Lemeshko Victor V
Department of Physics, National University of Colombia, Medellin Branch, AA3840 Medellin, Colombia.
Biophys J. 2002 Feb;82(2):684-92. doi: 10.1016/S0006-3495(02)75431-3.
Voltage-dependent anion channels in the outer mitochondrial membrane are strongly regulated by electrical potential. In this work, one of the possible mechanisms of the outer membrane potential generation is proposed. We suggest that the inner membrane potential may be divided on two resistances in series, the resistance of the contact sites between the inner and outer membranes and the resistance of the voltage-dependent anion channels localized beyond the contacts in the outer membrane. The main principle of the proposed mechanism is illustrated by simplified electric and kinetic models. Computational behavior of the kinetic model shows a restriction of the steady-state metabolite flux through the mitochondrial membranes at relatively high concentration of the external ADP. The flux restriction was caused by a decrease of the voltage across the contact sites and by an increase in the outer membrane potential (up to +60 mV) leading to the closure of the voltage-dependent anion channels localized beyond the contact sites. This mechanism suggests that the outer membrane potential may arrest ATP release through the outer membrane beyond the contact sites, thus tightly coordinating mitochondrial metabolism and aerobic glycolysis in tumor and normal proliferating cells.
线粒体外膜中的电压依赖性阴离子通道受电势的强烈调控。在这项工作中,提出了外膜电势产生的一种可能机制。我们认为内膜电势可能被分为两个串联电阻,即内膜与外膜之间接触位点的电阻以及位于外膜接触位点之外的电压依赖性阴离子通道的电阻。所提出机制的主要原理通过简化的电学和动力学模型进行说明。动力学模型的计算行为表明,在外部ADP浓度相对较高时,稳态代谢物通过线粒体膜的通量受到限制。通量限制是由接触位点上的电压降低以及外膜电势升高(高达 +60 mV)导致位于接触位点之外的电压依赖性阴离子通道关闭所致。该机制表明,外膜电势可能会阻止ATP通过接触位点之外的外膜释放,从而紧密协调肿瘤细胞和正常增殖细胞中的线粒体代谢与有氧糖酵解。