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Main Authors: Zablotsky, Amir, Biswas, Subham, Schaedel, Laura, John, Karin
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2511.06879
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author Zablotsky, Amir
Biswas, Subham
Schaedel, Laura
John, Karin
author_facet Zablotsky, Amir
Biswas, Subham
Schaedel, Laura
John, Karin
contents The structural integrity of microtubules is paramount for cellular function. We present a theoretical analysis of their lattice fracture, focusing on the influence of multi-seam structures arising from monomer defects and aiming to provide a more accurate estimation of GDP lattice parameters. Our findings reveal that seams function as pre-existing pathways that accelerate damage propagation. Consequently, monomer vacancies destabilize the lattice due to the inherent structural loss of tubulin-tubulin contacts and the additive acceleration of fracture through multiple seams. Importantly, the comparison of our simulations with experiments on lattice fracture suggests that the intrinsic ratio of longitudinal to lateral binding energies is bounded at approximately 1.5, challenging previous predictions of lattice anisotropy from tip-growth models and highlighting the urgent need to incorporate into current growth models parameters obtained from lattice dynamics.
format Preprint
id arxiv_https___arxiv_org_abs_2511_06879
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Beyond the Tip: Lattice Dynamics, Seams, and the Mechanism of Microtubule Fracture
Zablotsky, Amir
Biswas, Subham
Schaedel, Laura
John, Karin
Biological Physics
Materials Science
The structural integrity of microtubules is paramount for cellular function. We present a theoretical analysis of their lattice fracture, focusing on the influence of multi-seam structures arising from monomer defects and aiming to provide a more accurate estimation of GDP lattice parameters. Our findings reveal that seams function as pre-existing pathways that accelerate damage propagation. Consequently, monomer vacancies destabilize the lattice due to the inherent structural loss of tubulin-tubulin contacts and the additive acceleration of fracture through multiple seams. Importantly, the comparison of our simulations with experiments on lattice fracture suggests that the intrinsic ratio of longitudinal to lateral binding energies is bounded at approximately 1.5, challenging previous predictions of lattice anisotropy from tip-growth models and highlighting the urgent need to incorporate into current growth models parameters obtained from lattice dynamics.
title Beyond the Tip: Lattice Dynamics, Seams, and the Mechanism of Microtubule Fracture
topic Biological Physics
Materials Science
url https://arxiv.org/abs/2511.06879