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细胞色素P450cam中水分子介导蛋白质-配体相互作用的热力学:一项分子动力学研究

Thermodynamics of water mediating protein-ligand interactions in cytochrome P450cam: a molecular dynamics study.

作者信息

Helms V, Wade R C

机构信息

European Molecular Biology Laboratory, Heidelberg, Germany.

出版信息

Biophys J. 1995 Sep;69(3):810-24. doi: 10.1016/S0006-3495(95)79955-6.

DOI:10.1016/S0006-3495(95)79955-6
PMID:8519982
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1236311/
Abstract

Ordered water molecules are observed by crystallography and nuclear magnetic resonance to mediate protein-ligand interactions. Here, we examine the energetics of hydrating cavities formed at protein-ligand interfaces using molecular dynamics simulations. The free energies of hydrating two cavities in the active site of two liganded complexes of cytochrome P450cam were calculated by multiconfigurational thermodynamic integration. The complex of cytochrome P450cam with 2-phenyl-imidazole contains a crystallographically well defined water molecule mediating hydrogen bonds between the protein and the inhibitor. We calculate that this water molecule is stabilized by a binding free energy of -11.6 +/- kJ/mol. The complex of cytochrome P450cam with its natural substrate, camphor, contains a cavity that is empty in the crystal structure although a water molecule in it could make a hydrogen bond to camphor. Here, solvation of this cavity is calculated to be unfavorable by +15.8 +/- 5.0 kJ/mol. The molecular dynamics simulations can thus distinguish a hydrated interfacial cavity from an empty one. They also provide support for the notion that protein-ligand complexes can accommodate empty interfacial cavities and that such cavities are likely to be unhydrated unless more than one hydrogen bond can be made to a water molecule in the cavity.

摘要

通过晶体学和核磁共振观察到有序水分子介导蛋白质-配体相互作用。在此,我们使用分子动力学模拟研究蛋白质-配体界面形成的水合腔的能量学。通过多构型热力学积分计算了细胞色素P450cam两种配体复合物活性位点中两个水合腔的自由能。细胞色素P450cam与2-苯基咪唑的复合物包含一个在晶体学上定义明确的水分子,该水分子介导蛋白质与抑制剂之间的氢键。我们计算出这个水分子通过-11.6±kJ/mol的结合自由能得以稳定。细胞色素P450cam与其天然底物樟脑的复合物包含一个在晶体结构中为空的腔,尽管其中的一个水分子可以与樟脑形成氢键。在此,计算得出该腔的溶剂化是不利的,自由能为+15.8±5.0 kJ/mol。因此,分子动力学模拟可以区分水合的界面腔和空的界面腔。它们还为以下观点提供了支持:蛋白质-配体复合物可以容纳空的界面腔,并且除非能与腔内的水分子形成不止一个氢键,否则这种腔很可能是未水合的。

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