Showing papers on "GTP-Binding Protein alpha Subunits published in 1996"

The 2.0 Å crystal structure of a heterotrimeric G protein

Abstract: The structure of a heterotrimeric G protein reveals the mechanism of the nucleotide-dependent engagement of the alpha and beta gamma subunits that regulates their interaction with receptor and effector molecules. The interaction involves two distinct interfaces and dramatically alters the conformation of the alpha but not of the beta gamma subunits. The location of the known sites for post-translational modification and receptor coupling suggest a plausible orientation with respect to the membrane surface and an activated heptahelical receptor.

Carboxyl-terminal mutations of Gq alpha and Gs alpha that alter the fidelity of receptor activation.

Abstract: The carboxyl terminus of the G protein alpha subunit is a key determinant of the fidelity of receptor activation. We have previously shown that the Gq alpha subunit (alpha q) can be made to respond to alpha i-coupled receptors by replacing its carboxyl terminus with the corresponding alpha i2, alpha o, alpha z residues. We now extend these findings in three ways: 1) carboxyl-terminal mutations of alpha q/alpha i chimeras show that the critical amino acids are in the -3 and -4 positions, 2) exchange of carboxyl termini between alpha q and alpha z allows activation by receptors appropriate to the carboxyl-terminal residues, and 3) we identify receptors that either do or do not activate the expected carboxyl-terminal chimeras (alpha q/alpha i, alpha q/alpha s, alpha s/alpha q). Replacement of the five carboxyl-terminal amino acids of alpha q with the alpha s sequence permitted an alpha s-coupled receptor (the V2 vasopressin receptor but not the beta 2-adrenergic receptor) to stimulate phospholipase C. Replacement of the five carboxyl-terminal amino acids of alpha z with residues of alpha q permitted certain alpha q-coupled receptors (bombesin and V1a vasopressin receptors but not the oxytocin receptor) to stimulate adenylyl cyclase. Thus, the relative importance of the G alpha carboxyl terminus in permitting coupling to a new receptor depends on the receptor with which it is paired. These studies refine our understanding and provide new tools with which to study the fidelity of receptor/G alpha activation.

Reciprocal regulation of Gsα by palmitate and the βγ subunit

Abstract: Hormonal activation of Gs, the stimulatory regulator of adenylyl cyclase, promotes dissociation of alpha s from G beta gamma, accelerates removal of covalently attached palmitate from the G alpha subunit, and triggers release of a fraction of alpha s from the plasma membrane into the cytosol. To elucidate relations among these three events, we assessed biochemical effects in vitro of attached palmitate on recombinant alpha s prepared from Sf9 cells. In comparison to the unpalmitoylated protein (obtained from cytosol of Sf9 cells, treated with a palmitoyl esterase, or expressed as a mutant protein lacking the site for palmitoylation), palmitoylated alpha s (from Sf9 membranes, 50% palmitoylated) was more hydrophobic, as indicated by partitioning into TX-114, and bound beta gamma with 5-fold higher affinity. beta gamma protected GDP-bound alpha s, but not alpha s-GTP[gamma S], from depalmitoylation by a recombinant esterase. We conclude that beta gamma binding and palmitoylation reciprocally potentiate each other in promoting membrane attachment of alpha s and that dissociation of alpha s.GTP from beta gamma is likely to mediate receptor-induced alpha s depalmitoylation and translocation of the protein to cytosol in intact cells.

The mating-specific G(alpha) protein of Saccharomyces cerevisiae downregulates the mating signal by a mechanism that is dependent on pheromone and independent of G(beta)(gamma) sequestration.

