Forkink Marleen, Smeitink Jan A M, Brock Roland, Willems Peter H G M, Koopman Werner J H
Department of Biochemistry, Nijmegen Centre for Molecular Life Sciences, Radboud University Nijmegen Medical Centre, Nijmegen, The Netherlands.
Biochim Biophys Acta. 2010 Jun-Jul;1797(6-7):1034-44. doi: 10.1016/j.bbabio.2010.01.022. Epub 2010 Jan 25.
Reactive oxygen species (ROS) are formed upon incomplete reduction of molecular oxygen (O2) as an inevitable consequence of mitochondrial metabolism. Because ROS can damage biomolecules, cells contain elaborate antioxidant defense systems to prevent oxidative stress. In addition to their damaging effect, ROS can also operate as intracellular signaling molecules. Given the fact that mitochondrial ROS appear to be only generated at specific sites and that particular ROS species display a unique chemistry and have specific molecular targets, mitochondria-derived ROS might constitute local regulatory signals. The latter would allow individual mitochondria to auto-regulate their metabolism, shape and motility, enabling them to respond autonomously to the metabolic requirements of the cell. In this review we first summarize how mitochondrial ROS can be generated and removed in the living cell. Then we discuss experimental strategies for (local) detection of ROS by combining chemical or proteinaceous reporter molecules with quantitative live cell microscopy. Finally, approaches involving targeted pro- and antioxidants are presented, which allow the local manipulation of ROS levels.
活性氧(ROS)是线粒体代谢不可避免的结果,由分子氧(O₂)不完全还原形成。由于ROS会损害生物分子,细胞含有复杂的抗氧化防御系统以防止氧化应激。除了具有破坏作用外,ROS还可作为细胞内信号分子发挥作用。鉴于线粒体ROS似乎仅在特定部位产生,且特定的ROS种类具有独特的化学性质和特定的分子靶点,线粒体衍生的ROS可能构成局部调节信号。后者将使单个线粒体能够自动调节其代谢、形态和运动,使其能够自主响应细胞的代谢需求。在本综述中,我们首先总结活细胞中线粒体ROS如何产生和清除。然后我们讨论通过将化学或蛋白质报告分子与定量活细胞显微镜相结合来(局部)检测ROS的实验策略。最后,介绍了涉及靶向促氧化剂和抗氧化剂的方法,这些方法可对ROS水平进行局部调控。
