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对肌红蛋白内部氧气、一氧化碳、一氧化氮和氙气的迁移路径进行成像。

Imaging the migration pathways for O2, CO, NO, and Xe inside myoglobin.

作者信息

Cohen Jordi, Arkhipov Anton, Braun Rosemary, Schulten Klaus

机构信息

Department of Physics and Beckman Institute, University of Illinois, Urbana, Illinois, USA

出版信息

Biophys J. 2006 Sep 1;91(5):1844-57. doi: 10.1529/biophysj.106.085746. Epub 2006 Jun 2.

DOI:10.1529/biophysj.106.085746
PMID:16751246
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1544290/
Abstract

Myoglobin (Mb) is perhaps the most studied protein, experimentally and theoretically. Despite the wealth of known details regarding the gas migration processes inside Mb, there exists no fully conclusive picture of these pathways. We address this deficiency by presenting a complete map of all the gas migration pathways inside Mb for small gas ligands (O2, NO, CO, and Xe). To accomplish this, we introduce a computational approach for studying gas migration, which we call implicit ligand sampling. Rather than simulating actual gas migration events, we infer the location of gas migration pathways based on a free-energy perturbation approach applied to simulations of Mb's dynamical fluctuations at equilibrium in the absence of ligand. The method provides complete three-dimensional maps of the potential of mean force of gas ligand placement anywhere inside a protein-solvent system. From such free-energy maps we identify each gas docking site, the pathways between these sites, to the heme and to the external solution. Our maps match previously known features of these pathways in Mb, but also point to the existence of additional exits from the protein matrix in regions that are not easily probed by experiment. We also compare the pathway maps of Mb for different gas ligands and for different animal species.

摘要

肌红蛋白(Mb)可能是在实验和理论方面研究最多的蛋白质。尽管关于Mb内部气体迁移过程已知的细节丰富,但对于这些途径尚无完全确凿的图景。我们通过呈现Mb内部针对小气体配体(O₂、NO、CO和Xe)的所有气体迁移途径的完整图谱来解决这一不足。为实现这一目标,我们引入了一种研究气体迁移的计算方法,我们称之为隐式配体采样。我们不是模拟实际的气体迁移事件,而是基于一种自由能微扰方法来推断气体迁移途径的位置,该方法应用于在无配体情况下Mb在平衡态时动态涨落的模拟。该方法提供了蛋白质 - 溶剂系统内任何位置气体配体放置的平均力势的完整三维图谱。从这些自由能图谱中,我们确定每个气体对接位点、这些位点之间通向血红素和外部溶液的途径。我们的图谱与Mb中这些途径先前已知的特征相匹配,但也指出在实验难以探测的区域存在从蛋白质基质的其他出口。我们还比较了不同气体配体和不同动物物种的Mb的途径图谱。

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