施加电场对重构于平面脂质双分子层中的反应中心电荷复合动力学的影响。

The effect of an applied electric field on the charge recombination kinetics in reaction centers reconstituted in planar lipid bilayers.

作者信息

Gopher A, Blatt Y, Schönfeld M, Okamura M Y, Feher G, Montal M

出版信息

Biophys J. 1985 Aug;48(2):311-20. doi: 10.1016/S0006-3495(85)83784-X.

DOI:10.1016/S0006-3495(85)83784-X

PMID:3902109

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1329322/

Abstract

Reaction Centers (RCs) from the photosynthetic bacterium Rhodopseudomonas sphaeroides were incorporated in planar bilayers made from monolayers derived from liposomes reconstituted with purified RCs. The photocurrents associated with the charge recombination process between the reduced primary quinone (QA-) and the oxidized bacteriochlorophyll donor (D+) were measured as a function of voltage (-150 mV less than V less than 150 mV) applied across the bilayer. When QA was the native ubiquinone (UQ) the charge recombination was voltage independent. However, when UQ was replaced by anthraquinone (AQ), the recombination time depended on the applied voltage V according to the relation tau = 8.5 X 10(-3) eV/0.175S. These results were explained by a simple model in which the charge recombination from UQ- proceeds directly to D+ while that from AQ occurs via a thermally activated intermediate state, D+I-QA, where I is the intermediate acceptor. The voltage dependence arises from an electric field induced change in the energy gap, delta G0, between the states D+I-QA and D+IQA-. This model is supported by the measured temperature dependence of the charge recombination time, which for RCs with AQ gave a value of delta G0 = 340 +/- 20 meV. In contrast, delta G0 for RCs with UQ as the primary acceptor, is sufficiently large (approximately 550 meV) so that even in the presence of the field, the direct pathway dominates. The voltage dependence shows that the electron transfer from I- to QA is electrogenic. From a quantitative analysis of the voltage dependence on the recombination rate it was concluded that the component of the distance between I and QA along the normal to the membrane is about one-seventh of the thickness of the membrane. This implies that the electron transfer from I to Q contributes at least one-seventh to the potential generated by the charge separation between D+ and QA-.

摘要

来自球形红假单胞菌光合细菌的反应中心（RCs）被整合到由单层脂质体衍生而来的平面双层膜中，这些脂质体是用纯化的RCs重构的。测量了与还原态初级醌（QA-）和氧化态细菌叶绿素供体（D+）之间电荷复合过程相关的光电流，该光电流是施加在双层膜上的电压（-150 mV < V < 150 mV）的函数。当QA是天然泛醌（UQ）时，电荷复合与电压无关。然而，当UQ被蒽醌（AQ）取代时，复合时间根据关系tau = 8.5×10(-3) eV/0.175S取决于施加的电压V。这些结果由一个简单模型解释，其中从UQ-的电荷复合直接进行到D+，而从AQ的电荷复合通过热激活中间态D+I-QA发生，其中I是中间受体。电压依赖性源于电场引起的D+I-QA和D+IQA-态之间能隙ΔG0的变化。该模型得到电荷复合时间的测量温度依赖性的支持，对于含有AQ的RCs，ΔG值为340±20 meV。相比之下，以UQ作为初级受体的RCs的ΔG0足够大（约550 meV），以至于即使在场存在的情况下，直接途径也占主导。电压依赖性表明从I-到QA的电子转移是生电的。通过对电压对复合速率的依赖性进行定量分析得出，I和QA之间沿膜法线方向的距离分量约为膜厚度的七分之一。这意味着从I到Q的电子转移对D+和QA-之间电荷分离产生的电位至少贡献七分之一。

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