van Mieghem F, Brettel K, Hillmann B, Kamlowski A, Rutherford A W, Schlodder E
Section de Bioénergétique, CNRS, URA 1290, Gif-sur-Yvette, France.
Biochemistry. 1995 Apr 11;34(14):4798-813. doi: 10.1021/bi00014a038.
Recombination reactions of the primary radical pair in photosystem II (PS II) have been studied in the nanosecond to millisecond time scales by flash absorption spectroscopy. Samples in which the first quinone acceptor (QA) was in the semiquinone form (QA-) or in the doubly reduced state (presumably QAH2) were used. The redox state of QA and the long-lived triplet state of the primary electron donor chlorophyll (3P680) were monitored by EPR. The following results were obtained at cryogenic temperatures (around 20 K). (1) the primary radical pair, P680+Pheo-, is formed with a high yield irrespective of the redox state of QA. (2) The decay of the primary pair is faster with QA- than with QAH2 and could be described biexponentially with t1/2 approximately 20 ns (approximately 65%)/150 ns (approximately 35%) and t1/2 approximately 60 ns (approximately 35%)/250 ns (approximately 65%), respectively. The different kinetics may be due to electrostatic and/or magnetic effects of QA- on charge recombination or due to conformational changes caused by the double reduction treatment. (3) The yield of the triplet state 3P680 was high both with QA- and QAH2. (4) The triplet decay was much faster with QA- [t1/2 approximately 2 microseconds (approximately 50%)/20 microseconds (approximately 50%)] than with QAH2 [t1/2 approximately 1 ms (approximately 65%)/3 ms (approximately 35%)]. The short lifetime of the triplet with QA- explains why it was not detected earlier. The mechanism of triplet quenching in the presence of QA- is not understood; however it may represent a protective process in PS II. (5) Almost identical data were obtained for PS II-enriched membranes from spinach and PS II core preparations from Synechococcus. Room temperature optical studies were performed on the Synechococcus preparation. In samples containing sodium dithionite to form QA- in the dark, EPR controls showed that multiple excitation flashes given at room temperature led to a decrease of the QA-Fe2+ signal, indicating double reduction of QA. During the first few flashes, QA- was still present in the large majority of the centers. In this case, the yield of the primary pair at room temperature was around 50%, and its decay could be described monoexponentially with t1/2 approximately 8 ns (a slightly better fit was obtained with two exponentials: t1/2 approximately 4 ns (approximately 80%)/25 ns (approximately 20%).(ABSTRACT TRUNCATED AT 400 WORDS)
通过闪光吸收光谱法,在纳秒至毫秒时间尺度上研究了光系统II(PS II)中初级自由基对的重组反应。使用了其中第一个醌受体(QA)处于半醌形式(QA-)或双还原状态(可能是QAH2)的样品。通过电子顺磁共振(EPR)监测QA的氧化还原状态和初级电子供体叶绿素的长寿命三重态(3P680)。在低温(约20K)下获得了以下结果。(1)无论QA的氧化还原状态如何,初级自由基对P680+Pheo-都能高产率形成。(2)与QAH2相比,QA-存在时初级自由基对的衰减更快,并且可以用双指数形式描述,t1/2分别约为20纳秒(约65%)/150纳秒(约35%)和t1/2约为60纳秒(约35%)/250纳秒(约65%)。不同的动力学可能是由于QA-对电荷重组的静电和/或磁效应,或者是由于双还原处理引起的构象变化。(3)QA-和QAH2存在时三重态3P680的产率都很高。(4)QA-存在时三重态的衰减[t1/2约为2微秒(约50%)/20微秒(约50%)]比QAH2存在时[t1/2约为1毫秒(约65%)/3毫秒(约35%)]快得多。QA-存在时三重态的短寿命解释了为什么它没有更早被检测到。QA-存在时三重态猝灭的机制尚不清楚;然而,它可能代表了PS II中的一种保护过程。(5)从菠菜中提取的富含PS II的膜和来自集胞藻的PS II核心制剂获得了几乎相同的数据。对集胞藻制剂进行了室温光学研究。在含有连二亚硫酸钠以在黑暗中形成QA-的样品中,EPR对照表明,在室温下多次激发闪光导致QA-Fe2+信号降低,表明QA发生了双还原。在最初的几次闪光期间,QA-仍存在于大多数中心。在这种情况下,室温下初级自由基对的产率约为50%,其衰减可以用单指数形式描述,t1/2约为8纳秒(用两个指数拟合效果稍好:t1/2约为4纳秒(约80%)/25纳秒(约20%))。(摘要截断于400字)
