A Universal Allosteric Mechanism for G Protein Activation

G proteins play a central role in signal transduction and pharmacology. Signaling is initiated by cell-surface receptors, which promote GTP binding and the dissociation of G from the G{beta}{gamma} subunits. Structural studies have revealed the molecular basis for subunit association with receptors, RGS proteins and downstream effectors. In contrast, the mechanism of subunit dissociation is poorly understood. We used cell signaling assays, MD simulations, biochemistry and structural analysis to identify a conserved network of amino acids that dictates subunit release. In the presence of the terminal phosphate of GTP, a glycine forms a polar network with an arginine and glutamate, putting torsional strain on the subunit binding interface. This "G-R-E motif" secures GTP and, through an allosteric link, discharges the G{beta}{gamma} dimer. Replacement of network residues prevents subunit dissociation, regardless of agonist or GTP binding. These findings reveal the molecular basis for the final committed step of G protein activation. HIGHLIGHTSO_LIReceptors promote GTP-GDP exchange and dissociation of G protein and {beta}{gamma} subunits C_LIO_LIWe find an allosteric network linking the {gamma} phosphate of GTP with release of G{beta}{gamma} C_LIO_LIThe network consists of a conserved Gly-Arg-Glu "activation triad" C_LIO_LITriad mutations prevent subunit dissociation, regardless of agonist or GTP binding C_LIO_LITriad mutations are responsible for human endocrine and neurological disorders C_LI