Substrate softness promotes terminal differentiation of human keratinocytes without altering their ability to proliferate back into a rigid environment.

Substrate stiffness is a key regulator of cell behavior. To investigate how mechanical properties of cell microenvironment affect the human keratinocyte, primary cells were seeded on polyacrylamide hydrogels of different compliances (soft: 4 kPa, medium: 14 kPa, rigid: 45 kPa) in comparison with glass coverslip (> GPa). Keratinocyte spreading and proliferation were strongly decreased on the softest hydrogel, while no significant difference was observed between medium, rigid hydrogels and glass coverslip, and cells' viability was comparable in all conditions after 72 h. We then performed a RNA-seq to compare the transcriptomes from keratinocytes cultured for 72 h on the softest hydrogel or on coverslips. The cells on the soft hydrogel showed a strong increase in the expression of late differentiation marker genes from the epidermal differentiation complex (1q21) and the antioxidant machinery. In parallel, these cells displayed a significant loss of expression of the matrix receptors (integrin α6 and ß1) and the EGF receptor. However, when these cells were replated on a plastic culture plate (> GPa), they were able to re-engage the proliferation machinery with a strong colony-formation efficiency. Overall, using low-calcium differentiation monolayers at confluence, the lesser the rigidity, the stronger the markers of late differentiation are expressed, while the inverse is observed regarding the markers of early differentiation. In conclusion, below a certain rigidity, human keratinocytes undergo genome reprogramming indicating terminal differentiation that can switch back to proliferation in contact with a stiffer environment.

The Syk kinases orchestrate cerebellar granule cell tangential migration.

The tyrosine kinases of the Syk family are essential components of the well-characterized immunoreceptor ITAM-based signaling pathway. However, ITAM-based signaling typically does not function in isolation. Instead, it is enmeshed in the molecular network controlling cellular adhesion and chemotaxis. Consistent with the increasing number of data involving ITAM-bearing molecules in neuronal functions, we previously depicted a role for Syk kinases in the establishment of neuronal connectivity. In the developing cerebellum, we found that Syk is essentially expressed in the granule cells (GC) and more importantly, phosphorylated on tyrosine residues representative of an active form of the kinase in tangentially migrating GC. In light of these findings, experiments were performed to establish the implication of Syk in this process. We showed that Syk state of phosphorylation is spatiotemporally regulated during GC ontogeny. Moreover, the analysis of external granular layer microexplants treated with a Syk pharmacological inhibitor together with the quantification of ectopic GC in Syk+/-; ZAP-70-/- mutant mice brought evidence of a requirement of Syk in GC tangential migration. Syk phosphorylation was induced by EphB2 engagement and locally turned down by a not yet identified factor that could in part explain the restricted pattern of Syk phosphorylation observed along GC migratory route. Whereas Syk kinase activity appeared not essential for ephrin/Eph-mediated axon extension, it might provide polarization signals required for proper nucleus translocation during GC migration. In conclusion, Syk kinase acts downstream of receptors controlling GC tangential migration.