The "weaken-fill-repair" model for cell budding: Linking cell wall biosynthesis with mechanics

Yu Liu; Chunxiuzi Liu; Shaohua Tang; Hui Xiao; Xinlin Wu; Yunru Peng; Xianyi Wang; Linjie Que; Zengru Di; Da Zhou; Matthias Heinemann

doi:10.1016/j.isci.2024.110981

The "weaken-fill-repair" model for cell budding: Linking cell wall biosynthesis with mechanics

Yu Liu^*
, Chunxiuzi Liu
, Shaohua Tang
, Hui Xiao
, Xinlin Wu
, Yunru Peng
, Xianyi Wang
, Linjie Que
, Zengru Di
, Da Zhou
, Matthias Heinemann

^*Corresponding author for this work

Molecular Systems Biology

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

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Abstract

The interplay between cellular mechanics and biochemical processes in the cell cycle is not well understood. We propose a quantitative model of cell budding in Saccharomyces cerevisiae as a "weaken-fill-repair" process, linking Newtonian mechanics of the cell wall with biochemical changes that affect its properties. Our model reveals that (1) oscillations in mother cell size during budding are an inevitable outcome of the process; (2) asymmetric division is necessary for the daughter cell to maintain mechanical stiffness; and (3) although various aspects of the cell are constrained and interconnected, the budding process is governed by a single reduced parameter, ψ, which balances osmolyte accumulation with enzymatic wall-weakening to ensure homeostasis. This model provides insights into the evolution of cell walls and their role in cell division, offering a system-level perspective on cell morphology.

Original language	English
Article number	110981
Number of pages	21
Journal	Iscience
Volume	27
Issue number	10
DOIs	https://doi.org/10.1016/j.isci.2024.110981
Publication status	Published - 18-Oct-2024

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abstract = "The interplay between cellular mechanics and biochemical processes in the cell cycle is not well understood. We propose a quantitative model of cell budding in Saccharomyces cerevisiae as a {"}weaken-fill-repair{"} process, linking Newtonian mechanics of the cell wall with biochemical changes that affect its properties. Our model reveals that (1) oscillations in mother cell size during budding are an inevitable outcome of the process; (2) asymmetric division is necessary for the daughter cell to maintain mechanical stiffness; and (3) although various aspects of the cell are constrained and interconnected, the budding process is governed by a single reduced parameter, ψ, which balances osmolyte accumulation with enzymatic wall-weakening to ensure homeostasis. This model provides insights into the evolution of cell walls and their role in cell division, offering a system-level perspective on cell morphology. ",

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T2 - Linking cell wall biosynthesis with mechanics

AU - Liu, Yu

AU - Liu, Chunxiuzi

AU - Tang, Shaohua

AU - Xiao, Hui

AU - Wu, Xinlin

AU - Peng, Yunru

AU - Wang, Xianyi

AU - Que, Linjie

AU - Di, Zengru

AU - Zhou, Da

AU - Heinemann, Matthias

PY - 2024/10/18

Y1 - 2024/10/18

N2 - The interplay between cellular mechanics and biochemical processes in the cell cycle is not well understood. We propose a quantitative model of cell budding in Saccharomyces cerevisiae as a "weaken-fill-repair" process, linking Newtonian mechanics of the cell wall with biochemical changes that affect its properties. Our model reveals that (1) oscillations in mother cell size during budding are an inevitable outcome of the process; (2) asymmetric division is necessary for the daughter cell to maintain mechanical stiffness; and (3) although various aspects of the cell are constrained and interconnected, the budding process is governed by a single reduced parameter, ψ, which balances osmolyte accumulation with enzymatic wall-weakening to ensure homeostasis. This model provides insights into the evolution of cell walls and their role in cell division, offering a system-level perspective on cell morphology.

AB - The interplay between cellular mechanics and biochemical processes in the cell cycle is not well understood. We propose a quantitative model of cell budding in Saccharomyces cerevisiae as a "weaken-fill-repair" process, linking Newtonian mechanics of the cell wall with biochemical changes that affect its properties. Our model reveals that (1) oscillations in mother cell size during budding are an inevitable outcome of the process; (2) asymmetric division is necessary for the daughter cell to maintain mechanical stiffness; and (3) although various aspects of the cell are constrained and interconnected, the budding process is governed by a single reduced parameter, ψ, which balances osmolyte accumulation with enzymatic wall-weakening to ensure homeostasis. This model provides insights into the evolution of cell walls and their role in cell division, offering a system-level perspective on cell morphology.

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DO - 10.1016/j.isci.2024.110981

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JO - Iscience

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The "weaken-fill-repair" model for cell budding: Linking cell wall biosynthesis with mechanics

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