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球形红假单胞菌反应中心的电子转移。I. D + QAQ(-)B 的电荷复合途径以及 Q(-)AQB 与 QAQ(-)B 之间的自由能和动力学关系的测定

Electron transfer in reaction centers of Rhodopseudomonas sphaeroides. I. Determination of the charge recombination pathway of D+QAQ(-)B and free energy and kinetic relations between Q(-)AQB and QAQ(-)B.

作者信息

Kleinfeld D, Okamura M Y, Feher G

出版信息

Biochim Biophys Acta. 1984 Jul 27;766(1):126-40. doi: 10.1016/0005-2728(84)90224-x.

DOI:10.1016/0005-2728(84)90224-x
PMID:6331502
Abstract

The electron-transfer reactions and thermodynamic equilibria involving the quinone acceptor complex in bacterial reaction centers from R. sphaeroides were investigated. The reactions are described by the scheme: (Formula: see text). We found that the charge recombination pathway of D+QAQ(-)B proceeds via the intermediate state D+Q(-)AQB, the direct pathway contributing less than approx. 5% to the observed recombination rate. The method used to obtain this result was based on a comparison of the kinetics predicted for the indirect pathway (given by the product kAD-times the fraction of reaction centers in the Q-AQB state) with the observed recombination rate, kobsD+----D. The kinetic measurements were used to obtain the pH dependence (6.1 smaller than or equal to pH smaller than or equal to 11.7) of the free energy difference between the states Q(-)AQB and QAQ(-)B. At low pH (less than 9) QAQ(-)B is stabilized relative to Q(-)AQB by 67 meV, whereas at high pH Q(-)AQB is energetically favored. Both Q(-)A and Q(-)B associate with a proton, with pK values of 9.8 and 11.3, respectively. The stronger interaction of the proton with Q(-)B provides the driving force for the forward electron transfer.

摘要

对球形红细菌(R. sphaeroides)细菌反应中心中涉及醌受体复合物的电子转移反应和热力学平衡进行了研究。这些反应由以下反应式描述:(公式:见原文)。我们发现,D + QAQ(-)B的电荷复合途径通过中间态D + Q(-)AQB进行,直接途径对观察到的复合速率的贡献小于约5%。用于获得该结果的方法是基于对间接途径预测的动力学(由kAD乘以处于Q-AQB状态的反应中心分数给出)与观察到的复合速率kobsD+----D进行比较。动力学测量用于获得Q(-)AQB和QAQ(-)B状态之间自由能差的pH依赖性(6.1≤pH≤11.7)。在低pH(小于9)时,QAQ(-)B相对于Q(-)AQB稳定67 meV,而在高pH时,Q(-)AQB在能量上更有利。Q(-)A和Q(-)B都与一个质子结合,pK值分别为9.8和11.3。质子与Q(-)B的更强相互作用为正向电子转移提供了驱动力。

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