真菌中的线粒体-细胞核相互作用与寿命控制

Mitochondrial-nuclear interactions and lifespan control in fungi.

作者信息

Osiewacz H D, Kimpel E

机构信息

Botanisches Institut, Molekulare Entwicklungsbiologie und Biotechnologie, Johann Wolfgang Goethe-Universität, Frankfurt am Main, Germany.

出版信息

Exp Gerontol. 1999 Dec;34(8):901-9. doi: 10.1016/s0531-5565(99)00063-7.

DOI:10.1016/s0531-5565(99)00063-7

PMID:10673144

Abstract

In fungi, mitochondrial-nuclear interactions are part of a complex molecular network involved in the control of aging processes. The generation of reactive oxygen species at the mitochondrial respiratory chain plays a major role in this network. Mitochondrial DNA instabilities, which are under the control of nuclear genes, affect the generation of reactive oxygen species and modulate the rate of aging. As mitochondria become dysfunctional, they transduce signals to the nucleus and induce the expression of a set of nuclear genes, a process termed retrograde regulation. Molecular data are emerging which suggest that retrograde regulation is involved in lifespan control.

摘要

在真菌中，线粒体与细胞核的相互作用是参与衰老过程控制的复杂分子网络的一部分。线粒体呼吸链上活性氧的产生在这个网络中起主要作用。受核基因控制的线粒体DNA不稳定性会影响活性氧的产生并调节衰老速率。当线粒体功能失调时，它们会向细胞核传递信号并诱导一组核基因的表达，这一过程称为逆行调控。越来越多的分子数据表明逆行调控与寿命控制有关。

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真菌中的线粒体-细胞核相互作用与寿命控制

Mitochondrial-nuclear interactions and lifespan control in fungi.

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