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离子强度对肌球蛋白亚片段1-核苷酸复合物构象的影响。

Effect of ionic strength on the conformation of myosin subfragment 1-nucleotide complexes.

作者信息

Peyser Y M, Ajtai K, Burghardt T P, Muhlrad A

机构信息

Hebrew University Hadassah School of Dental Medicine, Institute of Dental Sciences, Department of Oral Biology, Jerusalem 91120, Israel.

出版信息

Biophys J. 2001 Aug;81(2):1101-14. doi: 10.1016/s0006-3495(01)75767-0.

DOI:10.1016/s0006-3495(01)75767-0
PMID:11463651
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1301579/
Abstract

The effect of ionic strength on the conformation and stability of S1 and S1-nucleotide-phosphate analog complexes in solution was studied. It was found that increasing concentration of KCl enhances the reactivity of Cys(707) (SH1 thiol) and Lys(84) (reactive lysyl residue) and the nucleotide-induced tryptophan fluorescence increment. In contrast, high KCl concentration lowers the structural differences between the intermediate states of ATP hydrolysis in the vicinity of Cys(707), Trp(510) and the active site, possibly by increasing the flexibility of the molecule. High concentrations of neutral salts inhibit both the formation and the dissociation of the M**.ADP.Pi analog S1.ADP.Vi complex. High ionic strength profoundly affects the structure of the stable S1.ADP.BeF(x) complex, by destabilizing the M*.ATP intermediate, which is the predominant form of the complex at low ionic strength, and shifting the equilibrium to favor the M**.ADP.Pi state. The M*.ATP intermediate is destabilized by perturbation of ionic interactions possibly by disruption of salt bridges. Two salt-bridge pairs, Glu(501)-Lys(505) in the Switch II helix and Glu(776)-Lys(84) connecting the catalytic domain to the lever arm, seem most appropriate to consider for participating in the ionic strength-induced transition of the open M*.ATP to the closed M**.ADP.Pi state of S1.

摘要

研究了离子强度对溶液中S1以及S1 - 核苷酸 - 磷酸类似物复合物的构象和稳定性的影响。发现增加KCl浓度可增强半胱氨酸(707)(SH1硫醇)和赖氨酸(84)(反应性赖氨酰残基)的反应性以及核苷酸诱导的色氨酸荧光增量。相反,高KCl浓度可能通过增加分子的柔韧性来降低半胱氨酸(707)、色氨酸(510)附近以及活性位点处ATP水解中间状态之间的结构差异。高浓度的中性盐会抑制M**.ADP.Pi类似物S1.ADP.Vi复合物的形成和解离。高离子强度会深刻影响稳定的S1.ADP.BeF(x)复合物的结构,它会使M*.ATP中间体不稳定,而M*.ATP中间体是低离子强度下复合物的主要形式,从而使平衡向有利于M**.ADP.Pi状态的方向移动。M*.ATP中间体可能通过破坏盐桥扰乱离子相互作用而变得不稳定。开关II螺旋中的谷氨酸(501) - 赖氨酸(505)以及连接催化结构域和杠杆臂的谷氨酸(776) - 赖氨酸(84)这两对盐桥似乎最有可能参与离子强度诱导的S1从开放的M*.ATP状态到封闭的M**.ADP.Pi状态的转变。

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