Single-Molecule Characterization of a Nanopore-Coupled Cas9 Protein on an Electrode Array

2018 IEEE SENSORS Pub Date : 2018-10-01 DOI:10.1109/ICSENS.2018.8630288

M. Palla, David B. Thompson, G. Church

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Abstract

Nanopore sequencing technology is an emerging method for achieving long sequence reads on single DNA molecules without prior sample amplification. Detection involves changes in current across a membrane through a self-assembling protein nanopore complex. Each pore is associated with a single electrode within a complementary metal-oxide semiconductor (CMOS) array, enabling detection of single-molecule events. Extending these capabilities, we describe here a nanopore-based method to detect specific DNA molecules through binding to a Cas9:gRNA complex. Specifically, we generated a recombinant protein tool for the assembly of a functional Cas9 or dCas9 molecules on a nanopore array. To date, we have demonstrated that the construct is functional, recruits appropriately designed gRNA molecules, and binds to target DNA molecules while failing to bind non-target DNA. We believe that our Cas9-functionalized nanopore method may have utility in both basic research and clinical diagnostic applications by enabling single-molecule kinetic characterization of the enzyme, potentially offering novel insights into the mechanism of Cas9 catalytic cycle.

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纳米孔偶联Cas9蛋白在电极阵列上的单分子表征

纳米孔测序技术是一种新兴的方法，可以在没有事先样品扩增的情况下实现对单个DNA分子的长序列读取。检测涉及通过自组装蛋白质纳米孔复合物穿过膜的电流变化。每个孔都与互补金属氧化物半导体(CMOS)阵列中的单个电极相关联，从而能够检测单分子事件。为了扩展这些功能，我们在这里描述了一种基于纳米孔的方法，通过结合Cas9:gRNA复合物来检测特定的DNA分子。具体来说，我们生成了一个重组蛋白工具，用于在纳米孔阵列上组装功能性Cas9或dCas9分子。迄今为止，我们已经证明该结构是功能性的，招募了适当设计的gRNA分子，并与靶DNA分子结合，而不能与非靶DNA结合。我们相信我们的Cas9功能化纳米孔方法可以通过实现酶的单分子动力学表征，在基础研究和临床诊断应用中都有实用价值，可能为Cas9催化循环的机制提供新的见解。

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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2018 IEEE SENSORS

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