Respiration and substrate transport rates as well as reactive oxygen species production distinguish mitochondria from brain and liver.

Q2 Biochemistry, Genetics and Molecular Biology

BMC Biochemistry Pub Date : 2015-09-10 DOI:10.1186/s12858-015-0051-8

Aaron M Gusdon, Gabriel A Fernandez-Bueno, Stephanie Wohlgemuth, Jenelle Fernandez, Jing Chen, Clayton E Mathews

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Abstract

Background: Aberrant mitochondrial function, including excessive reactive oxygen species (ROS) production, has been implicated in the pathogenesis of human diseases. The use of mitochondrial inhibitors to ascertain the sites in the electron transport chain (ETC) resulting in altered ROS production can be an important tool. However, the response of mouse mitochondria to ETC inhibitors has not been thoroughly assessed. Here we set out to characterize the differences in phenotypic response to ETC inhibitors between the more energetically demanding brain mitochondria and less energetically demanding liver mitochondria in commonly utilized C57BL/6J mice.

Results: We show that in contrast to brain mitochondria, inhibiting distally within complex I or within complex III does not increase liver mitochondrial ROS production supported by complex I substrates, and liver mitochondrial ROS production supported by complex II substrates occurred primarily independent of membrane potential. Complex I, II, and III enzymatic activities and membrane potential were equivalent between liver and brain and responded to ETC. inhibitors similarly. Brain mitochondria exhibited an approximately two-fold increase in complex I and II supported respiration compared with liver mitochondria while exhibiting similar responses to inhibitors. Elevated NADH transport and heightened complex II-III coupled activity accounted for increased complex I and II supported respiration, respectively in brain mitochondria.

Conclusions: We conclude that important mechanistic differences exist between mouse liver and brain mitochondria and that mouse mitochondria exhibit phenotypic differences compared with mitochondria from other species.

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线粒体的呼吸作用和底物转运率以及活性氧的产生使其与大脑和肝脏区分开来。

背景：线粒体功能异常，包括活性氧（ROS）产生过多，已被认为与人类疾病的发病机制有关。使用线粒体抑制剂来确定电子传递链（ETC）中导致 ROS 生成改变的位点是一种重要的工具。然而，小鼠线粒体对 ETC 抑制剂的反应尚未得到全面评估。在这里，我们试图描述常用的 C57BL/6J 小鼠中对能量要求较高的脑线粒体和对能量要求较低的肝线粒体对 ETC 抑制剂的表型反应差异：我们发现，与脑线粒体不同的是，抑制复合物 I 或复合物 III 的远端并不会增加肝线粒体在复合物 I 底物支持下产生的 ROS，而肝线粒体在复合物 II 底物支持下产生的 ROS 主要与膜电位无关。肝脏和大脑的复合体 I、II 和 III 酶活性和膜电位相同，对 ETC 抑制剂的反应也相似。与肝脏线粒体相比，脑线粒体的复合物 I 和 II 支持呼吸增加了约两倍，同时对抑制剂的反应也相似。NADH转运的增加和复合体II-III偶联活性的提高分别是脑线粒体中复合体I和II支持呼吸增加的原因：我们得出结论：小鼠肝脏线粒体和脑线粒体之间存在重要的机理差异，而且小鼠线粒体与其他物种的线粒体相比表现出表型差异。

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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来源期刊

BMC Biochemistry BIOCHEMISTRY & MOLECULAR BIOLOGY-

CiteScore

4.80

自引率

0.00%

发文量

审稿时长

3 months

期刊介绍： BMC Biochemistry is an open access journal publishing original peer-reviewed research articles in all aspects of biochemical processes, including the structure, function and dynamics of metabolic pathways, supramolecular complexes, enzymes, proteins, nucleic acids and small molecular components of organelles, cells and tissues. BMC Biochemistry (ISSN 1471-2091) is indexed/tracked/covered by PubMed, MEDLINE, BIOSIS, CAS, EMBASE, Scopus, Zoological Record, Thomson Reuters (ISI) and Google Scholar.