Expression of Gs alpha in Escherichia coli. Purification and properties of two forms of the protein

Cloning of complementary DNAs that encode either of two forms of the alpha subunit of the guanine nucleotide-binding regulatory protein (Gs) that stimulates adenylyl cyclase into appropriate plasmid vectors has allowed these proteins to be synthesized in Escherichia coli (Graziano, M.P., Casey, P.J., and Gilman, A.G. (1987) J. Biol. Chem. 262, 11375-11381). A rapid procedure for purification of milligram quantities of these proteins is described. As expressed in E. coli, both forms of Gs alpha (apparent molecular weights of 45,000 and 52,000) bind guanosine 5'-(3-O-thio)triphosphate stoichiometrically. The proteins also hydrolyze GTP, although at different rates (i.e. 0.13.min-1 and 0.34.min-1 at 20 degrees C for the 45- and the 52-kDa forms, respectively). These rates reflect differences in the rate of dissociation of GDP from the two proteins. Both forms of recombinant Gs alpha have essentially the same kcat for GTP hydrolysis, approximately 4.min-1. Recombinant Gs alpha interacts functionally with G protein beta gamma subunits and with beta-adrenergic receptors. The proteins can also be ADP-ribosylated stoichiometrically by cholera toxin. This reaction requires the addition of beta gamma subunits. Both forms of recombinant Gs alpha can reconstitute GTP-, isoproterenol + GTP-, guanosine 5'-(3-O-thio)triphosphate-, and fluoride-stimulated adenylyl cyclase activity in S49 cyc- membranes to maximal levels, although their specific activities for this reaction are lower than that observed for Gs purified from rabbit liver. Experiments with purified bovine brain adenylyl cyclase indicate that the affinity of recombinant Gs alpha for adenylyl cyclase is 5-10 times lower than that of liver Gs under these assay conditions; however, the intrinsic capacity of the recombinant protein to activate adenylyl cyclase is normal. These findings suggest that Gs alpha, when synthesized in E. coli, may fail to undergo a posttranslational modification that is crucial for high affinity interaction of the G protein with adenylyl cyclase.     

Regulation of signal transfer from beta 1-adrenoceptor to adenylate cyclase by beta gamma subunits in a reconstituted system

The beta gamma subunits of guanine nucleotide binding proteins from bovine brain and bovine rod outer segments have different structural and immunochemical properties. In spite of these structural differences, beta gamma subunits from these sources have been found to be fully interchangeable in terms of their interaction with alpha subunits of pertussis-toxin-sensitive G proteins. In contrast, however, there are striking differences between these beta gamma subunits with regard to their ability to deactivate fluoride-stimulated Gs. These profound differences were also observed when the interaction of the purified components of the adenylate cyclase system was studied after reconstitution into phospholipid vesicles. Addition of beta gamma purified from bovine brain to vesicles containing beta-receptor and Gs results in a biphasic effect on receptor-stimulated GTPase activity, whereas addition of transducin beta gamma was virtually without any effect. Likewise, beta gamma from bovine brain, but not transducin beta gamma, affected adenylate cyclase activity of a reconstituted system consisting of three purified components (R, Gs, C). Thus, the alpha subunit of Gs, but not the alpha subunits of pertussis-toxin-sensitive G proteins discriminate between structurally different beta gamma subunits.     

ADP-ribosylation of Gs promotes the dissociation of its alpha and beta subunits

We have utilized purified reactants and cofactors to examine the form of the stimulatory guanine nucleotide-binding regulatory component (Gs) of adenylate cyclase that serves as a substrate for ADP-ribosylation by cholera toxin; we have also investigated some of the consequences of that covalent modification. Activation of Gs with nonhydrolyzable analogs of GTP, which causes dissociation of its subunits, completely inhibits the toxin-catalyzed covalent modification. However, this effect cannot be explained by subunit dissociation, since activation of Gs by fluoride is not inhibitory and ADP ribosylation of the alpha (45,000-Da) subunit of Gs proceeds equally well in the presence and absence of the beta (35,000-Da) subunit. ADP-ribosylation of the alpha subunit of Gs decreases its apparent affinity for the beta subunit; however, the affinity of alpha and ADP-ribosyl-alpha for GTP appear to be approximately the same. ADP-ribosylation of Gs thus promotes the dissociation of its alpha and beta subunits. This effect may account for or contribute to the activation of adenylate cyclase by cholera toxin.     

