线粒体复合物 I：衰老过程的中央调控者。

Mitochondrial complex I: a central regulator of the aging process.

机构信息

Beatson Institute for Cancer Research; Cancer Research UK, Glasgow, UK.

出版信息

Cell Cycle. 2011 May 15;10(10):1528-32. doi: 10.4161/cc.10.10.15496.

DOI:10.4161/cc.10.10.15496

Abstract

Mitochondria are considered major regulators of longevity, although their exact role in aging is not fully understood. Data from different laboratories show a negative correlation between reactive oxygen species (ROS) generated by complex I and lifespan. This suggests that complex I has a central role in the regulation of longevity. Here, we review data that both support and refute the role of complex I as a pacemaker of aging. We include data from our laboratory, where we have manipulated ROS production by the electron transport chain (ETC) in Drosophila melanogaster. The bypass of complex I increases the lifespan of the fruit fly, but it is not clear if this is caused by a reduction in ROS or by a change in the NAD+ to NADH ratio. We propose that complex I regulates aging through at least two mechanisms: (1) an ROS-dependent mechanism that leads to mitochondrial DNA damage and (2) an ROS-independent mechanism through the control of the NAD+ to NADH ratio. Control of the relative levels of NAD+ and NADH would allow the regulation of (1) glyco- and (2) lipoxidative-damage and (3) the activation of sirtuins.

摘要

线粒体被认为是长寿的主要调节因子，尽管它们在衰老过程中的确切作用尚不完全清楚。来自不同实验室的数据表明，I 型复合物产生的活性氧（ROS）与寿命呈负相关。这表明 I 型复合物在调节寿命方面起着核心作用。在这里，我们回顾了支持和反驳 I 型复合物作为衰老起搏器的作用的数据。我们包括了我们实验室的数据，我们在果蝇中操纵了电子传递链（ETC）产生的 ROS 。绕过 I 型复合物会增加果蝇的寿命，但尚不清楚这是由于 ROS 的减少还是由于 NAD+到 NADH 比例的变化所致。我们提出，I 型复合物通过至少两种机制来调节衰老：（1）ROS 依赖性机制，导致线粒体 DNA 损伤；（2）通过控制 NAD+到 NADH 比例的 ROS 非依赖性机制。NAD+和 NADH 的相对水平的控制将允许调节（1）糖基和（2）脂基氧化损伤和（3）sirtuins 的激活。

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线粒体复合物 I：衰老过程的中央调控者。

Mitochondrial complex I: a central regulator of the aging process.

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