Increasingly efficient chromatin binding of cohesin and CTCF supports chromatin architecture formation during zebrafish embryogenesis

Coßmann, Jonas; Kos, Pavel I.; Varamogianni-Mamatsi, Vassiliki; Assenheimer, Devin; Bischof, Tobias; Kuhn, Timo; Vomhof, Thomas; Papantonis, Argyris; Giorgetti, Luca; Gebhardt, J. Christof M.

doi:10.1101/2023.12.08.570809

2023

DOI: 10.1101/2023.12.08.570809

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Increasingly efficient chromatin binding of cohesin and CTCF supports chromatin architecture formation during zebrafish embryogenesis

Jonas Coßmann,

Pavel I. Kos,

Vassiliki Varamogianni-Mamatsi

et al.

Abstract: The three-dimensional folding of chromosomes is essential for nuclear functions such as DNA replication and gene regulation. The emergence of chromatin architecture is thus an important process during embryogenesis. To shed light on the molecular and kinetic underpinnings of chromatin architecture formation, we characterized biophysical properties of cohesin and CTCF binding to chromatin and their changes upon cofactor depletion using single-molecule imaging in live developing zebrafish embryos. We found that … Show more

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2024

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The physical chemistry of interphase loop extrusion

Tortora,

Fudenberg

2024

Preprint

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Loop extrusion constitutes a universal mechanism of genome organization, whereby structural maintenance of chromosomes (SMC) protein complexes load onto the chromatin fiber and generate DNA loops of increasingly-larger sizes until their eventual release. In mammalian interphase cells, loop extrusion is mediated by the cohesin complex, which is dynamically regulated by the interchange of multiple accessory proteins. Although these regulators bind the core cohesin complex only transiently, their disruption can dramatically alter cohesin dynamics, gene expression, chromosome morphology and contact patterns. Still, a theory of how cohesin regulators and their molecular interplay with the core complex modulate genome folding remains at large. Here we derive a model of cohesin loop extrusion from first principles, based onin vivomeasurements of the abundance and dynamics of cohesin regulators. We systematically evaluate potential chemical reaction networks that describe the association of cohesin with its regulators and with the chromatin fiber. Remarkably, experimental observations are consistent with only a single biochemical reaction cycle, which results in a unique minimal model that may be fully parameterized by quantitative protein measurements. We demonstrate how distinct roles for cohesin regulators emerge simply from the structure of the reaction network, and how their dynamic exchange can regulate loop extrusion kinetics over time-scales that far exceed their own chromatin residence times. By embedding our cohesin biochemical reaction network within biophysical chromatin simulations, we evidence how variations in regulatory protein abundance can alter chromatin architecture across multiple length- and time-scales. Predictions from our model are corroborated by biophysical and biochemical assays, optical microscopy observations, and Hi-C conformation capture techniques. More broadly, our theoretical and numerical framework bridges the gap betweenin vitroobservations of extrusion motor dynamics at the molecular scale and their structural consequences at the genome-wide level.

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The physical chemistry of interphase loop extrusion

Tortora,

Fudenberg

2024

Preprint

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show abstract

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Increasingly efficient chromatin binding of cohesin and CTCF supports chromatin architecture formation during zebrafish embryogenesis

Cited by 1 publication

References 134 publications

The physical chemistry of interphase loop extrusion

The physical chemistry of interphase loop extrusion

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