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The interplay between asymmetric and symmetric DNA loop extrusion

Edward J. Banigan, Leonid A. Mirny

2020eLife28 citationsDOIOpen Access PDF

Abstract

Chromosome compaction is essential for reliable transmission of genetic information. Experiments suggest that ∼1000-fold compaction is driven by condensin complexes that extrude chromatin loops, by progressively collecting chromatin fiber from one or both sides of the complex to form a growing loop. Theory indicates that symmetric two-sided loop extrusion can achieve such compaction, but recent single-molecule studies (Golfier et al., 2020) observed diverse dynamics of condensins that perform one-sided, symmetric two-sided, and asymmetric two-sided extrusion. We use simulations and theory to determine how these molecular properties lead to chromosome compaction. High compaction can be achieved if even a small fraction of condensins have two essential properties: a long residence time and the ability to perform two-sided (not necessarily symmetric) extrusion. In mixtures of condensins I and II, coupling two-sided extrusion and stable chromatin binding by condensin II promotes compaction. These results provide missing connections between single-molecule observations and chromosome-scale organization.

Topics & Concepts

CondensinExtrusionCompactionChromatinChromosomeBiophysicsChemical physicsBiologyDNACell biologyChemistryPhysicsMaterials scienceGeneticsComposite materialCohesinGeneGenomics and Chromatin DynamicsDNA and Nucleic Acid ChemistryRNA and protein synthesis mechanisms
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