Electron transfer in deuterated reaction centers of Rhodobacter sphaeroides at 90 K according to femtosecond spectroscopy dataстатья
Информация о цитировании статьи получена из
Web of Science,
Scopus
Статья опубликована в журнале из списка Web of Science и/или Scopus
Дата последнего поиска статьи во внешних источниках: 7 октября 2013 г.
Местоположение издательства:Road Town, United Kingdom
Первая страница:603
Последняя страница:610
Аннотация:The primary act of charge separation was studied in P(+)B(A)(-) and P(+)H(A)(-) states (P, primary electron donor; B(A) and H(A), primary and secondary electron acceptor) of native reaction centers (RCs) of Rhodobacter sphaeroides R-26 using femtosecond absorption spectroscopy at low (90 K) and room temperature. Coherent oscillations were studied in the kinetics of the stimulated emission band of P* (935 nm), of absorption band of B(A)(-) (1020 nm) and of absorption band of H(A) (760 nm). It was found that in native RCs kept in heavy water (D(2)O) buffer the isotopic decreasing of basic oscillation frequency 32 cm(-1) and its overtones takes place by the same factor approximately 1.3 in the 935, 1020, and 760 nm bands in comparison with the samples in ordinary water H2O. This suggests that the femtosecond oscillations in RC kinetics with 32 cm(-1) frequency may be caused by rotation of hydrogen-containing groups, in particular the water molecule which may be placed between primary electron donor P(B) and primary electron acceptor B(A). This rotation may appear also as high harmonics up to sixth in the stimulated emission of P*. The rotation of the water molecule may modulate electron transfer from P* to B(A). The results allow for tracing of the possible pathway of electron transfer from P* to B(A) along a chain consisting of polar atoms according to the Brookhaven Protein Data Bank (1PRC): Mg(P(B))-N-C-N(His M200)-HOH-O = B(A). We assume that the role of 32-cm(-1) modulation in electron transfer along this chain consist of a fixation of electron density at B(A)(-) during a reversible electron transfer, when populations of P* and P(+)B(A)(-) states are approximately equal.