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Main Authors: Zheng, Chongbin, Agudo-Canalejo, Jaime, Howard, Jonathon, Tang, Evelyn
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2510.14109
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author Zheng, Chongbin
Agudo-Canalejo, Jaime
Howard, Jonathon
Tang, Evelyn
author_facet Zheng, Chongbin
Agudo-Canalejo, Jaime
Howard, Jonathon
Tang, Evelyn
contents Microtubules capture chromosomes during mitosis by stochastically switching between growth and shrinkage at catastrophe events. They display strikingly rich biochemistry and dynamics, regulated by a stabilizing cap with distinct conformational states. Microtubule lengths at catastrophe are observed to follow a peaked distribution, while their growth "stutters" briefly before catastrophe. Such complexity makes it hard to capture all these observations without a large number of tunable parameters. Here, we introduce a topological model of the microtubule cap that reproduces the features above through dynamical edge states, that provides a minimal description with just two free parameters. Our approach further provides an analytical description of catastrophes and allows the same features to persist over a wide range of tubulin concentration, consistent with experimental observations.
format Preprint
id arxiv_https___arxiv_org_abs_2510_14109
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Topological edge currents promote exploratory chromosome capture in microtubule dynamic instability
Zheng, Chongbin
Agudo-Canalejo, Jaime
Howard, Jonathon
Tang, Evelyn
Biological Physics
Soft Condensed Matter
Statistical Mechanics
Microtubules capture chromosomes during mitosis by stochastically switching between growth and shrinkage at catastrophe events. They display strikingly rich biochemistry and dynamics, regulated by a stabilizing cap with distinct conformational states. Microtubule lengths at catastrophe are observed to follow a peaked distribution, while their growth "stutters" briefly before catastrophe. Such complexity makes it hard to capture all these observations without a large number of tunable parameters. Here, we introduce a topological model of the microtubule cap that reproduces the features above through dynamical edge states, that provides a minimal description with just two free parameters. Our approach further provides an analytical description of catastrophes and allows the same features to persist over a wide range of tubulin concentration, consistent with experimental observations.
title Topological edge currents promote exploratory chromosome capture in microtubule dynamic instability
topic Biological Physics
Soft Condensed Matter
Statistical Mechanics
url https://arxiv.org/abs/2510.14109