Stereochemistry of polypeptide conformation in coarse grained analysis

Anil Korkut, W. Hendrickson
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引用次数: 1

Abstract

The conformations available to polypeptides are determined by the interatomic forces acting on the peptide units, whereby backbone torsion angles are restricted as described by the Ramachandran plot. Although typical proteins are composed predominantly from {\alpha}-helices and {\beta}-sheets, they nevertheless adopt diverse tertiary structure, each folded as dictated by its unique amino-acid sequence. Despite such uniqueness, however, the functioning of many proteins involves changes between quite different conformations. The study of large-scale conformational changes, particularly in large systems, is facilitated by a coarse-grained representation such as provided by virtually bonded C{\alpha} atoms. We have developed a virtual atom molecular mechanics (VAMM) force field to describe conformational dynamics in proteins and a VAMM-based algorithm for computing conformational transition pathways. Here we describe the stereochemical analysis of proteins in this coarse-grained representation, comparing the relevant plots in coarse-grained conformational space to the corresponding Ramachandran plots, having contoured each at levels determined statistically from residues in a large database. The distributions shown for an all-{\alpha} protein, two all-{\beta} proteins and one {\alpha}+{\beta} protein serve to relate the coarse-grained distributions to the familiar Ramachandran plot.
粗粒分析中多肽构象的立体化学
多肽的构象是由作用在肽单元上的原子间作用力决定的,因此主链扭转角受到拉马钱德兰图所描述的限制。虽然典型的蛋白质主要由{\alpha} -螺旋和{\beta} -薄片组成,但它们仍然采用不同的三级结构,每种结构都按照其独特的氨基酸序列折叠。然而,尽管有这样的独特性,许多蛋白质的功能涉及到不同构象之间的变化。大规模构象变化的研究,特别是在大型系统中,可以通过虚拟键合C {\alpha}原子提供的粗粒度表示来促进。我们开发了一个虚拟原子分子力学力场来描述蛋白质的构象动力学,并开发了一个基于虚拟原子分子力学力场的计算构象转变途径的算法。在这里,我们描述了这种粗粒度表示中蛋白质的立体化学分析,将粗粒度构象空间中的相关图与相应的Ramachandran图进行比较,并在大型数据库中的残基统计确定的水平上对每个图进行轮廓。一个全{\alpha}蛋白、两个全{\beta}蛋白和一个{\alpha} + {\beta}蛋白的分布将粗粒度分布与熟悉的Ramachandran图联系起来。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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