Litcius/Paper detail

Mechanics of the cellular microenvironment as probed by cells in vivo during zebrafish presomitic mesoderm differentiation

Alessandro Mongera, Marie Pochitaloff, Hannah J. Gustafson, Georgina A. Stooke‐Vaughan, Payam Rowghanian, Sangwoo Kim, Otger Campàs

2022Nature Materials85 citationsDOIOpen Access PDF

Abstract

Tissue morphogenesis, homoeostasis and repair require cells to constantly monitor their three-dimensional microenvironment and adapt their behaviours in response to local biochemical and mechanical cues. Yet the mechanical parameters of the cellular microenvironment probed by cells in vivo remain unclear. Here, we report the mechanics of the cellular microenvironment that cells probe in vivo and in situ during zebrafish presomitic mesoderm differentiation. By quantifying both endogenous cell-generated strains and tissue mechanics, we show that individual cells probe the stiffness associated with deformations of the supracellular, foam-like tissue architecture. Stress relaxation leads to a perceived microenvironment stiffness that decreases over time, with cells probing the softest regime. We find that most mechanical parameters, including those probed by cells, vary along the anteroposterior axis as mesodermal progenitors differentiate. These findings expand our understanding of in vivo mechanosensation and might aid the design of advanced scaffolds for tissue engineering applications.

Topics & Concepts

ZebrafishParaxial mesodermMorphogenesisMechanosensationIn vivoCell biologyCellular differentiationMechanobiologyTissue engineeringBiologyBiophysicsChemistryMesodermEmbryonic stem cellIon channelReceptorBiochemistryBiotechnologyGeneticsGeneCellular Mechanics and Interactions3D Printing in Biomedical ResearchSpaceflight effects on biology