The interface between biochemical signaling and cell mechanics shapes T lymphocyte migration and activation.

tT cells migrate to lymphoid organs to become activated through specific contacts with antigen-presenting cells bearing foreign antigens. During migration and activation, T lymphocytes are exposed not only to diverse biochemical inputs, but also to different mechanical conditions. Passage from the blood or lymph to solid tissues involves lymphocyte rolling, firm arrest and diapedesis through endothelial monolayers. Throughout this process, cells are subjected to diverse fluid flow regimes. After extravasation, T lymphocytes crawl through viscoelastic media of different biochemical and mechanical properties and geometries. In lymph nodes, T cell contact with antigen-presenting cells is guided by rigidity cues and ligand-receptor interactions. T lymphocyte adaptation to diverse mechanical regimes involves multiple signaling and morphological modifications, many of which enable the conversion of mechanical forces into biochemical signals and vice-versa. These components enable T lymphocyte survival, homing and activation. Here, we review the mechanisms that enable T lymphocytes to survive and thrive under the different mechanical conditions they encounter during their life cycle. These processes require the integration of diverse signaling networks that convert extracellular mechano-chemical cues into force, movement and activation.

Tyrosine Phosphorylation of the Myosin Regulatory Light Chain Controls Non-muscle Myosin II Assembly and Function in Migrating Cells.

Active non-muscle myosin II (NMII) enables migratory cell polarization and controls dynamic cellular processes, such as focal adhesion formation and turnover and cell division. Filament assembly and force generation depend on NMII activation through the phosphorylation of Ser19 of the regulatory light chain (RLC). Here, we identify amino acid Tyr (Y) 155 of the RLC as a novel regulatory site that spatially controls NMII function. We show that Y155 is phosphorylated in vitro by the Tyr kinase domain of epidermal growth factor (EGF) receptor. In cells, phosphorylation of Y155, or its phospho-mimetic mutation (Glu), prevents the interaction of RLC with the myosin heavy chain (MHCII) to form functional NMII units. Conversely, Y155 mutation to a structurally similar but non-phosphorylatable amino acid (Phe) restores the more dynamic cellular functions of NMII, such as myosin filament formation and nascent adhesion assembly, but not those requiring stable actomyosin bundles, e.g., focal adhesion elongation or migratory front-back polarization. In live cells, phospho-Y155 RLC is prominently featured in protrusions, where it prevents NMII assembly. Our data indicate that Y155 phosphorylation constitutes a novel regulatory mechanism that contributes to the compartmentalization of NMII assembly and function in live cells.