Litcius/Paper detail

The Physics of Cellular Decision Making During Epithelial–Mesenchymal Transition

Shubham Tripathi, Herbert Levine, Mohit Kumar Jolly

2020Annual Review of Biophysics113 citationsDOI

Abstract

The epithelial-mesenchymal transition (EMT) is a process by which cells lose epithelial traits, such as cell-cell adhesion and apico-basal polarity, and acquire migratory and invasive traits. EMT is crucial to embryonic development and wound healing. Misregulated EMT has been implicated in processes associated with cancer aggressiveness, including metastasis. Recent experimental advances such as single-cell analysis and temporal phenotypic characterization have established that EMT is a multistable process wherein cells exhibit and switch among multiple phenotypic states. This is in contrast to the classical perception of EMT as leading to a binary choice. Mathematical modeling has been at the forefront of this transformation for the field, not only providing a conceptual framework to integrate and analyze experimental data, but also making testable predictions. In this article, we review the key features and characteristics of EMT dynamics, with a focus on the mathematical modeling approaches that have been instrumental to obtaining various useful insights.

Topics & Concepts

Epithelial–mesenchymal transitionBiologyCell polarityPhenotypePolarity (international relations)Process (computing)Embryonic stem cellMetastasisCell migrationEpithelial polarityComputational biologyNeuroscienceCellComputer scienceCancerGeneticsGeneOperating systemCancer Cells and MetastasisMathematical Biology Tumor GrowthCellular Mechanics and Interactions