Topology-dependent DNA binding

Kolbeck, Pauline J.; Tišma, Miloš; Analikwu, Brian T.; Vanderlinden, Willem; Dekker, Cees; Lipfert, Jan

doi:10.1101/2023.06.30.547266

2023

DOI: 10.1101/2023.06.30.547266

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Topology-dependent DNA binding

Pauline J. Kolbeck,

Miloš Tišma,

Brian T. Analikwu

et al.

Abstract: DNA stores our genetic information and is ubiquitous in biological and biotechnological applications, where it interacts with binding partners ranging from small molecules to large macromolecular complexes. Binding is modulated by mechanical strains in the molecule and, in turn, can change the local DNA structure. Frequently, DNA occurs in closed topological forms where topology and supercoiling add a global constraint to the interplay of binding-induced deformations and strain-modulated binding. Here, we pres… Show more

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Single-molecule visualization of twin-supercoiled domains generated during transcription

Janissen,

Barth,

Polinder

et al. 2023

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Transcription-coupled supercoiling of DNA is a key factor in chromosome compaction and the regulation of genetic processes in all domains of life. It has become common knowledge that, during transcription, the DNA-dependent RNA polymerase (RNAP) induces positive supercoiling ahead of it (downstream) and negative supercoils in its wake (upstream), as rotation of RNAP around the DNA axis upon tracking its helical groove gets constrained due to drag on its RNA transcript. Here, we experimentally validate this so-called twin-supercoiled-domain model within vitroreal-time visualization at the single-molecule scale. Upon binding to the promoter site on a supercoiled DNA molecule, RNAP merges all DNA supercoils into one large pinned plectoneme with RNAP residing at its apex. Transcription by RNAP in real time demonstrates that up- and downstream supercoils are generated simultaneously and in equal portions, in agreement with the twin-supercoiled-domain model. Experiments carried out in the presence of RNases A and H, revealed that an additional viscous drag of the RNA transcript is not necessary for the RNAP to induce supercoils. The latter results contrast the current consensus and simulations on the origin of the twin-supercoiled domains, pointing at an additional mechanistic cause underlying supercoil generation by RNAP in transcription.

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Single-molecule visualization of twin-supercoiled domains generated during transcription

Janissen,

Barth,

Polinder

et al. 2023

Preprint

Self Cite

View full text Add to dashboard Cite

show abstract

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Topology-dependent DNA binding

Cited by 1 publication

References 89 publications

Single-molecule visualization of twin-supercoiled domains generated during transcription

Single-molecule visualization of twin-supercoiled domains generated during transcription

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