分子动力学作为一种研究朊病毒蛋白错误折叠及致病突变影响的方法。

Molecular dynamics as an approach to study prion protein misfolding and the effect of pathogenic mutations.

作者信息

van der Kamp Marc W, Daggett Valerie

机构信息

Department of Bioengineering, University of Washington, Seattle, WA 98195-5013, USA.

出版信息

Top Curr Chem. 2011;305:169-97. doi: 10.1007/128_2011_158.

DOI:10.1007/128_2011_158

PMID:21526434

Abstract

Computer simulation of protein dynamics offers unique high-resolution information that complements experiment. Using experimentally derived structures of the natively folded prion protein (PrP), physically realistic dynamics and conformational changes can be simulated, including the initial steps of misfolding. By introducing mutations in silico, the effect of pathogenic mutations on PrP conformation and dynamics can be assessed. Here, we briefly introduce molecular dynamics methods and review the application of molecular dynamics simulations to obtain insight into various aspects of the PrP, including the mechanism of misfolding, the response to changes in the environment, and the influence of disease-related mutations.

摘要

蛋白质动力学的计算机模拟提供了独特的高分辨率信息，可作为实验的补充。利用天然折叠的朊病毒蛋白（PrP）的实验衍生结构，可以模拟物理上逼真的动力学和构象变化，包括错误折叠的初始步骤。通过在计算机上引入突变，可以评估致病突变对PrP构象和动力学的影响。在这里，我们简要介绍分子动力学方法，并综述分子动力学模拟在深入了解PrP各个方面的应用，包括错误折叠机制、对环境变化的响应以及疾病相关突变的影响。

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分子动力学作为一种研究朊病毒蛋白错误折叠及致病突变影响的方法。

Molecular dynamics as an approach to study prion protein misfolding and the effect of pathogenic mutations.

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