Physical Characteristics of von Willebrand Factor Binding with Platelet Glycoprotein Ibɑ Mutants at Residue 233 Causing Various Biological Functions.

Masamitsu Nakayama, Shinichi Goto, Shinya Goto
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引用次数: 1

Abstract

Glycoprotein (GP: HIS 1 -PRO 265 ) Ibɑ is a receptor protein expressed on the surface of the platelet. Its N-terminus domain binds with the A1 domain (ASP 1269 -PRO 1472 ) of its ligand protein von Willebrand factor (VWF) and plays a unique role in platelet adhesion under blood flow conditions. Single amino acid substitutions at residue 233 from glycine (G) to alanine (A), aspartic acid (D), or valine (V) are known to cause biochemically distinct functional alterations known as equal, loss, and gain of function, respectively. However, the underlying physical characteristics of VWF binding with GPIbɑ in wild-type and the three mutants exerting different biological functions are unclear. Here, we aimed to test the hypothesis: biological characteristics of macromolecules are influenced by small changes in physical parameters. The position coordinates and velocity vectors of all atoms and water molecules constructing the wild-type and the three mutants of GPIbɑ (G233A, G233D, and G233V) bound with VWF were calculated every 2 × 10 -15 seconds using the CHARMM (Chemistry at Harvard Macromolecular Mechanics) force field for 9 × 10 -10 seconds. Six salt bridges were detected for longer than 50% of the calculation period for the wild-type model generating noncovalent binding energy of -1096 ± 137.6 kcal/mol. In contrast, only four pairs of salt bridges were observed in G233D mutant with noncovalent binding energy of -865 ± 139 kcal/mol. For G233A and G233V, there were six and five pairs of salt bridges generating -929.8 ± 88.5 and -989.9 ± 94.0 kcal/mol of noncovalent binding energy, respectively. Our molecular dynamic simulation showing a lower probability of salt bridge formation with less noncovalent binding energy in VWF binding with the biologically loss of function G233D mutant of GPIbɑ as compared with wild-type, equal function, and gain of function mutant suggests that biological functions of macromolecules such as GPIbɑ are influenced by their small changes in physical characteristics.

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血管性血友病因子与血小板糖蛋白Ib突变体在233位点结合引起多种生物学功能的物理特性
糖蛋白(GP: HIS 1 -PRO 265)是一种表达于血小板表面的受体蛋白。其n端结构域与其配体蛋白血管性血液病因子(VWF)的A1结构域(ASP 1269 -PRO 1472)结合,在血流条件下血小板粘附中发挥独特作用。已知在残基233上,甘氨酸(G)取代丙氨酸(A)、天冬氨酸(D)或缬氨酸(V)会导致生物化学上不同的功能改变,分别称为功能相等、丧失和获得。然而,野生型和三种发挥不同生物学功能的突变体中VWF与GPIb的结合的潜在物理特性尚不清楚。在这里,我们的目的是验证假设:大分子的生物学特性受到物理参数的微小变化的影响。利用CHARMM (Harvard Macromolecular Mechanics化学系)力场,每2 × 10 -15秒计算构建野生型和GPIb突变体(G233A、G233D和G233V)与VWF结合的所有原子和水分子的位置坐标和速度矢量,时间为9 × 10 -10秒。在野生型模型计算周期的50%以上,检测到6个盐桥,产生的非共价结合能为-1096±137.6 kcal/mol。相比之下,G233D突变体中只观察到4对盐桥,非共价结合能为-865±139 kcal/mol。对于G233A和G233V,分别存在6对和5对盐桥,分别产生-929.8±88.5和-989.9±94.0 kcal/mol的非共价结合能。我们的分子动力学模拟显示,与野生型、功能相等、功能获得的突变体相比,GPIb / G233D突变体与VWF结合时,盐桥形成的概率更低,非共价结合能更少,这表明GPIb / G233D突变体等大分子的生物学功能受到其物理特性微小变化的影响。
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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