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针对耐药性HIV-1整合酶T66I/M154I催化结构域计算的多个分子动力学轨迹的比较。

Comparison of multiple molecular dynamics trajectories calculated for the drug-resistant HIV-1 integrase T66I/M154I catalytic domain.

作者信息

Brigo Alessandro, Lee Keun Woo, Iurcu Mustata Gabriela, Briggs James M

机构信息

Dipartimento di Scienze Farmaceutiche, Università degli Studi di Padova, 35131 Padova, Italy.

出版信息

Biophys J. 2005 May;88(5):3072-82. doi: 10.1529/biophysj.104.050286. Epub 2005 Mar 11.

DOI:10.1529/biophysj.104.050286
PMID:15764656
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1305459/
Abstract

HIV-1 integrase (IN) is an essential enzyme for the viral replication and an interesting target for the design of new pharmaceuticals for multidrug therapy of AIDS. Single and multiple mutations of IN at residues T66, S153, or M154 confer degrees of resistance to several inhibitors that prevent the enzyme from performing its normal strand transfer activity. Four different conformations of IN were chosen from a prior molecular dynamics (MD) simulation on the modeled IN T66I/M154I catalytic core domain as starting points for additional MD studies. The aim of this article is to understand the dynamic features that may play roles in the catalytic activity of the double mutant enzyme in the absence of any inhibitor. Moreover, we want to verify the influence of using different starting points on the MD trajectories and associated dynamical properties. By comparison of the trajectories obtained from these MD simulations we have demonstrated that the starting point does not affect the conformational space explored by this protein and that the time of the simulation is long enough to achieve convergence for this system.

摘要

HIV-1整合酶(IN)是病毒复制所必需的酶,也是设计用于艾滋病多药治疗的新型药物的一个有趣靶点。IN在T66、S153或M154位点的单突变和多突变赋予了对几种抑制剂的不同程度抗性,这些抑制剂可阻止该酶进行正常的链转移活性。从先前对建模的IN T66I/M154I催化核心结构域进行的分子动力学(MD)模拟中选择了四种不同的IN构象,作为额外MD研究的起点。本文的目的是了解在没有任何抑制剂的情况下,可能在双突变酶催化活性中起作用的动态特征。此外,我们想验证使用不同起点对MD轨迹和相关动力学性质的影响。通过比较从这些MD模拟获得的轨迹,我们证明了起点不会影响该蛋白质探索的构象空间,并且模拟时间足够长,以使该系统达到收敛。

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Comparative molecular dynamics simulations of HIV-1 integrase and the T66I/M154I mutant: binding modes and drug resistance to a diketo acid inhibitor.
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