Unzipping of knotted DNA via nanopore translocation

arXiv - QuanBio - Biomolecules Pub Date : 2024-07-16 DOI:arxiv-2407.11567

Antonio Suma, Cristian Micheletti

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Abstract

DNA unzipping by nanopore translocation has implications in diverse contexts, from polymer physics to single-molecule manipulation to DNA-enzyme interactions in biological systems. Here we use molecular dynamics simulations and a coarse-grained model of DNA to address the nanopore unzipping of DNA filaments that are knotted. This previously unaddressed problem is motivated by the fact that DNA knots inevitably occur in isolated equilibrated filaments and in vivo. We study how different types of tight knots in the DNA segment just outside the pore impact unzipping at different driving forces. We establish three main results. First, knots do not significantly affect the unzipping process at low forces. However, knotted DNAs unzip more slowly and heterogeneously than unknotted ones at high forces. Finally, we observe that the microscopic origin of the hindrance typically involves two concurrent causes: the topological friction of the DNA chain sliding along its knotted contour and the additional friction originating from the entanglement with the newly unzipped DNA. The results reveal a previously unsuspected complexity of the interplay of DNA topology and unzipping, which should be relevant for interpreting nanopore-based single-molecule unzipping experiments and improving the modeling of DNA transactions in vivo.

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通过纳米孔转运解开打结的 DNA

DNA 通过纳米孔转位解压缩的过程涉及多种领域，从聚合物物理学到单分子操纵，再到生物系统中 DNA 与酶的相互作用。在这里，我们利用分子动力学模拟和 DNA 的粗粒度模型来解决打结的 DNA 细丝的纳米孔解压缩问题。我们研究了在不同的驱动力下，孔外 DNA 片段中不同类型的紧结如何影响解压缩。我们得出了三个主要结果。首先，在低驱动力下，结对解链过程的影响不大。然而，在高驱动力下，打结的DNA比未打结的DNA解链速度更慢，且解链不均匀。最后，我们观察到，阻碍的微观起源通常涉及两个并发原因：DNA 链沿着打结轮廓滑动时的拓扑限制，以及与新解开的 DNA 发生纠缠时产生的额外限制。研究结果揭示了DNA拓扑结构与解压之间相互作用的复杂性，这对于解释基于纳米孔的单分子解压实验和改进体内DNA交易建模具有重要意义。

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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arXiv - QuanBio - Biomolecules

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