通过分子动力学模拟预测各种突变的血管性血友病因子与血小板糖蛋白 Ibα 之间的结合特性。

Prediction of binding characteristics between von Willebrand factor and platelet glycoprotein Ibα with various mutations by molecular dynamic simulation.

机构信息

Department of Medicine (Cardiology), Tokai University School of Medicine, Metabolic Disease Research Center, Tokai University Graduate School of Medicine, Isehara, Japan; Department of Cardiology, Keio University School of Medicine, Tokyo, Japan.

Department of Medicine (Cardiology), Tokai University School of Medicine, Metabolic Disease Research Center, Tokai University Graduate School of Medicine, Isehara, Japan.

出版信息

Thromb Res. 2019 Dec;184:129-135. doi: 10.1016/j.thromres.2019.10.022. Epub 2019 Oct 24.

DOI:10.1016/j.thromres.2019.10.022

PMID:31739151

Abstract

INTRODUCTION

Binding of platelet glycoprotein (GP)Ibα with von-Willebrand factor (VWF) exclusively mediates the initial platelet adhesion to injured vessel wall. To understand the mechanism of biomedical functions, we calculated the dynamic fluctuating three-dimensional (3D) structures and dissociation energy for GPIbα with various single amino-acid substitution at G233, which location is known to cause significant changes in platelet adhesive characteristics.

MATERIAL AND METHODS

Molecular dynamics (MD) simulation was utilized to calculate 3D structures and Potential of Mean Force (PMF) for wild-type VWF bound with wild-type, G233A (equal function), G233V (gain of function), and G233D (loss of function) GPIbα. Simulation was done on water-soluble condition with time-step of 2 × 10 s using NAnoscale Molecular Dynamics (NAMD) with Chemistry at HARvard Molecular Mechanics (CHARMM) force field. Initial structure for each mutant was obtained by inducing single amino-acid substitution to the stable water-soluble binding structure of wild-type.

RESULTS

The most stable structures of wild-type VWF bound to GPIbα in wild-type or any mutant did not differ. However, bond dissociation energy defined as difference of PMF between most stable structure and the structure at 65 Å mass center distances in G233D was 4.32 kcal/mol (19.5%) lower than that of wild-type. Approximately, 2.07 kcal/mol energy was required to dissociate VWF from GPIbα with G233V at mass center distance from 48 to 52 Å, which may explain the apparent "gain of function" in G233V.

CONCLUSION

The mechanism of substantially different biochemical characteristics of GPIbα with mutations in G233 location was predicted from physical movement of atoms constructing these proteins.

摘要

简介

血小板糖蛋白 (GP)Ibα 与血管性血友病因子 (VWF) 的结合专门介导初始血小板与受损血管壁的黏附。为了理解其生物医学功能的机制，我们计算了不同单氨基酸取代 G233 位置的 GPIbα 的动态波动三维 (3D) 结构和离解能，该位置已知会导致血小板黏附特性发生显著变化。

材料与方法

使用分子动力学 (MD) 模拟计算了与野生型、G233A（等效功能）、G233V（功能获得）和 G233D（功能丧失）GPIbα 结合的野生型 VWF 的 3D 结构和平均力势 (PMF)。模拟在水溶性条件下进行，时间步长为 2×10-12s，使用 NAnoscale Molecular Dynamics (NAMD) 结合 Chemistry at HARvard Molecular Mechanics (CHARMM) 力场。每个突变体的初始结构是通过诱导野生型稳定水溶性结合结构中的单个氨基酸取代获得的。

结果

野生型 VWF 与 GPIbα 结合的最稳定结构在野生型或任何突变体中没有差异。然而，定义为最稳定结构与质心距离为 65Å 时的 PMF 之间差异的键离解能 G233D 为 4.32kcal/mol（19.5%）低于野生型。大约需要 2.07kcal/mol 的能量才能将 VWF 从 G233V 的质心距离为 48 至 52Å 处的 GPIbα 上解离，这可能解释了 G233V 中的明显“功能获得”。

结论

从构建这些蛋白质的原子的物理运动预测了 G233 位置突变的 GPIbα 具有明显不同的生化特征的机制。

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通过分子动力学模拟预测各种突变的血管性血友病因子与血小板糖蛋白 Ibα 之间的结合特性。

Prediction of binding characteristics between von Willebrand factor and platelet glycoprotein Ibα with various mutations by molecular dynamic simulation.

机构信息

出版信息

INTRODUCTION

MATERIAL AND METHODS

RESULTS

CONCLUSION

简介

材料与方法

结果

结论

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