27 Mitochondrial Translation and Human Disease

E. Shoubridge, F. Sasarman
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Abstract

Most eukaryotic cells rely on oxidative phosphorylation for cellular ATP production. The machinery for oxidative phosphorylation consists of five large hetero-oligomeric enzyme complexes, located in the inner mitochondrial membrane. The majority of the approximately 85 structural components of this system are encoded in the nuclear genome, but a small number of essential protein subunits—13 in mammals—have been retained on the mitochondrial genome (mtDNA), and these are synthesized on a dedicated protein translation apparatus in the mitochondrial matrix. All of the proteins necessary for the replication, transcription, and translation of the genes encoded in mtDNA are encoded in the nuclear genome. This genetic investment is far out of proportion to the number of proteins involved, and it is likely that a small, semiautonomous mitochondrial genome has persisted because the proteins it encodes are hydrophobic proteins that need to be cotranslationally inserted into the inner mitochondrial membrane during assembly of the oxidative phosphorylation complexes. As might be expected from the α- proteobacterial origins of mitochondria, many of the features of mitochondrial translation are similar to those found in prokaryotes. In this chapter, we review the organization and control of mitochondrial translation, with a particular emphasis on the system in mammals and on mechanisms of disease. ORGANIZATION OF THE MAMMALIAN MITOCHONDRIAL TRANSLATION SYSTEM Mammalian mtDNA is a small (~16.5 kb) double-stranded circular genome that codes for 13 proteins, 22 tRNAs, and 2 rRNAs. It contains no introns, and the genetic code is different from the universal code: Nuclear arginine (AGA, AGG)...
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线粒体翻译与人类疾病
大多数真核细胞依靠氧化磷酸化来产生细胞ATP。氧化磷酸化机制由位于线粒体膜内的五个大型异聚寡聚酶复合物组成。该系统的大约85个结构成分中的大多数是在核基因组中编码的,但是一小部分必需的蛋白质亚基(哺乳动物中有13个)保留在线粒体基因组(mtDNA)上,这些是在线粒体基质中的专用蛋白质翻译装置上合成的。mtDNA编码的基因的复制、转录和翻译所必需的所有蛋白质都编码在核基因组中。这种遗传投资远远超出了所涉及的蛋白质数量的比例,并且很可能是一个小的,半自主的线粒体基因组持续存在,因为它编码的蛋白质是疏水蛋白质,在氧化磷酸化复合物的组装过程中需要共翻译插入线粒体内膜。从线粒体的α-变形菌起源可以预料到,线粒体翻译的许多特征与原核生物中发现的特征相似。在本章中,我们回顾了线粒体翻译的组织和控制,特别强调了哺乳动物的系统和疾病的机制。哺乳动物线粒体翻译系统的组织哺乳动物线粒体dna是一个小的(约16.5 kb)双链环状基因组,编码13种蛋白质,22种trna和2种rrna。它不含内含子,遗传密码与通用密码不同:核精氨酸(AGA, AGG)…
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