光合放氧生物光系统II中光诱导水分解的机制。

Mechanism of light induced water splitting in Photosystem II of oxygen evolving photosynthetic organisms.

作者信息

Renger Gernot

机构信息

Technical University Berlin, Berlin, Germany.

出版信息

Biochim Biophys Acta. 2012 Aug;1817(8):1164-76. doi: 10.1016/j.bbabio.2012.02.005. Epub 2012 Feb 12.

DOI:10.1016/j.bbabio.2012.02.005

PMID:22353626

Abstract

The reactions of light induced oxidative water splitting were analyzed within the framework of the empirical rate constant-distance relationship of non-adiabatic electron transfer in biological systems (C. C. Page, C. C. Moser, X. Chen , P. L. Dutton, Nature 402 (1999) 47-52) on the basis of structure information on Photosystem II (PS II) (A. Guskov, A. Gabdulkhakov, M. Broser, C. Glöckner, J. Hellmich, J. Kern, J. Frank, W. Saenger, A. Zouni, Chem. Phys. Chem. 11 (2010) 1160-1171, Y. Umena, K. Kawakami, J-R Shen, N. Kamiya, Crystal structure of oxygen-evolving photosystem II at a resolution of 1.9Å. Nature 47 (2011) 55-60). Comparison of these results with experimental data leads to the following conclusions: 1) The oxidation of tyrosine Y(z) by the cation radical P680(+·) in systems with an intact water oxidizing complex (WOC) is kinetically limited by the non-adiabatic electron transfer step and the extent of this reaction is thermodynamically determined by relaxation processes in the environment including rearrangements of hydrogen bond network(s). In marked contrast, all Y(z)(ox) induced oxidation steps in the WOC up to redox state S(3) are kinetically limited by trigger reactions which are slower by orders of magnitude than the rates calculated for non-adiabatic electron transfer. 3) The overall rate of the triggered reaction sequence of Y(z)(ox) reduction by the WOC in redox state S(3) eventually leading to formation and release of O(2) is kinetically limited by an uphill electron transfer step. Alternative models are discussed for this reaction. The protein matrix of the WOC and bound water molecules provide an optimized dynamic landscape of hydrogen bonded protons for catalyzing oxidative water splitting energetically driven by light induced formation of the cation radical P680(+·). In this way the PS II core acts as a molecular machine formed during a long evolutionary process. This article is part of a Special Issue entitled: Photosynthesis Research for Sustainability: from Natural to Artificial.

摘要

在生物系统中非绝热电子转移的经验速率常数 - 距离关系框架内（C.C. Page、C.C. Moser、X. Chen、P.L. Dutton，《自然》402 (1999) 47 - 52），基于光系统II（PS II）的结构信息（A. Guskov、A. Gabdulkhakov、M. Broser、C. Glöckner、J. Hellmich、J. Kern、J. Frank、W. Saenger、A. Zouni，《化学物理化学》11 (2010) 1160 - 1171，Y. Umena、K. Kawakami、J - R Shen、N. Kamiya，分辨率为1.9Å的析氧光系统II的晶体结构。《自然》47 (2011) 55 - 60），对光诱导氧化水分解反应进行了分析。将这些结果与实验数据进行比较得出以下结论：1）在具有完整水氧化复合物（WOC）的系统中，阳离子自由基P⁶⁸⁰⁺·对酪氨酸Y(z)的氧化在动力学上受非绝热电子转移步骤限制，并且该反应的程度在热力学上由包括氢键网络重排在内的环境弛豫过程决定。与之形成显著对比的是，WOC中直至氧化还原态S(3)的所有Y(z)(ox)诱导的氧化步骤在动力学上受触发反应限制，这些触发反应比非绝热电子转移计算的速率慢几个数量级。3）氧化还原态S(3)的WOC对Y(z)(ox)还原的触发反应序列最终导致O₂形成和释放的总速率在动力学上受一个上坡电子转移步骤限制。讨论了该反应的替代模型。WOC的蛋白质基质和结合的水分子为催化由光诱导形成阳离子自由基P⁶⁸⁰⁺·能量驱动的氧化水分解提供了优化的氢键质子动态景观。通过这种方式，PS II核心充当了在漫长进化过程中形成的分子机器。本文是名为：可持续性光合作用研究：从自然到人工的特刊的一部分。

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光合放氧生物光系统II中光诱导水分解的机制。

Mechanism of light induced water splitting in Photosystem II of oxygen evolving photosynthetic organisms.

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