通过X射线、荧光寿命和分子动力学建模所证实的色氨酸旋转异构体。
Tryptophan rotamers as evidenced by X-ray, fluorescence lifetimes, and molecular dynamics modeling.
作者信息
Moors Samuel L C, Hellings Mario, De Maeyer Marc, Engelborghs Yves, Ceulemans Arnout
机构信息
Laboratory of Quantum Chemistry, University of Leuven, Leuven, Belgium.
出版信息
Biophys J. 2006 Aug 1;91(3):816-23. doi: 10.1529/biophysj.106.085100. Epub 2006 May 12.
Abstract
We investigated the native-state dynamics of the Bacillus caldolyticus cold-shock protein mutant Bc-Csp L66E, using fluorescence and appropriate molecular dynamics methods. Two fluorescence lifetimes were found, the amplitudes of which agree very well with tryptophan rotamer populations, obtained from parallel tempering calculations. Rotamer lifetimes were predicted by transition-state theory from high-temperature simulations. Transition pathways were extracted from the transition rates between individual rotameric states. The molecular dynamics also reveal the loop fluctuations in the native state.
摘要
我们使用荧光和适当的分子动力学方法,研究了嗜热栖热芽孢杆菌冷休克蛋白突变体Bc-Csp L66E的天然态动力学。发现了两种荧光寿命,其幅度与通过并行回火计算获得的色氨酸旋转异构体群体非常吻合。通过高温模拟的过渡态理论预测了旋转异构体寿命。从各个旋转异构体状态之间的转换速率中提取了过渡路径。分子动力学还揭示了天然态中的环波动。
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