Structural reorganization and relaxation dynamics of axially stressed chromosomes

Benjamin S. Ruben; Sumitabha Brahmachari; Vinícius G. Contessoto; Ryan R. Cheng; Antonio B. Oliveira Junior; Michele Di Pierro; José N. Onuchic

doi:10.1016/j.bpj.2023.03.029

Structural reorganization and relaxation dynamics of axially stressed chromosomes

Benjamin S. Ruben, Sumitabha Brahmachari, Vinícius G. Contessoto, Ryan R. Cheng, Antonio B. Oliveira Junior, Michele Di Pierro, José N. Onuchic

Research output: Contribution to journal › Article › peer-review

7 Scopus citations

Abstract

Chromosomes endure mechanical stresses throughout the cell cycle; for example, resulting from the pulling of chromosomes by spindle fibers during mitosis or deformation of the nucleus during cell migration. The response to physical stress is closely related to chromosome structure and function. Micromechanical studies of mitotic chromosomes have revealed them to be remarkably extensible objects and informed early models of mitotic chromosome organization. We use a data-driven, coarse-grained polymer modeling approach to explore the relationship between the spatial organization of individual chromosomes and their emergent mechanical properties. In particular, we investigate the mechanical properties of our model chromosomes by axially stretching them. Simulated stretching led to a linear force-extension curve for small strain, with mitotic chromosomes behaving about 10-fold stiffer than interphase chromosomes. Studying their relaxation dynamics, we found that chromosomes are viscoelastic solids with a highly liquid-like, viscous behavior in interphase that becomes solid-like in mitosis. This emergent mechanical stiffness originates from lengthwise compaction, an effective potential capturing the activity of loop-extruding SMC complexes. Chromosomes denature under large strains via unraveling, which is characterized by opening of large-scale folding patterns. By quantifying the effect of mechanical perturbations on the chromosome's structural features, our model provides a nuanced understanding of in vivo mechanics of chromosomes.

Original language	English
Pages (from-to)	1633-1645
Number of pages	13
Journal	Biophysical Journal
Volume	122
Issue number	9
DOIs	https://doi.org/10.1016/j.bpj.2023.03.029
State	Published - May 2 2023

Bibliographical note

Publisher Copyright:
© 2023 Biophysical Society

Funding

This work was supported by the Center for Theoretical Biological Physics sponsored by the National Science Foundation (NSF) (grants PHY-2019745 and PHY-2210291) and by the Welch Foundation (grant C-1792). J.N.O. is a Cancer Prevention and Research Institute of Texas (CPRIT) Scholar in Cancer Research. A.B.O.J. acknowledges the Robert A. Welch Postdoctoral Fellow program. BSR was supported in part by the Rice University Department of Physics and Astronomy's Summer Undergraduate Research Fellowship, as well as the Rice University Center for Theoretical Biological Physics’ Opportunities for Research in Biophysics, Informatics, and Theoretical Science (ORBITS) summer program. B.S.R. was also supported by the National Institutes of Health Molecular Biophysics Training Grant NIH/NIGMS T32 GM008313. M.D.P. is supported by the NIGMS of the National Institutes of Health under award number R35GM146852. The content is solely the responsibility of the authors and does not necessarily represent the official views of the National Institutes of Health. B.S.R. thanks David Greenblott for thoughtful discussion. The authors declare no competing interests. This work was supported by the Center for Theoretical Biological Physics sponsored by the National Science Foundation (NSF) (grants PHY-2019745 and PHY-2210291 ) and by the Welch Foundation (grant C-1792 ). J.N.O. is a Cancer Prevention and Research Institute of Texas (CPRIT) Scholar in Cancer Research. A.B.O.J. acknowledges the Robert A. Welch Postdoctoral Fellow program. BSR was supported in part by the Rice University Department of Physics and Astronomy’s Summer Undergraduate Research Fellowship, as well as the Rice University Center for Theoretical Biological Physics’ Opportunities for Research in Biophysics, Informatics, and Theoretical Science (ORBITS) summer program. B.S.R. was also supported by the National Institutes of Health Molecular Biophysics Training Grant NIH/ NIGMS T32 GM008313 . M.D.P. is supported by the NIGMS of the National Institutes of Health under award number R35GM146852 . The content is solely the responsibility of the authors and does not necessarily represent the official views of the National Institutes of Health. B.S.R. thanks David Greenblott for thoughtful discussion.