Purification of the catalyst of adenylate cyclase

The catalytic moiety of hormone-sensitive adenylate cyclase has been purified from bovine brain. It is isolated largely without its guanine nucleotide-binding regulatory protein, Gs, by affinity chromatography on 7-O-hemisuccinyldeacetylforskolin-agarose. It appears to be a single polypeptide which migrates on sodium dodecyl sulfate-polyacrylamide gels with an apparent Mr of approximately 120,000. When subjected to electrophoresis on gradient (5-10%) sodium dodecyl sulfate-polyacrylamide gels, it displays a larger apparent Mr of 150,000. The adenylate cyclase activity of the preparation can be stimulated by the addition of Gs, forskolin, or calcium-calmodulin. The preparation has been reconstituted with purified beta-adrenergic receptors and Gs to form a hormone-stimulated adenylate cyclase system (May, D., Ross, E.M., Gilman, A.G., and Smigel, M.D. (1985) J. Biol. Chem. 260, 15829-15833). In contrast to its stimulation by Gs, inhibition by the alpha subunits of Gi and Go, G proteins known to be coupled to inhibitory receptors (Sternweis, P., and Florio, V. (1985) J. Biol. Chem. 260, 3477-3483), is not seen. Preparations of adenylate cyclase show varying degrees of inhibition by added G protein beta . gamma subunit. This inhibition can be explained as reflecting a variable, small (under 5%) contamination of the preparation by Gs alpha which would be deactivated by complexing with the added beta . gamma subunit.     

Immunoprecipitation of adenylate cyclase with an antibody to a carboxyl-terminal peptide from Gs alpha

An antibody (RM) raised against the carboxyl-terminal decapeptide of the alpha subunit of the stimulatory guanine nucleotide regulatory protein (Gs alpha) has been used to study the interaction of Gs alpha with bovine brain adenylate cyclase [ATP pyrophosphate-lyase (cyclizing), EC 4.6.1.1]. RM antibody immunoprecipitated about 60% of the solubilized adenylate cyclase preactivated with either GTP-gamma-S or AlF4-. In contrast, RM antibody immunoprecipitated about 5% of the adenylate cyclase not preactivated (control) and 15% of the adenylate cyclase pretreated with forskolin. Adenylate cyclase solubilized from control membranes or GTP-gamma-S preactivated membranes was partially purified by using forskolin-agarose affinity chromatography. The amount of Gs alpha protein in the partially purified preparations was determined by immunoblotting with RM antibody. There was 3-fold more Gs alpha detected in partially purified adenylate cyclase from preactivated membranes than in the partially purified adenylate cyclase from control membranes. Partially purified adenylate cyclase from preactivated membranes was immunoprecipitated with RM antibody and the amount of adenylate cyclase activity immunoprecipitated (65% of total) corresponded to the amount of Gs alpha protein immunoprecipitated. Only 15% of the partially purified adenylate cyclase from control membranes was immunoprecipitated. The presence of other G proteins in the partially purified preparations of adenylate cyclase was investigated by using specific antisera that detect Go alpha, Gi alpha, and G beta. The G beta protein was the only subunit detected in the partially purified preparations of adenylate cyclase and the amount of G beta was about the same in adenylate cyclase from preactivated membranes and from control membranes.(ABSTRACT TRUNCATED AT 250 WORDS)     

Mono-ADP-ribosylation of Gs by an eukaryotic arginine-specific ADP-ribosyltransferase stimulates the adenylate cyclase system

An arginine-specific ADP-ribosyltransferase, named ADP-ribosyltransferase A, was partially purified from human platelets using polyarginine as an ADP-ribose acceptor. When human platelet membranes were incubated with the transferase A in the presence of NAD+, Gs, a stimulatory guanine nucleotide-binding protein of the adenylate cyclase was specifically mono-ADP-ribosylated. ADP-ribose transfer to Gs by this enzyme was suppressed when membranes were pre-ADP-ribosylated by cholera toxin. Incubation of membranes with the transferase A resulted in activation of the adenylate cyclase system. This stimulatory effect of the transferase A on the adenylate cyclase system was inhibited by the presence of polyarginine. These results indicate a role of ADP-ribosyltransferase A in regulation of the adenylate cyclase system via endogenous mono-ADP-ribosylation of Gs.     

Evidence for a rabbit luteal ADP-ribosyltransferase activity which appears to be capable of activating adenylyl cyclase.

