Gialpha and Gbeta subunits both define selectivity of G protein activation by alpha2-adrenergic receptors.

Previous studies of the specificity of receptor interactions with G protein subunits in living cells have relied on measurements of second messengers or other downstream responses. We have examined the selectivity of interactions between alpha2-adrenergic receptors (alpha2R) and various combinations of Gialpha and Gbeta subunit isoforms by measuring changes in FRET between Gialpha-yellow fluorescent protein and cyan fluorescent protein-Gbeta chimeras in HeLa cells. All combinations of Gialpha1, -2, or -3 with Gbeta1, -2, or -4 were activated to some degree by endogenous alpha2Rs as judged by agonist-dependent decreases in FRET. The degree of G protein activation is determined by the combination of Gialpha and Gbeta subunits rather than by the identity of an individual subunit. RT-PCR analysis and small interfering RNA knockdown of alpha2R subtypes, followed by quantification of radiolabeled antagonist binding, demonstrated that HeLa cells express alpha2a- and alpha2b-adrenergic receptor isoforms in a 2:1 ratio. Increasing receptor number by overexpression of the alpha2aR subtype minimized the differences among coupling preferences for Gialpha and Gbeta isoforms. The molecular properties of each Gialpha, Gbeta, and alpha2-adrenergic receptor subtype influence signaling efficiency for the alpha2-adrenergic receptor-mediated signaling pathway.

Allosteric determinants in guanine nucleotide-binding proteins.

Members of the G protein superfamily contain nucleotide-dependent switches that dictate the specificity of their interactions with binding partners. Using a sequence-based method termed statistical coupling analysis (SCA), we have attempted to identify the allosteric core of these proteins, the network of amino acid residues that couples the domains responsible for nucleotide binding and protein-protein interactions. One-third of the 38 residues identified by SCA were mutated in the G protein Gs alpha, and the interactions of guanosine 5'-3-O-(thio)triphosphate- and GDP-bound mutant proteins were tested with both adenylyl cyclase (preferential binding to GTP-Gs alpha) and the G protein beta gamma subunit complex (preferential binding to GDP-Gs alpha). A two-state allosteric model predicts that mutation of residues that control the equilibrium between GDP- and GTP-bound conformations of the protein will cause the ratio of affinities of these species for adenylyl cyclase and G beta gamma to vary in a reciprocal fashion. Observed results were consistent with this prediction. The network of residues identified by the SCA appears to comprise a core allosteric mechanism conferring nucleotide-dependent switching; the specific features of different G protein family members are built on this core.