Protein folding mechanism revealed by single-molecule force spectroscopy experiments.

Hao Sun, Zilong Guo, Haiyan Hong, Ping Yu, Zhenyong Xue, Hu Chen
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引用次数: 2

Abstract

Force spectroscopy experiments use mechanical force as a control factor to regulate the folding and unfolding process of proteins. Atomic force microscopy has been widely used to study the mechanical stability of proteins, and obtained unfolding forces and unfolding distance of different proteins, while recently, more low force folding and unfolding measurements were done by optical tweezers and magnetic tweezers. Due to the relatively small distortion of the free energy landscape, low force measurements give the free energy landscape information over bigger conformational space. In this review, we summarize the results of force spectroscopy experiments on different proteins. The unfolding distance obtained at high forces by atomic force microscopy are mostly smaller than 2 nm, while the unfolding distances at low forces distribute over a larger range: from a negative value to more than 6 nm. The sizes of the transition states at low force are ~4 nm for most compact two-state globular proteins, which indicates that this transition state might be the general free energy barrier separating the unfolded state and the theoretically predicated molten globule state. Up to now, only a limited number of proteins has been studied at low forces. We expect that more and more proteins with different conformations will be studied at low forces to reveal the general protein folding mechanism.

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单分子力谱实验揭示蛋白质折叠机制。
力谱实验利用机械力作为控制因子来调节蛋白质的折叠和展开过程。原子力显微镜被广泛用于研究蛋白质的机械稳定性,获得了不同蛋白质的展开力和展开距离,而近年来,更多的是通过光学镊子和磁镊子进行低力折叠和展开测量。由于自由能格局的畸变相对较小,低力测量给出了更大构象空间上的自由能格局信息。本文综述了不同蛋白质的力谱实验结果。原子力显微镜在强力下得到的展开距离大多小于2 nm,而在低力下得到的展开距离分布在更大的范围内:从负值到大于6 nm。大多数致密的两态球状蛋白在低力作用下的过渡态大小约为4 nm,这表明该过渡态可能是分离未折叠态和理论预测的熔融态的一般自由能垒。到目前为止,只有有限数量的蛋白质在低力下进行了研究。我们期望在低力下研究更多不同构象的蛋白质,以揭示蛋白质的一般折叠机制。
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CiteScore
1.30
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117
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