来自绿弯菌属橙色绿弯菌的B808-866天线中的能量转移。
Energy transfers in the B808-866 antenna from the green bacterium Chloroflexus aurantiacus.
作者信息
Novoderezhkin V I, Taisova A S, Fetisova Z G, Blankenship R E, Savikhin S, Buck D R, Struve W S
机构信息
A. N. Belozersky Institute of Physico-Chemical Biology, Moscow State University, Russia.
出版信息
Biophys J. 1998 Apr;74(4):2069-75. doi: 10.1016/S0006-3495(98)77913-5.
Abstract
Energy transfers within the B808-866 BChl a antenna in chlorosome-membrane complexes from the green photosynthetic bacterium Chloroflexus aurantiacus were studied in two-color pump-probe experiments at room temperature. The steady-state spectroscopy and protein sequence of the B808-866 complex are reminiscent of well-studied LH2 antennas from purple bacteria. B808-->B866 energy transfers occur with approximately 2 ps kinetics; this is slower by a factor of approximately 2 than B800-->B850 energy transfers in LH2 complexes from Rhodopseudomonas acidophila or Rhodobacter sphaeroides. Anisotropy studies show no evidence for intra-B808 energy transfers before the B808-->B866 step; intra-B866 processes are reflected in 350-550 fs anisotropy decays. Two-color anisotropies under 808 nm excitation suggest the presence of a B808-->B866 channel arising either from direct laser excitation of upper B866 exciton components that overlap the B808 absorption band or from excitation of B866 vibronic bands in nontotally symmetric modes.
摘要
在室温下的双色泵浦-探测实验中,研究了来自绿色光合细菌嗜热栖热菌的叶绿体-膜复合物中B808-866细菌叶绿素a天线内的能量转移。B808-866复合物的稳态光谱和蛋白质序列让人联想到来自紫色细菌的经过充分研究的LH2天线。B808→B866的能量转移以大约2皮秒的动力学发生;这比嗜酸红假单胞菌或球形红杆菌的LH2复合物中B800→B850的能量转移慢约2倍。各向异性研究表明,在B808→B866步骤之前没有B808内能量转移的证据;B866内的过程反映在350-550飞秒的各向异性衰减中。808纳米激发下的双色各向异性表明存在一个B808→B866通道,该通道要么源于与B808吸收带重叠的上B866激子成分的直接激光激发,要么源于非完全对称模式下B866振动带的激发。
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