1. An ADP-ribosyltransferase activity which appears to be capable of activating adenylyl cyclase was identified in a plasma membrane fraction from rabbit corpora lutea and partially characterized by comparing the properties of the luteal transferase with those of cholera toxin. 2. Incubation of luteal membranes in the presence of GTP and varying concentrations of NAD resulted in concentration-dependent increases in adenylyl cyclase activity. 3. Stimulation of adenylyl cyclase by NAD and cholera toxin plus NAD was observed in the presence of GTP but not in the presence of guanosine-5'-O-(2-thiodiphosphate) or guanyl-5'-yl imidodiphosphate. 4. NAD or cholera toxin plus NAD reduced the Kact values for luteinizing hormone to activate adenylyl cyclase 3- to 3.5-fold. 5. NAD or cholera toxin plus NAD increased the extent to which cholate extracts from luteal membranes were able to reconstitute adenylyl cyclase activity in S49 cyc- mouse lymphoma membranes. 6. It was necessary to add ADP-ribose and arginine to the incubation mixture in order to demonstrate cholera toxin-specific ADP-ribosylation of a protein corresponding to the alpha subunit of the stimulatory guanine nucleotide-binding regulatory component (alpha Gs). 7. Treatment of luteal membranes with NAD prior to incubation in the presence of [32P]NAD plus cholera toxin resulted in reduced labeling of alpha Gs. 8. Endogenous ADP-ribosylation of alpha Gs was enhanced by Mg but was not altered by guanine nucleotide, NaF or luteinizing hormone and was inhibited by cAMP. 9. Incubation of luteal membranes in the presence of [32P]ADP-ribose in the absence and presence of cholera toxin did not result in the labeling of any membrane proteins.     

The stimulatory guanine-nucleotide regulatory unit of adenylate cyclase from bovine cerebral cortex. ADP-ribosylation and purification.

Hormonal stimulation of adenylate cyclase from bovine cerebral cortex is mediated by a guanine-nucleotide regulatory protein (Gs). This protein contains at least three polypeptides: a guanine nucleotide-binding alpha s component and a beta X gamma component, which modulates the function of alpha s. The alpha s component from many tissues can be ADP-ribosylated with cholera toxin, but has been unusually difficult to modify in brain. We have improved incorporation of ADP-ribose by including isonicotinic acid hydrazide to inhibit the potent NAD glycohydrolase activity of brain. ADP-ribosylation is further improved by addition of detergent to render the substrates accessible and 20 mM-EDTA to chelate metal ions. Although Mg2+ is absolutely required for activation of adenylate cyclase by the GTP analogue guanosine 5'-[beta gamma-imido]triphosphate (p[NH]ppG), it is not obligatory for p[NH]ppG-stimulated ADP-ribosylation by cholera toxin. Under these conditions, the ADP-ribosylation of brain membranes is not enhanced by a cytosolic protein. We find that there are two major sizes of brain alpha s, which we have named 'alpha sL', with an apparent Mr of 42,000-45,000, and 'alpha sH' with an apparent Mr of 46,000-51,000 depending on the gel-electrophoretic system used. The alpha sL and alpha sH components can incorporate different amounts of ADP-ribose depending on the reaction conditions, so that one or the other may appear to predominate. Thus we show that incomplete ADP-ribosylation by cholera toxin is not a good indication of the relative amounts of alpha s units. Functionally, however, both forms of alpha s appear to be similar. Both forms associate with the catalytic unit of adenylate cyclase, but neither of them does so preferentially. There is an excess of each of them over the amount associated with catalytic unit. We have now substantially purified Gs from brain by a modification of the method of Sternweis et al. [(1981) J. Biol. Chem. 256, 11517-11526] as well as by a new, simplified, procedure. On SDS/polyacrylamide-gel electrophoresis, the purified brain Gs contains both the 45 and 51 kDa alpha s polypeptides revealed by ADP-ribosylation and a beta X gamma component. Activation of purified alpha s by guanine nucleotides or fluoride can be reversed by addition of purified beta X gamma component. The activated form of purified brain Gs has an Mr of 49,000 as determined by hydrodynamic measurements, which is consistent with the idea that the active form of brain Gs is the dissociated one.     

Translocation of alpha subunits of stimulatory guanine nucleotide-binding proteins through stimulation of the prostacyclin receptor in mouse mastocytoma cells.

