简单的少体模型揭示了蛋白质折叠中的隐藏复杂性。
Simple few-state models reveal hidden complexity in protein folding.
机构信息
Biophysics Program, Stanford University, Stanford, CA 94305, USA.
出版信息
Proc Natl Acad Sci U S A. 2012 Oct 30;109(44):17807-13. doi: 10.1073/pnas.1201810109. Epub 2012 Jul 9.
Abstract
Markov state models constructed from molecular dynamics simulations have recently shown success at modeling protein folding kinetics. Here we introduce two methods, flux PCCA+ (FPCCA+) and sliding constraint rate estimation (SCRE), that allow accurate rate models from protein folding simulations. We apply these techniques to fourteen massive simulation datasets generated by Anton and Folding@home. Our protocol quantitatively identifies the suitability of describing each system using two-state kinetics and predicts experimentally detectable deviations from two-state behavior. An analysis of the villin headpiece and FiP35 WW domain detects multiple native substates that are consistent with experimental data. Applying the same protocol to GTT, NTL9, and protein G suggests that some beta containing proteins can form long-lived native-like states with small register shifts. Even the simplest protein systems show folding and functional dynamics involving three or more states.
摘要
基于分子动力学模拟构建的马尔可夫状态模型最近在模拟蛋白质折叠动力学方面取得了成功。在这里,我们介绍了两种方法,通量主成分相关分析加(FPCCA+)和滑动约束速率估计(SCRE),它们允许从蛋白质折叠模拟中获得准确的速率模型。我们将这些技术应用于由 Anton 和 Folding@home 生成的 14 个大规模模拟数据集。我们的方案定量地确定了使用两态动力学描述每个系统的适用性,并预测了实验上可检测到的偏离两态行为。对 villin 头部片段和 FiP35 WW 结构域的分析检测到多个与实验数据一致的天然亚稳态。将相同的方案应用于 GTT、NTL9 和蛋白 G 表明,一些含有β的蛋白质可以形成具有小的寄存器移位的长寿命天然样状态。即使是最简单的蛋白质系统也显示出涉及三个或更多状态的折叠和功能动力学。
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