Signaling receptors in the plasma membrane control information exchange within and across cells. Among the different transmembrane signaling receptors, the Fas protein is receiving growing attention, mainly because of its ‘dual character’ in promoting as well as preventing cell growth in both cancer and normal cells. Here, we engineer a bottom-up approach to investigate the physical mechanism behind the duality in Fas receptor-ligand complexes that control the cell functions.
Multi-domain signaling receptors, including Fas are known to undergo molecular conformational changes to facilitate the downstream recruitment of signaling molecules. Such a conformational switch is usually driven by the change in chemical state (ligand, phosphorylation, glycosylation, etc). Fas_Life-Death combines biochemical (for in-vitro protein reconstitution), synthetic biology (for site-specific fluorescence labeling), and optical methods (single-molecule FRET, single particle tracking) to explore new conformations, and molecular mechanisms of Fas-mediated clustering in membranes. Investigating the influence of structural and molecular dynamics of transmembrane proteins on the physiological activity of cells have both scientific and pharmaceutical significance. These could provide comprehensive insights to transmembrane communication and identify points of intervention for drug design.