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Main Authors: Thirumalai, D., Shi, Guang, Shin, Sucheol, Hyeon, Changbong
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2410.01219
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author Thirumalai, D.
Shi, Guang
Shin, Sucheol
Hyeon, Changbong
author_facet Thirumalai, D.
Shi, Guang
Shin, Sucheol
Hyeon, Changbong
contents How long threadlike eukaryotic chromosomes fit tidily in the small volume of the nucleus without significant entanglement is just beginning to be understood, thanks to major advances in experimental techniques. Several polymer models, which reproduce contact maps that measure the probabilities that two loci are in spatial contact, have predicted the three-dimensional structures of interphase chromosomes. Data-driven approaches, using contact maps as input, predict that mitotic helical chromosomes are characterized by switch in handedness, referred to as "perversion". By using experimentally derived effective interactions between chromatin loci in simulations, structures of conventional and inverted nuclei have been accurately predicted. Polymer theory and simulations show that the dynamics of individual loci in chromatin exhibit subdiffusive behavior but the diffusion exponents are broadly distributed, which accords well with experiments. Although coarse-grained models are successful, many challenging problems remain, which require the creation of new experimental and computational tools to understand genome biology.
format Preprint
id arxiv_https___arxiv_org_abs_2410_01219
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Organization and Dynamics of Chromosomes
Thirumalai, D.
Shi, Guang
Shin, Sucheol
Hyeon, Changbong
Soft Condensed Matter
Biological Physics
Chemical Physics
Genomics
How long threadlike eukaryotic chromosomes fit tidily in the small volume of the nucleus without significant entanglement is just beginning to be understood, thanks to major advances in experimental techniques. Several polymer models, which reproduce contact maps that measure the probabilities that two loci are in spatial contact, have predicted the three-dimensional structures of interphase chromosomes. Data-driven approaches, using contact maps as input, predict that mitotic helical chromosomes are characterized by switch in handedness, referred to as "perversion". By using experimentally derived effective interactions between chromatin loci in simulations, structures of conventional and inverted nuclei have been accurately predicted. Polymer theory and simulations show that the dynamics of individual loci in chromatin exhibit subdiffusive behavior but the diffusion exponents are broadly distributed, which accords well with experiments. Although coarse-grained models are successful, many challenging problems remain, which require the creation of new experimental and computational tools to understand genome biology.
title Organization and Dynamics of Chromosomes
topic Soft Condensed Matter
Biological Physics
Chemical Physics
Genomics
url https://arxiv.org/abs/2410.01219