Solvent Site-Dipole Field Accompanying Protein-Ligand Approach Process

IF 0.4 Q4 BIOCHEMISTRY & MOLECULAR BIOLOGY

Chem-Bio Informatics Journal Pub Date : 2008-01-01 DOI:10.1273/CBIJ.8.14

N. Takano, K. Umezawa, Jinzen Ikebe, Yuki Sonobe, Ryosuke Yagisawa, Ito Junichi, N. Hamasaki, D. Mitomo, H. Miyagawa, A. Yamagishi, J. Higo

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引用次数: 7

Abstract

We did a molecular dynamics simulation of a system consisting of a peptide and a protein in explicit solvent to study biomolecular approach process. In the initial structure of simulation, the minimum inter-biomolecular distance was 30 A. During the simulation, the biomolecules approached and contacted to each other. In spite of diffusive motions of water molecules, the orientations of water molecules tended to order in the inter-biomolecular zone showing coherent spatial patterns (solvent site-dipole field) of the ordering. The degree of ordering was synchronized well with the inter-biomolecular distance. This result strongly suggests that the biomolecules distant to each other can interact via the solvent site-dipole field. The effective range for the coherent ordering (i.e., the interaction range via the solvent site-dipole field) was larger than 20 A. A bridge-like structure of the solvent orientational ordering connected the two biomolecules. Biological and physicochemical significance of the ordering is discussed.

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溶剂位偶极子场伴随蛋白质配体接近过程

为了研究生物分子接近过程，我们对肽和蛋白质在显式溶剂中的分子动力学模拟进行了研究。在模拟的初始结构中，生物分子间的最小距离为30 A。在模拟过程中，生物分子相互接近并接触。尽管水分子具有弥漫性运动，但在生物分子间区，水分子的取向倾向于有序，表现出有序的空间格局(溶剂位-偶极子场)。排序程度与生物分子间距离同步良好。这一结果有力地表明，距离较远的生物分子可以通过溶剂位偶极子场相互作用。相干有序的有效范围(即通过溶剂位偶极子场的相互作用范围)大于20 A。溶剂取向有序的桥状结构连接了两个生物分子。讨论了排序的生物学和物理化学意义。

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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来源期刊

Chem-Bio Informatics Journal BIOCHEMISTRY & MOLECULAR BIOLOGY-

CiteScore

0.60

自引率

0.00%

发文量