The translocation of the alpha subunits of Gs from the membrane to the cytosol by iloprost, a stable prostacyclin analogue, was studied in mouse mastocytoma P-815 cells. In the presence of guanosine 5'-O-(thiotriphosphate) (GTP gamma S), iloprost stimulated the adenylate cyclase activity, caused the release of both 42- and 45-kDa proteins reactive with the anti Gs alpha carboxyl-terminal antibody, RM/1, from the membrane and attenuated cholera toxin-catalyzed ADP-ribosylation of the 42- and 45-kDa proteins in the membrane. The iloprost-stimulated adenylate cyclase activity and release of Gs alpha from the membrane were markedly suppressed by RM/1. Cholera toxin treatment also stimulated the adenylate cyclase activity and release of Gs alpha from the membrane, and iloprost synergistically potentiated these actions of cholera toxin. In mastocytoma cells, iloprost induced the translocation of both 42- and 45-kDa Gs alpha from the membrane to the cytosol, 45-kDa Gs alpha remaining in the cytosol for a longer time than 42- kDa Gs alpha. Whereas 42-kDa Gs alpha in the cytosol was eluted at the position of Mr = approximately 40,000 45-kDa Gs alpha was eluted at the position of Mr = approximately 120,000 from a Superose 12 gel filtration column. In contrast, both 42- and 45-kDa Gs alpha released in vitro from the membrane by iloprost plus GTP gamma S were eluted at the position of Mr = approximately 40,000, but only 45-kDa Gs alpha was eluted at the position of Mr = approximately 120,000 when it was incubated with cytosol. These results taken together demonstrate that iloprost induces the translocation of both 42- and 45-kDa Gs alpha from the membrane to the cytosol and that only the 45-kDa Gs alpha released exists in the cytosol as a soluble complex with unidentified component(s) in mastocytoma cells.     

Mutations of GS alpha designed to alter the reactivity of the protein with bacterial toxins. Substitutions at ARG187 result in loss of GTPase activity

We have introduced two types of mutations into cDNAs that encode the alpha subunit of Gs, the guanine nucleotide-binding regulatory protein that stimulates adenylyl cyclase. The arginine residue (Arg187) that is the presumed site of ADP-ribosylation of Gs alpha by cholera toxin has been changed to Ala, Glu, or Lys. The rate constant for hydrolysis of GTP by all of these mutants is reduced approximately 100-fold compared with the wild-type protein. As predicted from this change, these proteins activate adenylyl cyclase constitutively in the presence of GTP. Despite these substitutions, cholera toxin still catalyzes the incorporation of 0.2-0.3 mol of ADP-ribose/mol of mutant alpha subunit. The sequence near the carboxyl terminus of Gs alpha was altered to resemble those in Gi alpha polypeptides, which are substrates for pertussis toxin. Despite this change, the mutant protein is a poor substrate for pertussis toxin. Although this protein has unaltered rates of GDP dissociation and GTP hydrolysis, its ability to activate adenylyl cyclase in the presence of GTP is enhanced by 3-fold when compared with the wild-type protein but only when these assays are performed after reconstitution of Gs alpha into cyc- (Gs alpha-deficient) S49 cell membranes.     

The protein cofactor necessary for ADP-ribosylation of Gs by cholera toxin is itself a GTP binding protein

A membrane-bound protein cofactor (ARF) is required for the cholera toxin-dependent ADP-ribosylation of the stimulatory regulatory component (Gs) of adenylate cyclase. Improved methods for the purification of ARF from bovine brain are described. ARF has a high-affinity binding site for guanine nucleotides. Binding of GTP or GTP gamma S to ARF is necessary for the activity of the cofactor; GDP X ARF does not support ADP-ribosylation of Gs. Although the protein as purified contains stoichiometric amounts of GDP, GTPase activity of isolated ARF was not detected. Cholera toxin-dependent activation of adenylate cyclase thus requires two guanine nucleotide binding proteins.     

