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机械展开小型、拓扑结构简单的蛋白质L。

Mechanically unfolding the small, topologically simple protein L.

作者信息

Brockwell David J, Beddard Godfrey S, Paci Emanuele, West Dan K, Olmsted Peter D, Smith D Alastair, Radford Sheena E

机构信息

School of Biochemistry and Microbiology, Institute of Molecular Biophysics, Centre for Chemical Dynamics, University of Leeds, Leeds, United Kingdom.

出版信息

Biophys J. 2005 Jul;89(1):506-19. doi: 10.1529/biophysj.105.061465. Epub 2005 Apr 29.

DOI:10.1529/biophysj.105.061465
PMID:15863479
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1366550/
Abstract

beta-sheet proteins are generally more able to resist mechanical deformation than alpha-helical proteins. Experiments measuring the mechanical resistance of beta-sheet proteins extended by their termini led to the hypothesis that parallel, directly hydrogen-bonded terminal beta-strands provide the greatest mechanical strength. Here we test this hypothesis by measuring the mechanical properties of protein L, a domain with a topology predicted to be mechanically strong, but with no known mechanical function. A pentamer of this small, topologically simple protein is resistant to mechanical deformation over a wide range of extension rates. Molecular dynamics simulations show the energy landscape for protein L is highly restricted for mechanical unfolding and that this protein unfolds by the shearing apart of two structural units in a mechanism similar to that proposed for ubiquitin, which belongs to the same structural class as protein L, but unfolds at a significantly higher force. These data suggest that the mechanism of mechanical unfolding is conserved in proteins within the same fold family and demonstrate that although the topology and presence of a hydrogen-bonded clamp are of central importance in determining mechanical strength, hydrophobic interactions also play an important role in modulating the mechanical resistance of these similar proteins.

摘要

β-折叠蛋白质通常比α-螺旋蛋白质更能抵抗机械变形。通过测量由其末端延伸的β-折叠蛋白质的机械抗性进行的实验得出了这样的假设:平行的、直接氢键连接的末端β-链提供了最大的机械强度。在这里,我们通过测量蛋白质L的机械性能来检验这一假设,蛋白质L是一个拓扑结构预计具有较强机械强度但尚无已知机械功能的结构域。这种小的、拓扑结构简单的蛋白质的五聚体在很宽的延伸速率范围内都能抵抗机械变形。分子动力学模拟表明,蛋白质L的能量景观对于机械展开高度受限,并且这种蛋白质通过类似于泛素所提出的机制,即两个结构单元的剪切分离而展开,泛素与蛋白质L属于同一结构类别,但在显著更高的力作用下展开。这些数据表明,机械展开机制在同一折叠家族的蛋白质中是保守的,并证明尽管拓扑结构和氢键连接的夹子的存在对于确定机械强度至关重要,但疏水相互作用在调节这些相似蛋白质的机械抗性方面也起着重要作用。

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