Transition states in protein folding

arXiv: Biomolecules Pub Date : 2009-04-21 DOI:10.4208/cicp.2009.08.202

T. Weikl

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引用次数: 11

Abstract

The folding dynamics of small single-domain proteins is a current focus of simulations and experiments. Many of these proteins are 'two-state folders', i.e. proteins that fold rather directly from the denatured state to the native state, without populating metastable intermediate states. A central question is how to characterize the instable, partially folded conformations of two-state proteins, in particular the rate-limiting transition-state conformations between the denatured and the native state. These partially folded conformations are short-lived and cannot be observed directly in experiments. However, experimental data from detailed mutational analyses of the folding dynamics provide indirect access to transition states. The interpretation of these data, in particular the reconstruction of transition-state conformations, requires simulation and modeling. The traditional interpretation of the mutational data aims to reconstruct the degree of structure formation of individual residues in the transition state, while a novel interpretation aims at degrees of structure formation of cooperative substructures such as alpha-helices and beta-hairpins. By splitting up mutation-induced free energy changes into secondary and tertiary structural components, the novel interpretation resolves some of the inconsistencies of the traditional interpretation.

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蛋白质折叠中的过渡态

小单域蛋白的折叠动力学是当前模拟和实验的热点。这些蛋白质中的许多是“双态文件夹”，即蛋白质直接从变性状态折叠到天然状态，而不填充亚稳态中间状态。一个核心问题是如何表征不稳定的，部分折叠的两态蛋白质构象，特别是在变性和天然状态之间的限速过渡态构象。这些部分折叠的构象是短暂的，不能在实验中直接观察到。然而，来自折叠动力学的详细突变分析的实验数据提供了过渡态的间接途径。这些数据的解释，特别是过渡状态构象的重建，需要模拟和建模。传统的突变数据解释旨在重建过渡状态下单个残基的结构形成程度，而新的解释旨在重建α -螺旋和β -发夹等合作子结构的结构形成程度。通过将突变引起的自由能变化分解为二级和三级结构分量，新解释解决了传统解释的一些不一致之处。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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arXiv: Biomolecules

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