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比较经验蛋白质力场用于模拟结构化 LK 肽在功能化表面上的吸附行为。

Comparison between empirical protein force fields for the simulation of the adsorption behavior of structured LK peptides on functionalized surfaces.

机构信息

Department of Bioengineering, Clemson University, Clemson, SC 29634, USA.

出版信息

Biointerphases. 2012 Dec;7(1-4):24. doi: 10.1007/s13758-012-0024-z. Epub 2012 Mar 1.

DOI:10.1007/s13758-012-0024-z
PMID:22589067
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4243546/
Abstract

All-atom empirical molecular mechanics protein force fields, which have been developed to represent the energetics of peptide folding behavior in aqueous solution, have not been parameterized for protein interactions with solid material surfaces. As a result, their applicability for representing the adsorption behavior of proteins with functionalized material surfaces should not be assumed. To address this issue, we conducted replica-exchange molecular dynamics simulations of the adsorption behavior of structured peptides to functionalized surfaces using three protein force fields that are widely used for the simulation of peptide adsorption behavior: CHARMM22, AMBER94, and OPLS-AA. Simulation results for peptide structure both in solution and when adsorbed to the surfaces were compared to experimental results for similar peptide-surface systems to provide a means of evaluating and comparing the performance of these three force fields for this type of application. Substantial differences in both solution and adsorbed peptide conformations were found amongst these three force fields, with the CHARMM22 force field found to most closely match experimental results.

摘要

全原子经验分子力学蛋白质力场,旨在代表肽在水溶液中折叠行为的能量学,尚未针对蛋白质与固体材料表面的相互作用进行参数化。因此,不应假设它们适用于表示具有功能化材料表面的蛋白质的吸附行为。为了解决这个问题,我们使用三种广泛用于模拟肽吸附行为的蛋白质力场(CHARMM22、AMBER94 和 OPLS-AA)进行了结构肽在功能化表面上吸附行为的复制交换分子动力学模拟。比较了溶液中和吸附在表面上的肽结构的模拟结果与类似肽-表面系统的实验结果,为评估和比较这三种力场在这种应用类型中的性能提供了一种方法。在这三种力场中,溶液和吸附的肽构象都存在显著差异,CHARMM22 力场与实验结果最匹配。

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