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线粒体复合物 III Rieske Fe-S 蛋白的加工与组装。

Mitochondrial complex III Rieske Fe-S protein processing and assembly.

机构信息

a MRC-Mitochondrial Biology Unit , University of Cambridge , Hills Road, CB2 0XY , Cambridge , UK.

出版信息

Cell Cycle. 2018;17(6):681-687. doi: 10.1080/15384101.2017.1417707. Epub 2018 Apr 10.

DOI:10.1080/15384101.2017.1417707
PMID:29243944
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5969560/
Abstract

Regulation of the mitochondrial respiratory chain biogenesis is a matter of great interest because of its implications for mitochondrial disease. One of the mitochondrial disease genes recently discovered associated to encephalopathy and mitochondrial complex III (cIII) deficiency is TTC19. Our study of TTC19-deficient human and mouse models, has led us to propose a post-assembly quality control role or 'husbandry' function for this factor that is linked to Rieske Fe-S protein (UQCRFS1). UQCRFS1 is the last incorporated cIII subunit, and its presence is essential for enzymatic activity. During UQCRFS1 assembly, the precursor is cleaved and its N-terminal part remains bound to the complex, between the two core subunits (UQCRC1 and UQCRC2). In the absence of TTC19 there is a prominent accumulation of these UQCRFS1-derived N-terminal fragments that proved to be detrimental for cIII function. In this article we will discuss some ideas around the UQCRFS1 processing and assembly and its importance for the regulation of cIII activity and biogenesis.

摘要

线粒体呼吸链生物发生的调节是一个非常有趣的问题,因为它与线粒体疾病有关。最近发现的与脑病和线粒体复合物 III (cIII) 缺陷相关的线粒体疾病基因之一是 TTC19。我们对 TTC19 缺陷的人类和小鼠模型的研究,使我们提出了这个因素的后组装质量控制作用或“管理”功能,该功能与 Rieske Fe-S 蛋白 (UQCRFS1) 有关。UQCRFS1 是最后掺入的 cIII 亚基,其存在对于酶活性是必需的。在 UQCRFS1 组装过程中,前体被切割,其 N 端部分仍然结合在复合物中,位于两个核心亚基 (UQCRC1 和 UQCRC2) 之间。在没有 TTC19 的情况下,这些 UQCRFS1 衍生的 N 端片段会大量积累,这被证明对 cIII 功能有害。在本文中,我们将讨论围绕 UQCRFS1 加工和组装的一些想法及其对 cIII 活性和生物发生调节的重要性。

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