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Crumpled Polymer with Loops Recapitulates Key Features of Chromosome Organization

Kirill Polovnikov, Hugo B. Brandão, Sergey Belan, B. Slavov, Maxim Imakaev, Leonid A. Mirny

2023Physical Review X65 citationsDOIOpen Access PDF

Abstract

Chromosomes are exceedingly long topologically-constrained polymers compacted in a cell nucleus. We recently suggested that chromosomes are organized into loops by an active process of loop extrusion. Yet loops remain elusive to direct observations in living cells; detection and characterization of myriads of such loops is a major challenge. The lack of a tractable physical model of a polymer folded into loops limits our ability to interpret experimental data and detect loops. Here, we introduce a new physical model - a polymer folded into a sequence of loops, and solve it analytically. Our model and a simple geometrical argument show how loops affect statistics of contacts in a polymer across different scales, explaining universally observed shapes of the contact probability. Moreover, we reveal that folding into loops reduces the density of topological entanglements, a novel phenomenon we refer as "the dilution of entanglements". Supported by simulations this finding suggests that up to ~ 1 - 2Mb chromosomes with loops are not topologically constrained, yet become crumpled at larger scales. Our theoretical framework allows inference of loop characteristics, draws a new picture of chromosome organization, and shows how folding into loops affects topological properties of crumpled polymers.

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Key (lock)Computer scienceNanotechnologyMaterials scienceComputer securityAdvanced Materials and MechanicsStructural Analysis and OptimizationArchitecture and Computational Design
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