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利用广义系综模拟研究蛋白质折叠中的疏水核形成和脱水。

Hydrophobic core formation and dehydration in protein folding studied by generalized-ensemble simulations.

机构信息

Nagahama Institute of Bio-Science and Technology, Tamura, Nagahama, Shiga, Japan.

出版信息

Biophys J. 2010 Sep 8;99(5):1637-44. doi: 10.1016/j.bpj.2010.06.045.

DOI:10.1016/j.bpj.2010.06.045
PMID:20816077
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2931739/
Abstract

Despite its small size, chicken villin headpiece subdomain HP36 folds into the native structure with a stable hydrophobic core within several microseconds. How such a small protein keeps up its conformational stability and fast folding in solution is an important issue for understanding molecular mechanisms of protein folding. In this study, we performed multicanonical replica-exchange simulations of HP36 in explicit water, starting from a fully extended conformation. We observed at least five events of HP36 folding into nativelike conformations. The smallest backbone root mean-square deviation from the crystal structure was 1.1 A. In the nativelike conformations, the stably formed hydrophobic core was fully dehydrated. Statistical analyses of the simulation trajectories show the following sequential events in folding of HP36: 1), Helix 3 is formed at the earliest stage; 2), the backbone and the side chains near the loop between Helices 2 and 3 take nativelike conformations; and 3), the side-chain packing at the hydrophobic core and the dehydration of the core side chains take place simultaneously at the later stage of folding. This sequence suggests that the initial folding nucleus is not necessarily the same as the hydrophobic core, consistent with a recent experimental phi-value analysis.

摘要

尽管体积很小,但鸡肌球蛋白头部亚结构域 HP36 可以在几微秒内折叠成天然结构,形成稳定的疏水核心。如此小的蛋白质如何在溶液中保持构象稳定性和快速折叠,是理解蛋白质折叠分子机制的一个重要问题。在这项研究中,我们对 HP36 在明水环境中的多正则复制交换模拟进行了研究,从完全伸展的构象开始。我们观察到 HP36 折叠成天然构象的至少五个事件。与晶体结构相比,骨架均方根偏差最小为 1.1Å。在天然构象中,稳定形成的疏水核心完全脱水。对模拟轨迹的统计分析表明,HP36 折叠的以下顺序事件:1),最早形成螺旋 3;2),位于螺旋 2 和 3 之间环附近的骨架和侧链采取天然构象;3),在折叠的后期,疏水核心的侧链堆积和核心侧链的脱水同时发生。该序列表明,初始折叠核不一定与疏水核心相同,与最近的实验 phi 值分析一致。

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