Funders	Funder number
Cancer Prevention and Research Institute of Texas
National Institutes of Health (NIH)
Rice University
National Institute of General Medical Sciences DP2GM119177 Sophie Dumont National Institute of General Medical Sciences	R35GM146852, T32 GM008313
Welch Foundation	C-1792
National Science Foundation Arctic Social Science Program	PHY-2019745, PHY-2210291, 2019745

ASJC Scopus subject areas

Biophysics

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10.1016/j.bpj.2023.03.029

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@article{a23288746a33484db233f110d31709d1,

title = "Structural reorganization and relaxation dynamics of axially stressed chromosomes",

abstract = "Chromosomes endure mechanical stresses throughout the cell cycle; for example, resulting from the pulling of chromosomes by spindle fibers during mitosis or deformation of the nucleus during cell migration. The response to physical stress is closely related to chromosome structure and function. Micromechanical studies of mitotic chromosomes have revealed them to be remarkably extensible objects and informed early models of mitotic chromosome organization. We use a data-driven, coarse-grained polymer modeling approach to explore the relationship between the spatial organization of individual chromosomes and their emergent mechanical properties. In particular, we investigate the mechanical properties of our model chromosomes by axially stretching them. Simulated stretching led to a linear force-extension curve for small strain, with mitotic chromosomes behaving about 10-fold stiffer than interphase chromosomes. Studying their relaxation dynamics, we found that chromosomes are viscoelastic solids with a highly liquid-like, viscous behavior in interphase that becomes solid-like in mitosis. This emergent mechanical stiffness originates from lengthwise compaction, an effective potential capturing the activity of loop-extruding SMC complexes. Chromosomes denature under large strains via unraveling, which is characterized by opening of large-scale folding patterns. By quantifying the effect of mechanical perturbations on the chromosome's structural features, our model provides a nuanced understanding of in vivo mechanics of chromosomes.",

author = "Ruben, \{Benjamin S.\} and Sumitabha Brahmachari and Contessoto, \{Vin{\'i}cius G.\} and Cheng, \{Ryan R.\} and \{Oliveira Junior\}, \{Antonio B.\} and \{Di Pierro\}, Michele and Onuchic, \{Jos{\'e} N.\}",

note = "Publisher Copyright: {\textcopyright} 2023 Biophysical Society",

year = "2023",

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doi = "10.1016/j.bpj.2023.03.029",

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AU - Ruben, Benjamin S.

AU - Brahmachari, Sumitabha

AU - Contessoto, Vinícius G.

AU - Cheng, Ryan R.

AU - Oliveira Junior, Antonio B.

AU - Di Pierro, Michele

AU - Onuchic, José N.

PY - 2023/5/2

Y1 - 2023/5/2

N2 - Chromosomes endure mechanical stresses throughout the cell cycle; for example, resulting from the pulling of chromosomes by spindle fibers during mitosis or deformation of the nucleus during cell migration. The response to physical stress is closely related to chromosome structure and function. Micromechanical studies of mitotic chromosomes have revealed them to be remarkably extensible objects and informed early models of mitotic chromosome organization. We use a data-driven, coarse-grained polymer modeling approach to explore the relationship between the spatial organization of individual chromosomes and their emergent mechanical properties. In particular, we investigate the mechanical properties of our model chromosomes by axially stretching them. Simulated stretching led to a linear force-extension curve for small strain, with mitotic chromosomes behaving about 10-fold stiffer than interphase chromosomes. Studying their relaxation dynamics, we found that chromosomes are viscoelastic solids with a highly liquid-like, viscous behavior in interphase that becomes solid-like in mitosis. This emergent mechanical stiffness originates from lengthwise compaction, an effective potential capturing the activity of loop-extruding SMC complexes. Chromosomes denature under large strains via unraveling, which is characterized by opening of large-scale folding patterns. By quantifying the effect of mechanical perturbations on the chromosome's structural features, our model provides a nuanced understanding of in vivo mechanics of chromosomes.

AB - Chromosomes endure mechanical stresses throughout the cell cycle; for example, resulting from the pulling of chromosomes by spindle fibers during mitosis or deformation of the nucleus during cell migration. The response to physical stress is closely related to chromosome structure and function. Micromechanical studies of mitotic chromosomes have revealed them to be remarkably extensible objects and informed early models of mitotic chromosome organization. We use a data-driven, coarse-grained polymer modeling approach to explore the relationship between the spatial organization of individual chromosomes and their emergent mechanical properties. In particular, we investigate the mechanical properties of our model chromosomes by axially stretching them. Simulated stretching led to a linear force-extension curve for small strain, with mitotic chromosomes behaving about 10-fold stiffer than interphase chromosomes. Studying their relaxation dynamics, we found that chromosomes are viscoelastic solids with a highly liquid-like, viscous behavior in interphase that becomes solid-like in mitosis. This emergent mechanical stiffness originates from lengthwise compaction, an effective potential capturing the activity of loop-extruding SMC complexes. Chromosomes denature under large strains via unraveling, which is characterized by opening of large-scale folding patterns. By quantifying the effect of mechanical perturbations on the chromosome's structural features, our model provides a nuanced understanding of in vivo mechanics of chromosomes.

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Structural reorganization and relaxation dynamics of axially stressed chromosomes

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