Abstract: It has been inferred from compelling genetic evidence that the pheromone-responsive G(alpha) protein of Saccharomyces cerevisiae, Gpa1, directly inhibits the mating signal by binding to its own beta(gamma) subunit. Gpa1 has also been implicated in a distinct but as yet uncharacterized negative regulatory mechanism. We have used three mutant alleles of GPA1, each of which confers resistance to otherwise lethal doses of pheromone, to explore this possibility. Our results indicate that although the G322E allele of GPA1 completely blocks the pheromone response, the E364K allele promotes recovery from pheromone treatment rather than insensitivity to it. This observation suggests that Gpa1, like other G(alpha) proteins, interacts with an effector molecule and stimulates a positive signal--in this case, an adaptive signal. Moreover, the Gpa1-mediated adaptive signal is itself induced by pheromone, is delayed relative to the mating signal, and does not involve sequestration of G(beta)(gamma). The behavior of N388D, a mutant form of Gpa1 predicted to be activated, strongly supports these conclusions. Although N388D cannot sequester beta(gamma), as evidenced by two-hybrid analysis and its inability to complement a Gpa1 null allele under normal growth conditions, it can stimulate adaptation and rescue a gpa1(delta) strain when cells are exposed to pheromone. Considered as a whole, our data suggest that the pheromone-responsive heterotrimeric G protein of S. cerevisiae has a self-regulatory signaling function. Upon activation, the heterotrimer dissociates into its two subunits, one of which stimulates the pheromone response, while the other slowly induces a negative regulatory mechanism that ultimately shuts off the mating signal downstream of the receptor.

Enhancement of TNF-alpha synthesis by overexpression of G alpha z in a mast cell line.

Abstract: Ag stimulation of mast cells via the IgE receptor (Fc epsilon RI) elicits production and release of numerous cytokines. This activation of Fc epsilon RI initiates various tyrosine kinase-dependent signaling cascades, which ultimately result in the de novo synthesis of cytokines. To date, no heterotrimeric G proteins have been implicated in this process. Here we report that the alpha subunit of the heterotrimeric G protein, Gz, can regulate production of the cytokine, TNF-alpha. The alpha subunit was overexpressed in a cultured mast cell line (RBL-2H3) known to contain G alpha z. In stimulated cells, overexpression of G alpha z significantly enhanced the production of TNF-alpha. This effect of G alpha z appeared to be restricted in that constitutive synthesis of the cytokine, TGF-beta, and Ag-stimulation of the phosphoinositide-dependent secretory pathway were not significantly affected. Thus, G alpha z, a heterotrimeric G protein, appeared to modulate the stimulatory pathways for induction of TNF-alpha synthesis in RBL-2H3 cells.

Ontogeny of GTP-binding proteins, Gi and G(o), in rat retina.

Abstract: The distribution and the levels of Gi1 (plus Gi3), Gi2, and G(o) in rat retina were studied immunohistochemically and immunochemically during development. At embryonic day (E) 15, Gi1 alpha/Gi3 alpha was observed in the inner layer of the neural retina, the future nerve fiber layer (NFL), while Gi2 alpha was observed both in the inner and outer layers of the neural retina. No immunoreactivity for G(o) alpha was observed. At E18, Gi1 alpha/Gi3 alpha and Gi2 alpha appeared in the inner plexiform layer (IPL), while G(o) alpha was faintly immunoreactive only in the NFL. At birth, Gi2 alpha/Gi3 alpha and G(o) alpha appeared in the ganglion cell layer. Gi2 alpha was intensely immunoreactive in the NFL and IPL. At postnatal day (P) 10, the inner portions of the retina, from the NFL to the outer plexiform layer, were immunoreactive to Gi1 alpha/Gi3 alpha, Gi2 alpha, and G(o) alpha. Gi1 alpha/Gi3 alpha and G(o) alpha were distributed characteristically in a laminated pattern in the IPL, but Gi2 alpha was present homogeneously in the IPL. At P12, Gi2 alpha appeared in the outer nuclear layer. As the postnatal days advanced, the laminated pattern of immunoreactivity to G(o) alpha in the IPL became diffuse, but immunoreactivity to Gi1 alpha/Gi3 alpha remained. The results of enzyme immunoassays showed that the concentration of G(o) alpha increased rapidly from P10 to P15 and reached almost the adult level at P20-P30, while Gi2 alpha decreased until P15 and was almost constant thereafter. These results showed that the distribution of Gi1 alpha/Gi3 alpha, Gi2 alpha, and G(o) alpha differs during development, suggesting that each G protein in the developing retina has a unique function.