光系统I中PsaC蛋白与PsaA/PsaB异二聚体结合的静电影响。
Electrostatic influence of PsaC protein binding to the PsaA/PsaB heterodimer in photosystem I.
作者信息
Ishikita Hiroshi, Stehlik Dietmar, Golbeck John H, Knapp Ernst-Walter
机构信息
Institute of Chemistry and Biochemistry, Department of Biology, Free University of Berlin, D-14195 Berlin, Germany.
出版信息
Biophys J. 2006 Feb 1;90(3):1081-9. doi: 10.1529/biophysj.105.069781. Epub 2005 Oct 28.
Abstract
The absence of the PsaC subunit in the photosystem I (PSI) complex (native PSI complex) by mutagenesis or chemical manipulation yields a PSI core (P700-F(X) core) that also lacks subunits PsaD and PsaE and the two iron-sulfur clusters F(A) and F(B), which constitute an integral part of PsaC. In this P700-F(X) core, the redox potentials (E(m)) of the two quinones A(1A/B) and the iron-sulfur cluster F(X) as well as the corresponding protonation patterns are investigated by evaluating the electrostatic energies from the solution of the linearized Poisson-Boltzmann equation. The B-side specific Asp-B558 changes its protonation state significantly upon isolating the P700-F(X) core, being mainly protonated in the native PSI complex but ionized in the P700-F(X) core. In the P700-F(X) core, E(m)(A(1A/B)) remains practically unchanged, whereas E(m)(F(X)) is upshifted by 42 mV. With these calculated E(m) values, the electron transfer rate from A(1) to F(X) in the P700-F(X) core is estimated to be slightly faster on the A(1A) side than that of the wild type, which is consistent with kinetic measurements.
摘要
通过诱变或化学操作使光系统I(PSI)复合物(天然PSI复合物)中缺失PsaC亚基,会产生一个PSI核心(P700-F(X)核心),该核心也缺少PsaD和PsaE亚基以及两个铁硫簇F(A)和F(B),而这两个铁硫簇是PsaC不可或缺的一部分。在这个P700-F(X)核心中,通过评估线性化泊松-玻尔兹曼方程解的静电能,研究了两个醌A(1A/B)和铁硫簇F(X)的氧化还原电位(E(m))以及相应的质子化模式。分离P700-F(X)核心后,B侧特异性的天冬氨酸-B558的质子化状态发生了显著变化,在天然PSI复合物中主要处于质子化状态,而在P700-F(X)核心中则处于离子化状态。在P700-F(X)核心中,E(m)(A(1A/B))实际上保持不变,而E(m)(F(X))上移了42 mV。根据这些计算出的E(m)值,估计P700-F(X)核心中从A(1)到F(X)的电子转移速率在A(1A)侧比野生型略快,这与动力学测量结果一致。
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