细胞色素c氧化酶中金属中心的电荷参数化

Charge parameterization of the metal centers in cytochrome c oxidase.

作者信息

Johansson Mikael P, Kaila Ville R I, Laakkonen Liisa

机构信息

Department of Chemistry, University of Helsinki, P.O. Box 55, FI-00014 Helsinki, Finland.

出版信息

J Comput Chem. 2008 Apr 15;29(5):753-67. doi: 10.1002/jcc.20835.

DOI:10.1002/jcc.20835

PMID:17876762

Abstract

Reliable atomic point charges are of key importance for a correct description of the electrostatic interactions when performing classical, force field based simulations. Here, we present a systematic procedure for point charge derivation, based on quantum mechanical methodology suited for the systems at hand. A notable difference to previous procedures is to include an outer region around the actual system of interest. At the cost of increasing the system sizes, here up to 265 atoms, including the surroundings achieves near-neutrality for the systems as well as structural stability, important factors for reliable charge distributions. In addition, the common problem of converting between C--H bonds and C--C bonds at the border vanishes. We apply the procedure to the four redox-active metal centers of cytochrome c oxidase: Cu(A), haem a, haem a(3), and Cu(B). Several relevant charge and ligand states are considered. Charges for two different force fields, CHARMM and AMBER, are presented.

摘要

在进行基于经典力场的模拟时，可靠的原子点电荷对于正确描述静电相互作用至关重要。在此，我们基于适用于手头系统的量子力学方法，提出了一种系统的点电荷推导程序。与先前程序的一个显著差异是在实际感兴趣的系统周围包含一个外部区域。以增加系统规模为代价，此处系统规模可达265个原子，包括周围环境，实现了系统的近中性以及结构稳定性，这是可靠电荷分布的重要因素。此外，在边界处C-H键和C-C键之间转换的常见问题也消失了。我们将该程序应用于细胞色素c氧化酶的四个氧化还原活性金属中心：Cu(A)、血红素a、血红素a(3)和Cu(B)。考虑了几种相关的电荷和配体状态。给出了两种不同力场（CHARMM和AMBER）的电荷。

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细胞色素c氧化酶中金属中心的电荷参数化

Charge parameterization of the metal centers in cytochrome c oxidase.

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