生物大分子中的内部水分子与氢键:具有功能意义的结构特征综述
Internal water molecules and H-bonding in biological macromolecules: a review of structural features with functional implications.
作者信息
Meyer E
机构信息
Department of Biochemistry and Biophysics, Texas A&M University, College Station 77843-2128.
出版信息
Protein Sci. 1992 Dec;1(12):1543-62. doi: 10.1002/pro.5560011203.
Abstract
Conserved structural patterns of internal water molecules and/or H-bond chains were observed and are here correlated in this review, which then describes two functional properties: equilibration of hydrostatic pressure and proton transport. Available evidence in support of these hypotheses is presented, together with suggested experiments to test them. High-resolution crystal structures of a variety of proteins were studied with interactive computer graphics. Conserved H-bonding linkages may be used as a paradigm for a rationalization of proton transport in membranes. The concept of the "proton wire," which links buried active-site amino acids with the surface of the protein raises the more general question of the functional role of the various molecular components.
摘要
在本综述中观察到了内部水分子和/或氢键链的保守结构模式,并将其关联起来,随后描述了两种功能特性:静水压力平衡和质子传输。文中提供了支持这些假设的现有证据以及用于验证它们的建议实验。利用交互式计算机图形技术研究了多种蛋白质的高分辨率晶体结构。保守的氢键连接可作为解释膜中质子传输的范例。将埋藏的活性位点氨基酸与蛋白质表面连接起来的“质子线”概念引发了关于各种分子成分功能作用的更普遍问题。
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