The inhibitory guanine nucleotide-binding regulatory component of adenylate cyclase. Properties and function of the purified protein

Treatment of membranes with islet activating protein (IAP), a toxin from Bordetella pertussis, results in abolition of GTP-dependent, receptor-mediated inhibition of adenylate cyclase. This appears to result from IAP-catalyzed ADP-ribosylation of a 41,000-Da membrane-bound protein. A protein with 41,000- and 35,000-Da subunits has been purified from rabbit liver membranes as the predominant substrate for IAP. This protein has now been shown to be capable of regulating membrane-bound adenylate cyclase activity of human platelets under various conditions. The characteristics of the actions of the IAP substrate are as follows. 1) Purified 41,000/35,000-Da dimer is capable of restoring the inhibitory effects of guanine nucleotides and the alpha 2-adrenergic agonist, epinephrine, on the adenylate cyclase activity of IAP-treated membranes. 2) The subunits of the dimer dissociate in the presence of guanine nucleotide analogs or A1(3+), Mg2+, and F-. The 41,000-Da subunit has a high affinity binding site for guanine nucleotides. 3) The resolved 35,000-Da subunit of the dimer mimics guanine nucleotide- and epinephrine-induced inhibition of adenylate cyclase. 4) The resolved (unliganded) 41,000-Da subunit stimulates adenylate cyclase activity and relieves guanine nucleotide- +/- epinephrine-induced inhibition of the enzyme. In contrast, the GTP gamma S-bound form of the 41,000-Da subunit inhibits adenylate cyclase activity, although with lower apparent affinity than does the 35,000-Da subunit. 5) The 35,000-Da subunit increases the rate of deactivation of Gs, the stimulatory regulatory protein of adenylate cyclase. In contrast, the 41,000-Da subunit can interact with Gs and inhibit its deactivation. These data strongly suggest that the IAP substrate is another dimeric, guanine nucleotide-binding regulatory protein and that it is responsible for inhibitory modulation of adenylate cyclase activity.     

Deletion within the amino-terminal region of Gs alpha impairs its ability to interact with beta gamma subunits and to activate adenylate cyclase.

Proteolytic experiments performed on transducin and Go alpha subunit strongly suggest that the amino-terminal residues of the alpha chain are involved in the interaction with beta gamma subunits. To test the possibility that the same region in Gs may fulfill a similar function, we introduced a deletion in the amino-terminal domain of Gs alpha. The properties of the wild type and the deleted alpha chains were characterized on in vitro translated proteins or after reconstitution of cyc- membranes by in vitro-translated alpha subunits. The mutant (delta 2-29) Gs alpha could still bind guanosine 5'-3-O-(thio)triphosphate, as revealed by its resistance to trypsin proteolysis and was still able to interact with the membrane. However, (delta 2-29) Gs alpha was not ADP-ribosylated by cholera toxin. In contrast to Gs alpha, addition of beta gamma subunits did not increase the rate of sedimentation of (delta 2-29) Gs alpha in sucrose gradients. Binding experiments on reconstituted membranes showed that the coupling to beta-adrenergic receptors was very low with (delta 2-29) Gs alpha. Finally, the mutant did not restore activation of adenylate cyclase of cyc- membranes. We propose that the primary functional defect is the loss of interaction with beta gamma subunits, which secondarily impairs beta gamma-dependent properties such as receptor coupling and cholera toxin-catalyzed ADP-ribosylation. However, it remains to be established that the lack of adenylate cyclase activation also results from this impaired interaction with beta gamma subunits.     

Carbamylcholine inhibits beta-adrenergic receptor-coupled Gs protein function proximal to adenylate cyclase

The specific mechanism by which the inhibitory guanine nucleotide binding protein (Gi) mediates the inhibition of adenylate cyclase activity is still unclear. The subunit dissociation model, based on studies in purified or reconstituted systems, suggests that the beta gamma subunit, which is dissociated with activation of Gi, inhibits the function of the stimulatory guanine nucleotide binding protein (Gs) by reducing the concentration of the free alpha s subunit. In the present study, Gs protein function is determined by measuring cholera toxin-blockable, isoproterenol-induced increases in guanosine triphosphate (GTP) binding capacity to rat cardiac ventricle membrane preparations. Carbamylcholine totally inhibited this beta-adrenergic receptor-coupled Gs protein function. Pretreatment of the cardiac ventricle membrane with pertussis toxin prevented this muscarinic agonist effect. These results confirm the possibility of an inhibitory agonist-receptor coupled effect through Gi on Gs protein function proximal to the catalytic unit of adenylate cyclase in an intact membrane preparation.     

