活性氧
线粒体
氧化应激
生物物理学
双稳态
机制(生物学)
呼吸链
细胞呼吸
电子传输链
呼吸
线粒体呼吸链
氧化还原
氧气
氧化磷酸化
化学
稳态(化学)
生物系统
细胞生物学
生物
生物化学
物理
解剖
量子力学
物理化学
有机化学
作者
Vitaly A. Selivanov,Tatyana V. Votyakova,Jennifer A. Zeak,Massimo Trucco,Josep Roca,Marta Cascante
标识
DOI:10.1371/journal.pcbi.1000619
摘要
Increased production of reactive oxygen species (ROS) in mitochondria underlies major systemic diseases, and this clinical problem stimulates a great scientific interest in the mechanism of ROS generation. However, the mechanism of hypoxia-induced change in ROS production is not fully understood. To mathematically analyze this mechanism in details, taking into consideration all the possible redox states formed in the process of electron transport, even for respiratory complex III, a system of hundreds of differential equations must be constructed. Aimed to facilitate such tasks, we developed a new methodology of modeling, which resides in the automated construction of large sets of differential equations. The detailed modeling of electron transport in mitochondria allowed for the identification of two steady state modes of operation (bistability) of respiratory complex III at the same microenvironmental conditions. Various perturbations could induce the transition of respiratory chain from one steady state to another. While normally complex III is in a low ROS producing mode, temporal anoxia could switch it to a high ROS producing state, which persists after the return to normal oxygen supply. This prediction, which we qualitatively validated experimentally, explains the mechanism of anoxia-induced cell damage. Recognition of bistability of complex III operation may enable novel therapeutic strategies for oxidative stress and our method of modeling could be widely used in systems biology studies.
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