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聚合物通过可调节聚合物-孔静电相互作用的α-溶血素孔的易位。

Polymer translocation through alpha-hemolysin pore with tunable polymer-pore electrostatic interaction.

机构信息

Department of Polymer Science and Engineering, University of Massachusetts, Amherst, Massachusetts 01003, USA.

出版信息

J Chem Phys. 2010 Jul 28;133(4):045101. doi: 10.1063/1.3464333.

DOI:10.1063/1.3464333
PMID:20687689
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2921442/
Abstract

We have measured the ionic current blockages produced by single molecules of sodium poly(styrene sulfonate) passing through an alpha-hemolysin protein pore under an electric field. Most of the blockage events were composed of one or two blockage levels of ionic current. By analyzing the statistics of different event types for different polymer lengths, applied voltages, and pH conditions, we have identified the molecular mechanism behind the two-level blockages. Our analysis of the data shows that not all blockages are successful translocation events and the propensity of successful translocation can be tuned by pH gradients across the protein pore. We interpret our results as the change in protein-polymer interaction via protonation of charged amino acid residues of alpha-hemolysin pore. In addition, we have constructed a stochastic theory for polymer translocation through alpha-hemolysin pore with tunable polymer-pore interactions. The theoretical calculations capture many features observed in our experiments.

摘要

我们已经测量了在电场作用下,单个聚苯乙烯磺酸钠分子通过α-溶血素蛋白孔时产生的离子电流阻塞。大多数阻塞事件由一个或两个阻塞水平的离子电流组成。通过分析不同聚合物长度、施加电压和 pH 值条件下不同事件类型的统计数据,我们确定了双水平阻塞背后的分子机制。我们对数据的分析表明,并非所有阻塞都是成功的易位事件,并且成功易位的倾向可以通过蛋白孔跨 pH 梯度进行调节。我们将结果解释为通过α-溶血素孔带电氨基酸残基的质子化来改变蛋白-聚合物相互作用。此外,我们构建了一个具有可调聚合物-孔相互作用的聚合物通过α-溶血素孔的随机理论。理论计算捕捉到了我们实验中观察到的许多特征。

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