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细菌光合作用中初级电子转移过程的皮秒动力学

Picosecond dynamics of primary electron-transfer processes in bacterial photosynthesis.

作者信息

Peters K, Avouris P, Rentzepis P M

出版信息

Biophys J. 1978 Aug;23(2):207-17. doi: 10.1016/S0006-3495(78)85443-5.

DOI:10.1016/S0006-3495(78)85443-5
PMID:308379
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1473520/
Abstract

The primary electron transfer processes in Rhodopseudomonas sphaeroides R-26 were studied as a function of temperature by means of picosecond spectroscopy. The first chemical step of the bacterial photosynthesis involves an electron transfer from the excited state of a bacteriochlorophyll a dimer, (BChl)2, to a bacteriopheophytin (BPh) to form the radical ion pair (BChl)2+. BPh-.. The upper limit for the formation time of this ion-pair was found to be 10 ps, at temperatures in the range 300-4.2 degree K. Similarly, the second chemical step, involving electron transfer from BPh-. to an ubiquinone-iron complex (QFe), was found to have a lifetime of approximately 150 ps, also independent of temperature in the same range. We interpret the absence of temperature dependence as indicating that process 2 proceeds via a tunneling mechanism. Utilizing our results in conjunction with electron tunneling theories, we calculate the distance between BPh-. and Q(Fe) to be 9--13 A. Our results also imply a closer proximity between (BChl)2 and BPh.

摘要

利用皮秒光谱技术,研究了球形红假单胞菌R-26中初级电子转移过程与温度的关系。细菌光合作用的第一步化学过程涉及电子从细菌叶绿素a二聚体(BChl)2的激发态转移至细菌脱镁叶绿素(BPh),形成自由基离子对(BChl)2 +·BPh -。在300 - 4.2 K的温度范围内,该离子对形成时间的上限为10皮秒。同样,第二步化学过程,即电子从BPh -转移至泛醌 - 铁复合物(QFe),其寿命约为150皮秒,在相同温度范围内也与温度无关。我们将温度依赖性的缺失解释为过程2通过隧穿机制进行。结合电子隧穿理论和我们的研究结果,我们计算出BPh -与Q(Fe)之间的距离为9 - 13埃。我们的结果还表明(BChl)2与BPh之间的距离更近。

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本文引用的文献

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