Cell-cell adhesion impacts epithelia response to substrate stiffness: Morphology and gene expression

Cell-cell adhesion impacts epithelia response to substrate stiffness: Morphology and gene expression

Monolayer epithelial cells interact constantly with the substrate they reside on and their surrounding neighbors. As such, the properties of epithelial cells are profoundly governed by the mechanical and molecular cues that arise from both the substrate and contiguous cell neighbors. Although both c...

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Bibliographic Details
Published in:Biophysical journal Vol. 121; no. 2; pp. 336 - 346
Main Authors: Choi, David, Gonzalez, Zachary, Ho, Sum Yat, Bermudez, Alexandra, Lin, Neil Y.C.
Format: Journal Article
Language:English
Published: United States Elsevier Inc 18-01-2022
The Biophysical Society
Subjects:
Cell Adhesion - physiology
Cell Communication
Epithelial Cells
Epithelium
Gene Expression
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Summary:Monolayer epithelial cells interact constantly with the substrate they reside on and their surrounding neighbors. As such, the properties of epithelial cells are profoundly governed by the mechanical and molecular cues that arise from both the substrate and contiguous cell neighbors. Although both cell-substrate and cell-cell interactions have been studied individually, these results are difficult to apply to native confluent epithelia, in which both jointly regulate the cell phenotype. Specifically, it remains poorly understood about the intertwined contributions from intercellular adhesion and substrate stiffness on cell morphology and gene expression, two essential microenvironment properties. Here, by adjusting the substrate modulus and altering the intercellular adhesion within confluent kidney epithelia, we found that cell-substrate and cell-cell interactions can mask each other's influence. For example, we found that epithelial cells exhibit an elongated morphological phenotype only when the substrate modulus and intercellular adhesions are both reduced, whereas their motility can be upregulated by either reduction. These results illustrate that combinatorial changes of the physical microenvironment are required to alter cell morphology and gene expression.
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These authors contributed equally
ISSN:0006-3495
1542-0086
DOI:10.1016/j.bpj.2021.11.2887