E-cadherin adhesion dynamics as revealed by an accelerated force ramp are dependent upon the presence of -catenin

Tissue remodeling and shape changes often rely on force-induced cell rearrangements occurring via cell-cell contact dynamics. Epithelial cell-cell contact shape changes are particularly dependent upon E-cadherin adhesion dynamics which are directly influenced by cell-generated and external forces. While both the mobility of Ecadherin adhesions and their adhesion strength have been reported before, it is not clear how these two aspects of E-cadherin adhesion dynamics are related. Here, using magnetic pulling cytometry, we applied an accelerated force ramp on the E-cadherin adhesion between an E-cadherin-coated magnetic microbead and an epithelial cell to ascertain this relationship. Our approach enables the determination of the adhesion strength and forcedependent mobility of individual adhesions, which revealed a direct correlation between these key characteristics. Since alpha-catenin has previously been reported to play a role in both E-cadherin mobility and adhesion strength when studied independently, we also probed epithelial cells in which alpha-catenin has been knocked out. We found that, in the absence of alpha-catenin, E-cadherin adhesions not only had lower adhesion strength, as expected, but were also more mobile. We observed that alpha-catenin was required for the recovery of strained cell-cell contacts and propose that the adhesion strength and force-dependent mobility of E-cadherin adhesions act in tandem to regulate cell-cell contact homeostasis. Our approach introduces a method which relates the forcedependent adhesion mobility to adhesion strength and highlights the morphological role played by alpha-catenin in E-cadherin adhesion dynamics.