Litcius/Paper detail

Topological tuning of DNA mobility in entangled solutions of supercoiled plasmids

Jan Smrek, Jonathan Garamella, Rae M. Robertson‐Anderson, Davide Michieletto

2021Science Advances44 citationsDOIOpen Access PDF

Abstract

Ring polymers in dense solutions are among the most intriguing problems in polymer physics. Because of its natural occurrence in circular form, DNA has been extensively used as a proxy to study the fundamental physics of ring polymers in different topological states. Yet, torsionally constrained-such as supercoiled-topologies have been largely neglected so far. The applicability of existing theoretical models to dense supercoiled DNA is thus unknown. Here, we address this gap by coupling large-scale molecular dynamics simulations with differential dynamic microscopy of entangled supercoiled DNA plasmids. We find that, unexpectedly, larger supercoiling increases the size of entangled plasmids and concomitantly induces an enhancement in DNA mobility. These findings are reconciled as due to supercoiling-driven asymmetric and double-folded plasmid conformations that reduce interplasmid entanglements and threadings. Our results suggest a way to topologically tune DNA mobility via supercoiling, thus enabling topological control over the (micro)rheology of DNA-based complex fluids.

Topics & Concepts

PlasmidDNA supercoilTopology (electrical circuits)DNAPhysicsBiologyComputational biologyGeneticsDNA replicationMathematicsCombinatoricsNanopore and Nanochannel Transport StudiesBacteriophages and microbial interactionsMicrofluidic and Bio-sensing Technologies