的关系已经被大量记录。到目前为止,大多数研究使用氧气通量作为能量输出的代表,而不了解生物系统将氧气转化为ATP的效率。本研究的目的是研究12种哺乳动物骨骼肌线粒体偶联效率(ATP/O)的异速测定,范围从6 g到550 kg。在不同的磷酸化稳定状态下测量线粒体效率。代谢率越高,效率越高。我们已经表明,体重对线粒体效率的依赖取决于哺乳动物骨骼肌的代谢强度。当线粒体接近基础代谢率时,线粒体效率与体重呈正相关;然而,在最大代谢率下,效率与体重无关。因此,当线粒体从基础活动向最大活动转变时,大型哺乳动物比小型哺乳动物表现出更快的ATP/O动态增长。最后,哺乳动物物种之间最大耦合效率的不变值可以部分解释为什么在最大代谢率下缩放指数值非常接近1。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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