In Vivo Evidence that Lithium Inactivates Gi Modulation of Adenylate Cyclase in Brain

In vivo microdialysis of cyclic AMP from prefrontal cortex complemented by ex vivo measures was used to investigate the possibility that lithium produces functional changes in G proteins that could account for its effects on adenylate cyclase activity. Four weeks of lithium administration (serum lithium concentration of 0.85 +/- 0.05 mM; n = 11) significantly increased the basal cyclic AMP content in dialysate from prefrontal cortex of anesthetized rats. Forskolin infused through the probe increased dialysate cyclic AMP, but the magnitude of this increase was unaffected by chronic lithium administration. Inactivation of the inhibitory guanine nucleotide binding protein Gi with pertussis toxin increased dialysate cyclic AMP in control rats, as did stimulation with cholera toxin (which activates the stimulatory guanine nucleotide binding protein Gs). The effect of pertussis toxin was abolished following chronic lithium, whereas the increase in cyclic AMP after cholera toxin was enhanced. In vitro pertussis toxin-catalyzed ADP ribosylation of alpha i (and alpha o) was increased by 20% in prefrontal cortex from lithium-treated rats, but the alpha i and alpha s contents (as determined by immunoblot) as well as the cholera toxin-catalyzed ADP ribosylation of alpha s were unchanged. Taken together, these results suggest that chronic lithium administration may interfere with the dissociation of Gi into its active components and thereby remove a tonic inhibitory influence on adenylate cyclase, with resultant enhanced basal and cholera toxin-stimulated adenylate cyclase activity.     

Molecular basis for two forms of the G protein that stimulates adenylate cyclase

Most cells contain two forms of the alpha subunit of the G protein (Gs) that stimulates adenylate cyclase; their apparent molecular weights are 45,000 and 52,000. Two cDNAs that correspond to distinct mRNAs for the alpha subunit of Gs have been cloned from a bovine adrenal library and sequenced. The sequences of the two cDNAs, designated pGs-l and pGs-S, are identical except for a single stretch of 46 nucleotides in the coding region, where four are altered and 42 are deleted in pGs-S. Expression of pGs-S and pGs-l in COS-m6 cells yields protein products with apparent molecular weights of 45,000 and 52,000, respectively, based on their mobility in sodium dodecyl sulfate-polyacrylamide gels. We conclude that pGs-S and pGs-l encode the 45- and 52-kDa forms of Gs alpha, respectively, and propose that the mRNAs encoding these proteins arise from a single gene by internal alternative RNA splicing.     

Mechanism of inhibition of transducin guanosine triphosphatase activity by vanadate

The visual excitation system of the retinal rod outer segments and the hormone-sensitive adenylate cyclase complex are regulated through guanine nucleotide-binding proteins, transducin in the former and inhibitory and stimulatory regulatory components, Gi and Gs, in the latter. These proteins are functionally and structurally similar; all are heterotrimers composed of alpha, beta, and gamma subunits and exhibit guanosine triphosphatase activity stimulated by light-activated rhodopsin or the agonist-receptor complex. Adenylate cyclase can be stimulated by vanadate, which, like NaF, probably acts through Gs. Effects of vanadate on the function of a guanine nucleotide-binding protein were investigated in a reconstituted model system consisting of purified transducin subunits (T alpha, T beta gamma) and rhodopsin in phosphatidylcholine vesicles. Vanadate (decameric) inhibited [3H]GTP binding to T alpha and noncompetitively inhibited GTP hydrolysis in a concentration-dependent manner with maximal inhibition of approximately 90% at 3-5 mM. Vanadate also inhibited release of bound GDP but did not affect the rate of hydrolysis of bound GTP (single turnover rate), indicating that vanadate did not interfere with the intrinsic GTPase activity of T alpha. Binding of T alpha to rhodopsin and the ADP-ribosylation of T alpha by pertussis toxin, both of which are enhanced in the presence of T beta gamma, were inhibited by vanadate. These findings are consistent with the conclusion that vanadate can cause the dissociation of T alpha from T beta gamma, resulting in the inhibition of GDP-GTP exchange and thereby GTP hydrolysis. Adenylate cyclase activation could result from a similar effect of vanadate on Gs.     

