Cohesin supercoils DNA during loop extrusion

Iain F. Davidson; Roman Barth; Kota Nagasaka; Wen Tang; Gordana Wutz; Sabrina Horn; Richard Janissen; Cees Dekker; Jan Michael Peters

doi:10.1016/j.celrep.2025.115856

Cohesin supercoils DNA during loop extrusion

Iain F. Davidson, Roman Barth, Kota Nagasaka, Wen Tang, Gordana Wutz, Sabrina Horn, Richard Janissen, Cees Dekker, Jan Michael Peters^*

^*Corresponding author for this work

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Abstract

Cohesin extrudes genomic DNA into loops that promote chromatin assembly, gene regulation, and gene recombination. Loop extrusion depends on large-scale conformational changes in cohesin, but how these translocate DNA is poorly understood. Here, we provide evidence that cohesin negatively supercoils DNA during loop extrusion. Supercoiling requires the engagement of cohesin’s ATPase heads, DNA clamping by these heads, and a DNA-binding site on cohesin’s hinge, indicating that cohesin twists DNA when constraining it between the hinge and the clamp. A cohesin mutant defective in negative supercoiling forms shorter loops in cells, and a similar, although weaker, phenotype is observed after the depletion of topoisomerase I. These results suggest that supercoiling is an integral part of the loop-extrusion mechanism and that relaxation of supercoiled DNA is required for cohesin-mediated loop extrusion and genome architecture.

Original language	English
Article number	115856
Number of pages	27
Journal	Cell Reports
Volume	44
Issue number	6
DOIs	https://doi.org/10.1016/j.celrep.2025.115856
Publication status	Published - 2025

Keywords

cohesin
loop extrusion
SMC complexes
supercoiling
topoisomerases

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10.1016/j.celrep.2025.115856

PIIS2211124725006278Final published version, 18.6 MBLicence: CC BY

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title = "Cohesin supercoils DNA during loop extrusion",

abstract = "Cohesin extrudes genomic DNA into loops that promote chromatin assembly, gene regulation, and gene recombination. Loop extrusion depends on large-scale conformational changes in cohesin, but how these translocate DNA is poorly understood. Here, we provide evidence that cohesin negatively supercoils DNA during loop extrusion. Supercoiling requires the engagement of cohesin{\textquoteright}s ATPase heads, DNA clamping by these heads, and a DNA-binding site on cohesin{\textquoteright}s hinge, indicating that cohesin twists DNA when constraining it between the hinge and the clamp. A cohesin mutant defective in negative supercoiling forms shorter loops in cells, and a similar, although weaker, phenotype is observed after the depletion of topoisomerase I. These results suggest that supercoiling is an integral part of the loop-extrusion mechanism and that relaxation of supercoiled DNA is required for cohesin-mediated loop extrusion and genome architecture.",

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T1 - Cohesin supercoils DNA during loop extrusion

AU - Davidson, Iain F.

AU - Barth, Roman

AU - Nagasaka, Kota

AU - Tang, Wen

AU - Wutz, Gordana

AU - Horn, Sabrina

AU - Janissen, Richard

AU - Dekker, Cees

AU - Peters, Jan Michael

PY - 2025

Y1 - 2025

N2 - Cohesin extrudes genomic DNA into loops that promote chromatin assembly, gene regulation, and gene recombination. Loop extrusion depends on large-scale conformational changes in cohesin, but how these translocate DNA is poorly understood. Here, we provide evidence that cohesin negatively supercoils DNA during loop extrusion. Supercoiling requires the engagement of cohesin’s ATPase heads, DNA clamping by these heads, and a DNA-binding site on cohesin’s hinge, indicating that cohesin twists DNA when constraining it between the hinge and the clamp. A cohesin mutant defective in negative supercoiling forms shorter loops in cells, and a similar, although weaker, phenotype is observed after the depletion of topoisomerase I. These results suggest that supercoiling is an integral part of the loop-extrusion mechanism and that relaxation of supercoiled DNA is required for cohesin-mediated loop extrusion and genome architecture.

AB - Cohesin extrudes genomic DNA into loops that promote chromatin assembly, gene regulation, and gene recombination. Loop extrusion depends on large-scale conformational changes in cohesin, but how these translocate DNA is poorly understood. Here, we provide evidence that cohesin negatively supercoils DNA during loop extrusion. Supercoiling requires the engagement of cohesin’s ATPase heads, DNA clamping by these heads, and a DNA-binding site on cohesin’s hinge, indicating that cohesin twists DNA when constraining it between the hinge and the clamp. A cohesin mutant defective in negative supercoiling forms shorter loops in cells, and a similar, although weaker, phenotype is observed after the depletion of topoisomerase I. These results suggest that supercoiling is an integral part of the loop-extrusion mechanism and that relaxation of supercoiled DNA is required for cohesin-mediated loop extrusion and genome architecture.

KW - cohesin

KW - loop extrusion

KW - SMC complexes

KW - supercoiling

KW - topoisomerases

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Cohesin supercoils DNA during loop extrusion

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Keywords

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