基于低频振动模式的小型球状蛋白质动力学
Dynamics of a small globular protein in terms of low-frequency vibrational modes.
作者信息
Go N, Noguti T, Nishikawa T
出版信息
Proc Natl Acad Sci U S A. 1983 Jun;80(12):3696-700. doi: 10.1073/pnas.80.12.3696.
Abstract
Normal modes of low-frequency vibrations are calculated for a small globular protein, bovine pancreatic trypsin inhibitor. In modes with frequencies below 120 cm-1 the protein molecule behaves like a continuous elastic body. Most modes with frequencies above 50 cm-1 are shown to behave harmonically within the range of thermal fluctuations at room temperature. Those with frequencies below 50 cm-1 show some anharmonicity. Magnitudes of displacements of atoms are mainly determined by the modes with frequencies below 30 cm-1. These very-low-frequency modes contribute significantly to the entropy of the system. The dynamic structure of the globular protein is described as a superposition of harmonic high-frequency motions and coupled anharmonic low-frequency motions of collective variables corresponding to the normal modes of vibration.
摘要
计算了小型球状蛋白质牛胰蛋白酶抑制剂的低频振动的正常模式。在频率低于120厘米-1的模式中,蛋白质分子的行为类似于连续弹性体。大多数频率高于50厘米-1的模式在室温下的热波动范围内表现为谐波。频率低于50厘米-1的模式表现出一些非谐性。原子位移的大小主要由频率低于30厘米-1的模式决定。这些超低频模式对系统的熵有显著贡献。球状蛋白质的动态结构被描述为对应于正常振动模式的集体变量的谐波高频运动和耦合非谐低频运动的叠加。
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