A minimal spatial cell lineage model of epithelium: Tissue stratification and multi-stability

Wei Ting Yeh; Hsuan Yi Chen

doi:10.1088/1367-2630/aac2ad

A minimal spatial cell lineage model of epithelium: Tissue stratification and multi-stability

Wei Ting Yeh, Hsuan Yi Chen

Department of Physics

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

2 Scopus citations

Abstract

A minimal model which includes spatial and cell lineage dynamics for stratified epithelia is presented. The dependence of tissue steady state on cell differentiation models, cell proliferation rate, cell differentiation rate, and other parameters are studied numerically and analytically. Our minimal model shows some important features. First, we find that morphogen or mechanical stress mediated interaction is necessary to maintain a healthy stratified epithelium. Furthermore, comparing with tissues in which cell differentiation can take place only during cell division, tissues in which cell division and cell differentiation are decoupled can achieve relatively higher degree of stratification. Finally, our model also shows that in the presence of short-range interactions, it is possible for a tissue to have multiple steady states. The relation between our results and tissue morphogenesis or lesion is discussed.

Original language	English
Article number	053051
Journal	New Journal of Physics
Volume	20
Issue number	5
DOIs	https://doi.org/10.1088/1367-2630/aac2ad
State	Published - May 2018

Keywords

active matter
biological tissues
hydrodynamic theory

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10.1088/1367-2630/aac2ad

Symmetry, Motility and Response of Biological Cells(2/2)
Chen, H.-Y. (PI)
1/08/17 → 31/10/18
Project: Research

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title = "A minimal spatial cell lineage model of epithelium: Tissue stratification and multi-stability",

abstract = "A minimal model which includes spatial and cell lineage dynamics for stratified epithelia is presented. The dependence of tissue steady state on cell differentiation models, cell proliferation rate, cell differentiation rate, and other parameters are studied numerically and analytically. Our minimal model shows some important features. First, we find that morphogen or mechanical stress mediated interaction is necessary to maintain a healthy stratified epithelium. Furthermore, comparing with tissues in which cell differentiation can take place only during cell division, tissues in which cell division and cell differentiation are decoupled can achieve relatively higher degree of stratification. Finally, our model also shows that in the presence of short-range interactions, it is possible for a tissue to have multiple steady states. The relation between our results and tissue morphogenesis or lesion is discussed.",

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T2 - Tissue stratification and multi-stability

AU - Yeh, Wei Ting

AU - Chen, Hsuan Yi

PY - 2018/5

Y1 - 2018/5

N2 - A minimal model which includes spatial and cell lineage dynamics for stratified epithelia is presented. The dependence of tissue steady state on cell differentiation models, cell proliferation rate, cell differentiation rate, and other parameters are studied numerically and analytically. Our minimal model shows some important features. First, we find that morphogen or mechanical stress mediated interaction is necessary to maintain a healthy stratified epithelium. Furthermore, comparing with tissues in which cell differentiation can take place only during cell division, tissues in which cell division and cell differentiation are decoupled can achieve relatively higher degree of stratification. Finally, our model also shows that in the presence of short-range interactions, it is possible for a tissue to have multiple steady states. The relation between our results and tissue morphogenesis or lesion is discussed.

AB - A minimal model which includes spatial and cell lineage dynamics for stratified epithelia is presented. The dependence of tissue steady state on cell differentiation models, cell proliferation rate, cell differentiation rate, and other parameters are studied numerically and analytically. Our minimal model shows some important features. First, we find that morphogen or mechanical stress mediated interaction is necessary to maintain a healthy stratified epithelium. Furthermore, comparing with tissues in which cell differentiation can take place only during cell division, tissues in which cell division and cell differentiation are decoupled can achieve relatively higher degree of stratification. Finally, our model also shows that in the presence of short-range interactions, it is possible for a tissue to have multiple steady states. The relation between our results and tissue morphogenesis or lesion is discussed.

KW - active matter

KW - biological tissues

KW - hydrodynamic theory

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DO - 10.1088/1367-2630/aac2ad

M3 - 期刊論文

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SN - 1367-2630

VL - 20

JO - New Journal of Physics

JF - New Journal of Physics

IS - 5

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ER -

A minimal spatial cell lineage model of epithelium: Tissue stratification and multi-stability

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Keywords

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Symmetry, Motility and Response of Biological Cells(2/2)

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