细菌光合作用中的初级电荷分离:氧化叶绿素和还原脱镁叶绿素
Primary charge separation in bacterial photosynthesis: oxidized chlorophylls and reduced pheophytin.
作者信息
Fajer J, Brune D C, Davis M S, Forman A, Spaulding L D
出版信息
Proc Natl Acad Sci U S A. 1975 Dec;72(12):4956-60. doi: 10.1073/pnas.72.12.4956.
Abstract
Bacteriopheophytin, the magnesium-free base of bacteriochlorophyll, undergoes reversible one-electron reduction in organic solvents to yield an anionic free radical with characteristic optical and electron spin resonance spectra. The reduction potential of bacteriopheophytin, E1/2 approximately --0.55 V against a normal hydrogen electrode, compared to E1/2 approximately --0.85 V for bacteriochlorophyll, renders it a likely electron acceptor in the primary charge separation of photosynthesis. Comparison of these data with picosecond optical changes recently observed upon pulsed laser excitation of bacterial reaction centers leads us to propose that bacteriopheophytin is indeed a transient electron acceptor and that the primary charge separation of bacterial photosynthesis occurs between the bacteriochlorophyll complex P870 and bacteriopheophytin to yield the radicals of the oxidized chlorophyll dimer cation and reduced pheophytin anion.
摘要
细菌脱镁叶绿素是细菌叶绿素的无镁碱,在有机溶剂中会发生可逆的单电子还原反应,生成具有特征性光学和电子自旋共振光谱的阴离子自由基。与细菌叶绿素的E1/2约为-0.85 V(相对于标准氢电极)相比,细菌脱镁叶绿素的还原电位E1/2约为-0.55 V,这使其成为光合作用初级电荷分离中可能的电子受体。将这些数据与最近在脉冲激光激发细菌反应中心时观察到的皮秒级光学变化进行比较,我们提出细菌脱镁叶绿素确实是一个瞬态电子受体,并且细菌光合作用的初级电荷分离发生在细菌叶绿素复合物P870和细菌脱镁叶绿素之间,生成氧化叶绿素二聚体阳离子和还原脱镁叶绿素阴离子的自由基。
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