Explicit solvation of a single-stranded DNA, a binding protein, and their complex: a suitable protocol for fragment molecular orbital calculation

IF 0.4 Q4 BIOCHEMISTRY & MOLECULAR BIOLOGY Chem-Bio Informatics Journal Pub Date : 2017-07-30 DOI:10.1273/CBIJ.17.72

Yuto Komeij, Yoshio Okiyama, Y. Mochizuki, Kaori Fukuzawa

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引用次数: 6

Abstract

Fragment molecular orbital (FMO) calculations were performed for explicitly solvated single-stranded DNA (ssDNA), ssDNA binding protein, and their complex in order to assess the solvent effects on the solutes and thereby to find optimal solvation conditions for FMO calculation. A series of solvated structures were generated with different solvent thicknesses. The structures were subjected to FMO calculation at MP2/6-31G* to obtain the net charges and internal energies of the solutes and the solute–solvent interaction energies as functions of the solvent thickness. In all cases, the properties showed complete or marginal convergence at ca. 6 Ǻ, regardless whether or not the system charge was neutralized. This suggested that the first and second solvent shells mainly determine the electronic structure of a solute while the outer solvent including ions has only minor effects, consistent with several preceding reports. In light of this, and considering safety as a factor, we conclude that a solvent shell thickness of ca. 8 Ǻ suffices for FMO calculation of the solutes.

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单链DNA，结合蛋白及其复合物的显式溶剂化:片段分子轨道计算的合适方案

对明确溶剂化的单链DNA (ssDNA)、ssDNA结合蛋白及其复合物进行片段分子轨道(FMO)计算，以评估溶剂对溶质的影响，从而找到计算FMO的最佳溶剂化条件。在不同的溶剂厚度下，生成了一系列的溶剂化结构。在MP2/6-31G*下进行FMO计算，得到溶质的净电荷和内能以及溶质-溶剂相互作用能随溶剂厚度的变化。在所有情况下，性质显示完全或边际收敛在ca. 6 Ǻ，无论系统电荷是否被中和。这表明第一和第二溶剂壳层主要决定溶质的电子结构，而包括离子在内的外部溶剂对溶质的电子结构影响很小，这与之前的一些报道一致。鉴于此，并考虑到安全因素，我们得出结论，溶剂壳厚度约为8 Ǻ足以进行溶质的FMO计算。

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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Chem-Bio Informatics Journal BIOCHEMISTRY & MOLECULAR BIOLOGY-

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0.60

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