Baranov Sergei V, Stavrovskaya Irina G, Brown Abraham M, Tyryshkin Alexei M, Kristal Bruce S
Department of Neurosurgery, Brigham and Women's Hospital, Boston, Massachusetts 02115, USA.
J Biol Chem. 2008 Jan 11;283(2):665-76. doi: 10.1074/jbc.M703484200. Epub 2007 Oct 25.
Cytotoxicity associated with pathophysiological Ca(2+) overload (e.g. in stroke) appears mediated by an event termed the mitochondrial permeability transition (mPT). We built and solved a kinetic model of the mPT in populations of isolated rat liver mitochondria that quantitatively describes Ca(2+)-induced mPT as a two-step sequence of pre-swelling induction followed by Ca(2+)-driven, positive feedback, autocatalytic propagation. The model was formulated as two differential equations, each directly related to experimental parameters (Ca(2+) flux/mitochondrial swelling). These parameters were simultaneously assessed using a spectroscopic approach to monitor multiple mitochondrial properties. The derived kinetic model correctly identifies a correlation between initial Ca(2+) concentration and delay interval prior to mPT induction. Within the model's framework, Ru-360 (a ruthenium complex) and Mg(2+) were shown to compete with the Ca(2+)-stimulated initiation phase of mPT induction, consistent with known inhibition at the phenomenological level of the Ca(2+) uniporter. The model further reveals that Mg(2+), but not Ru-360, inhibits Ca(2+)-induced effects on a downstream stage of mPT induction at a site distinct from the uniporter. The analytical approach was then applied to promethazine, an FDA-approved drug previously shown to inhibit both mPT and ischemia-reperfusion injury. Kinetic analysis revealed that promethazine delayed mPT induction in a manner qualitatively distinct from that of lower concentrations of Mg(2+). In summary, we have developed a kinetic model to aid in the quantitative characterization of mPT induction. This model is consistent with/informative about the biochemistry of several mPT inhibitors, and its success suggests that this kinetic approach can aid in the classification of agents or targets that modulate mPT induction.
与病理生理状态下的钙(Ca²⁺)超载相关的细胞毒性(如在中风中)似乎是由一种称为线粒体通透性转换(mPT)的事件介导的。我们构建并求解了分离的大鼠肝线粒体群体中mPT的动力学模型,该模型将Ca²⁺诱导的mPT定量描述为一个两步序列:先是预肿胀诱导,然后是Ca²⁺驱动的正反馈自催化传播。该模型被表述为两个微分方程,每个方程都直接与实验参数(Ca²⁺通量/线粒体肿胀)相关。这些参数通过一种光谱方法同时进行评估,以监测多种线粒体特性。推导得到的动力学模型正确地识别出初始Ca²⁺浓度与mPT诱导前延迟间隔之间的相关性。在该模型的框架内,钌-360(一种钌络合物)和镁离子(Mg²⁺)被证明与mPT诱导的Ca²⁺刺激起始阶段相互竞争,这与在Ca²⁺单向转运体现象学水平上已知的抑制作用一致。该模型进一步揭示,Mg²⁺而非Ru-360在与单向转运体不同的位点抑制Ca²⁺对mPT诱导下游阶段的影响。然后将这种分析方法应用于异丙嗪,一种先前已被证明可抑制mPT和缺血再灌注损伤的FDA批准药物。动力学分析表明,异丙嗪延迟mPT诱导的方式在性质上与较低浓度的Mg²⁺不同。总之,我们开发了一个动力学模型来帮助对mPT诱导进行定量表征。该模型与几种mPT抑制剂的生物化学过程一致/提供了相关信息,其成功表明这种动力学方法有助于对调节mPT诱导的药物或靶点进行分类。
