光合膜中类胡萝卜素电致变色响应的理论研究。

Theoretical studies of the electrochromic response of carotenoids in photosynthetic membranes.

作者信息

Kakitani T, Honig B, Crofts A R

出版信息

Biophys J. 1982 Jul;39(1):57-63. doi: 10.1016/S0006-3495(82)84490-1.

DOI:10.1016/S0006-3495(82)84490-1

PMID:7104451

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1328910/

Abstract

Molecular orbital calculations are carried out on a number of carotenoids in the presence of an external charge and a constant electric field. The external charge is used to represent the strong permanent field that is believed to polarize carotenoids in photosynthetic membranes and thus to account for their linear response to the transmembrane potential. Our calculations show that the in vitro leads to in vivo spectral shifts of carotenoids (approximately 25 nm) can be produced by a charge in close proximity to the molecule. The interaction of the induced dipole moment with a constant field accounts for the observed magnitude of the electrochromic response in photosynthetic bacteria. The existence of a second pool of carotenoids that shows a significant (approximately 20 nm) wavelength shift but no electrochromic response can be explained by an external charge positioned near the center of the molecule that affects its absorption maximum while inducing essentially no dipole moment. The spectral shift for this pool is due to the induction of higher multipoles. These also account for discrepancies that arise when one attempts to account quantitatively for available experimental results on carotenoid band shifts in terms of classical electrochromic theory.

摘要

在存在外部电荷和恒定电场的情况下，对多种类胡萝卜素进行了分子轨道计算。外部电荷用于表示被认为会使光合膜中的类胡萝卜素极化的强永久场，从而解释它们对跨膜电位的线性响应。我们的计算表明，靠近分子的电荷可导致类胡萝卜素的体外光谱向体内光谱移动（约25纳米）。诱导偶极矩与恒定场的相互作用解释了光合细菌中观察到的电致变色响应的大小。存在第二类类胡萝卜素池，其显示出显著的（约20纳米）波长移动但无电致变色响应，这可以通过位于分子中心附近的外部电荷来解释，该电荷影响其最大吸收，同时基本不诱导偶极矩。该类胡萝卜素池的光谱移动是由于更高多极矩的诱导。这些也解释了在尝试根据经典电致变色理论对类胡萝卜素带移的现有实验结果进行定量解释时出现的差异。

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