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Main Authors: Roychoudhury, Kingkini, Pande, Shreerang, Shashank, Indrakanty S., Mitra, Debarshi, Chatterji, Apratim
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2501.02276
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author Roychoudhury, Kingkini
Pande, Shreerang
Shashank, Indrakanty S.
Mitra, Debarshi
Chatterji, Apratim
author_facet Roychoudhury, Kingkini
Pande, Shreerang
Shashank, Indrakanty S.
Mitra, Debarshi
Chatterji, Apratim
contents It has been shown that under high cylindrical confinement, two ring polymers with excluded volume interactions between monomers, segregate to two halves of the cylinder to maximize their entropy. In contrast, two ring polymers remain mixed within a sphere, as there is no symmetry breaking direction [Nat Rev Microbiol, 8, 600-607 (2010)]. Therefore, in order to observe emergent organization of ring polymers in a sphere, we can introduce an asymmetric topological modification to the polymer architecture by creating a small loop and a big loop within the ring polymer. We consider the bead-spring model of polymers where there are only repulsive excluded volume interactions between the monomers ensuring that the organization we observe is purely entropy-driven. We find that for a single topologically modified polymer within a sphere, the monomers of the bigger loop are statistically more probable to be found closer to the periphery. However, the situation is reversed when we have multiple such topologically modified polymers in a sphere. The monomers of the small loops are found closer to the walls of the sphere. We can increase this localization and radial organization of polymer segments by increasing the number of small loops in each ring polymer. We study how these loops interact with each other within a polymer, as well as with loops of other polymers in spherical confinement. We compare contact maps of multiple such topologically modified polymers in a sphere. Finally, we discuss the plausible relevance of our studies to eukaryotic chromosomes that are confined within a spherical nucleus.
format Preprint
id arxiv_https___arxiv_org_abs_2501_02276
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Entropic organization of topologically modified ring polymers in spherical confinement
Roychoudhury, Kingkini
Pande, Shreerang
Shashank, Indrakanty S.
Mitra, Debarshi
Chatterji, Apratim
Soft Condensed Matter
Biological Physics
It has been shown that under high cylindrical confinement, two ring polymers with excluded volume interactions between monomers, segregate to two halves of the cylinder to maximize their entropy. In contrast, two ring polymers remain mixed within a sphere, as there is no symmetry breaking direction [Nat Rev Microbiol, 8, 600-607 (2010)]. Therefore, in order to observe emergent organization of ring polymers in a sphere, we can introduce an asymmetric topological modification to the polymer architecture by creating a small loop and a big loop within the ring polymer. We consider the bead-spring model of polymers where there are only repulsive excluded volume interactions between the monomers ensuring that the organization we observe is purely entropy-driven. We find that for a single topologically modified polymer within a sphere, the monomers of the bigger loop are statistically more probable to be found closer to the periphery. However, the situation is reversed when we have multiple such topologically modified polymers in a sphere. The monomers of the small loops are found closer to the walls of the sphere. We can increase this localization and radial organization of polymer segments by increasing the number of small loops in each ring polymer. We study how these loops interact with each other within a polymer, as well as with loops of other polymers in spherical confinement. We compare contact maps of multiple such topologically modified polymers in a sphere. Finally, we discuss the plausible relevance of our studies to eukaryotic chromosomes that are confined within a spherical nucleus.
title Entropic organization of topologically modified ring polymers in spherical confinement
topic Soft Condensed Matter
Biological Physics
url https://arxiv.org/abs/2501.02276