在适配良好的纳米孔中蛋白质的运动和构象：亲和素在 ClyA 中。

Protein Motion and Configurations in a Form-Fitting Nanopore: Avidin in ClyA.

机构信息

Department of Physics, Harvard University, Cambridge, Massachusetts.

The Rowland Institute at Harvard, Harvard University, Cambridge, Massachusetts.

出版信息

Biophys J. 2018 Sep 4;115(5):801-808. doi: 10.1016/j.bpj.2018.07.024. Epub 2018 Aug 4.

DOI:10.1016/j.bpj.2018.07.024

PMID:30122294

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6127461/

Abstract

We probe the molecular dynamics and states of an avidin protein as it is captured and trapped in a voltage-biased cytolysin A nanopore using time-resolved single-molecule electrical conductance signals. The data for very large numbers of single-molecule events are analyzed and presented by a new method that provides clear visual insight into the molecular scale processes. Avidin in cytolysin A has surprisingly rich conductance spectra that reveal transient and more permanently trapped protein configurations in the pore and how they evolve into one another. We identify a long-lasting, stable, and low-noise configuration of avidin in the nanopore into which avidin can be reliably trapped and released. This may prove useful for single-molecule studies of other proteins that can be biotinylated and then transported by avidin to the pore via their coupling to avidin with biotin-avidin linking. We demonstrate the sensitivity of this system with detection of biotin attached to avidin captured by the pore.

摘要

我们使用时间分辨单分子电导信号探测了当卵清溶菌酶 A 纳米孔捕获并困住亲和素蛋白时的分子动力学和状态。通过一种新的方法分析和呈现了大量单分子事件的数据，该方法提供了对分子尺度过程的清晰直观的了解。卵清溶菌酶 A 中的亲和素具有惊人丰富的电导谱，揭示了孔内瞬态和更持久捕获的蛋白质构象，以及它们如何相互演变。我们确定了亲和素在纳米孔中一种持久、稳定且低噪声的构象，亲和素可以可靠地被捕获和释放。这对于其他可以通过生物素化并通过生物素-亲和素连接与亲和素偶联运输到孔中的蛋白质的单分子研究可能证明是有用的。我们通过检测孔内捕获的生物素化亲和素来证明该系统的灵敏度。

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