Abstract FR:

Epithelia are the biological tissues which line and protect our organs. Because their role is both to protect the body against various exterior stresses and to serve as an exchange platform (air, nutrient, liquids etc), epithelial tissues must adopt a precise morphology, which depends on its localization in our organism. In this thesis, we build a realistic though simple biophysical model of epithelia, incorporating one by one throughout the chapters the various aspects of the epithelial cell biology. We first consider the simplest case of a tissue composed of a single cell type, without migration or division. The only active forces arise from differential tensions on each of the cell edges, which dictate the morphology of the epithelial sheet. This model of active foams predicts non-trivial phase transitions between the different stereotypical morphologies observed in vivo, which can be used to understand various developmental events such as sheet bending and the formation of biological tubes or spheres of precise radii. Secondly, we incorporate in our model the stresses arising from cell division and death. When tissues grow in constrained environments, buckling instabilities are generically expected, and we show that a simple biomechanical model can explain a wide variety of biological shapes, such as the intestinal wall or pathologies of biological tubes such as arteries and trachea. We also consider the interconversion of different cell types such as stem cell and differentiated cells. Finally, we study collective cell migration, modeling each cell as a self-propelled polar particle. We discuss how the polarity field of collective cell migration can create biological patterns. We integrate the ingredients above in a simple analytical model, and show the existence of a spontaneous instability leading the the formation of stem cell patterns. The instability results from a subtle interplay between the forces arising from differentiated cell migration and stem cell division.