In situ binding of a photo-affinity GTP analog to synaptic membrane G-proteins. Distribution of bound GTP analog reflects the status of adenylate cyclase

Regulation of synaptic membrane adenylate cyclase is likely to involve interaction between neurotransmitter receptors, G-proteins and the adenylate cyclase catalytic unit as well as several other membrane proteins and lipids. Despite intensive study of this system, regulation of guanine nucleotide binding by the G-proteins which stimulate [Gs] or inhibit [Gi] adenylate cyclase has been examined only when those proteins have been purified and removed from the influence of the membrane environment. The hydrolysis-resistant photoaffinity GTP-analog, P3-(4-azidoanilido)-P1 5'-GTP (AAGTP) is able to bind specifically to the G-proteins in rat cerebral cortex synaptic membranes and, in this study, we have used this probe to examine the specificity and selectivity of guanine nucleotide binding to each G-protein without removing those proteins from the synaptic membrane. Marked differences were noted between guanine nucleotide binding data obtained with detergent-soluble G-proteins and data from this in situ approach. In these studies it was found that the affinity of the G-proteins binding AAGTP correlated well with the expression of adenylate cyclase activity, the affinity of both forms of Gs increasing under conditions favoring the stimulation of that enzyme.     

Synthesis in Escherichia coli of GTPase-deficient mutants of Gs alpha

We have reduced the GTPase activity of the alpha subunit of Gs, the guanine nucleotide-binding regulatory protein that stimulates adenylyl cyclase, by introduction of point mutations analogous to those described in p21ras. Mutants G49V and Q227L differ from the wild type protein in the substitution of Val for Gly49 and Leu for Gln227, respectively (analogous to positions 12 and 61 in p21ras). Wild type and mutant proteins were synthesized in Escherichia coli, purified, and characterized. The rate constants for dissociation of GDP from G49V recombinant Gs alpha (rGs alpha) (0.47/min) and Q227L rGs alpha (0.23/min) differ by no more than 2-fold from that observed for the wild type protein (0.5/min). In marked contrast, the rate constants for hydrolysis of GTP by G49V rGs alpha (0.78/min) and Q227L rGs alpha (0.03-0.06/min) are 4-fold and roughly 100-fold slower than that for wild type rGs alpha (3.5/min). These reductions in the rate of hydrolysis of GTP result in significant fractional occupancy of these proteins by GTP in the presence of the nucleotide, 0.37 for G49V rGs alpha and 0.78 for Q227L rGs alpha, compared to 0.05 for wild type rGs alpha. When reconstituted with cyc- (Gs alpha-deficient) S49 cell membranes or purified adenylyl cyclase, both mutant proteins stimulate adenylyl cyclase activity in the presence of GTP to a much greater extent than does wild type Gs alpha; their maximal ability to activate the enzyme is largely unaltered. The fractional ability of a given Gs alpha polypeptide to active adenylyl cyclase in the presence of GTP correlates well with the fractinal occupancy of the protein by the nucleotide. The mutant subunits appear to interact normally with G protein beta gamma subunits, and their ability to activate adenylyl cyclase is enhanced by interaction with beta-adrenergic receptors. These results indicate that the structural analogy that has been inferred between the guanine nucleotide-binding domains of G proteins and the p21ras family is at least generally correct. They also provide confirmation of the kinetic model of G protein function and document mutations that permit the expression in vivo of constitutively activated G protein alpha subunits.     

Antibodies directed against transducin beta subunits interfere with the regulation of adenylate cyclase activity in brain membranes

In an attempt to study the mechanisms of action of membrane-bound adenylate cyclase, we have applied to rat brain synaptosomal membranes antibodies raised against purified bovine transducin (T) beta gamma subunits. The antibodies recognized one 36-kDa protein in Western blots of the membranes. Adenylate cyclase activation by GTP non-hydrolyzable analogues was greatly decreased in immune, as compared to preimmune, antibody-treated membranes, whereas the enzyme basal activity was unaffected by both types of antibodies. The inhibition of forskolin-stimulated adenylate cyclase by guanine 5'-(beta, gamma-imino)triphosphate (Gpp-(NH)p) was decreased in membranes preincubated with immune, but not preimmune, antibodies. Anti-T beta antibodies moderately decreased the extent of subsequent adenylate cyclase activation by forskolin, while not affecting activation by Al3+/F-. The enzyme activation by Gpp(NH)p in untreated membranes remained the same upon further incubation in the presence of either type of antibodies. Such results were consistent with the decreased exchange of guanine nucleotides which occurred in membrane treated with immune, but not preimmune antibodies, upon addition of GTP. The blockade of the regulation of adenylate cyclase by Gpp(NH)p observed in membranes pretreated by anti-T beta antibodies thus appears to be caused by the impairment of the guanine nucleotide exchange occurring on Gs alpha subunits. The G beta subunits in the adenylate cyclase complex seem to be instrumental in the guanine nucleotide exchange on G alpha subunits, just as T beta subunits are in the transducin complex.