Functional reconstitution of prostaglandin E receptor from bovine adrenal medulla with guanine nucleotide binding proteins

Prostaglandin E2 (PGE2) was found to bind specifically to a 100,000 x g pellet prepared from bovine adrenal medulla. The PGE receptor was associated with a GTP-binding protein (G-protein) and could be covalently cross-linked with this G-protein by dithiobis(succinimidyl propionate) in the 100,000 x g pellet (Negishi, M., Ito, S., Tanaka, T., Yokohama, H., Hayashi, H., Katada, T., Ui, M., and Hayaishi, O. (1987) J. Biol. Chem. 262, 12077-12084). In order to characterize the G-protein associated with the PGE receptor and reconstitute these proteins in phospholipid vesicles, we purified the G-protein to apparent homogeneity from the 100,000 x g pellet. The G-protein served as a substrate of pertussis toxin but differed in its alpha subunit from two known pertussis toxin substrate G-proteins (Gi and Go) purified from bovine brain. The molecular weight of the alpha subunit was 40,000, which is between those of Gi and Go. The purified protein was also distinguished immunologically from Gi and Go and was referred to as Gam. PGE receptor was solubilized by 3-[(3-cholamidopropyl)dimethylammonio]-1-propanesulfonic acid and freed from G-proteins by wheat germ agglutinin column chromatography. Reconstitution of the PGE receptor with pure Gam, Gi, or Go in phospholipid vesicles resulted in a remarkable restoration of [3H]PGE2 binding activity in a GTP-dependent manner. The efficiency of these three G-proteins in this capacity was roughly equal. When pertussis toxin- or N-ethylmaleimide-treated G-proteins, instead of the native ones, were reconstituted into vesicles, the restoration of binding activity was no longer observed. The displacement of [3H]PGE2 binding was specific for PGE1 and PGE2. Furthermore, addition of PGE2 stimulated the GTPase activity of the G-proteins in reconstituted vesicles. These results indicate that the PGE receptor can couple functionally with Gam, Gi, or Go in phospholipid vesicles and suggest that Gam may be involved in signal transduction of the PGE receptor in bovine adrenal medulla.     

Brain somatostatin receptor-G protein interaction. G alpha C-terminal antibodies demonstrate coupling of the soluble receptor with Gi(1-3) but not with Go.

Somatostatin (SST) receptors activate potassium channels, stimulate protein phosphatases, inhibit adenylate cyclase and close calcium channels. These multiple effects are controlled by guanine nucleotide binding (G) proteins of the pertussis toxin-sensitive Gi and Go types. In the present study we have identified the G proteins coupling with brain SST receptors. To this end, brain SST receptors were solubilized in G-protein coupled form. Binding of the SST analogue MK 678 to the solubilized receptor was completely inhibited by guanosine 5'-O-thiotriphosphate (IC50 = 100 nM), reflecting decreased receptor affinity for agonist following uncoupling of the receptor and G protein(s). Antibodies raised against specific COOH-terminal peptides of the G proteins Gi(1-3), Go, and Gz were used to probe for SST receptor-G protein coupling in this system. Antibodies binding to the COOH-terminal regions of Gi1 and Gi2 (antibody AS) and Gi3 (antibody EC) inhibited binding of 125I-MK 678 (75 pM) by 57 +/- 4% and 48 +/- 5%, respectively. The effects of these antibodies were concentration-dependent and additive, such that in combination AS and EC completely inhibited binding. Antibodies binding to the COOH-terminal region of Go (GO) and Gz (QN) did not affect binding of 125I-MK 678, indicating that neither Go nor Gz are associated with the brain SST receptor. Prelabeling of the receptor with 125I-MK 678 prior to addition of antibody induced the formation of a "locked conformation" of the agonist-bound receptor-G protein complex which was insensitive to antibody. In conclusion, Gi1 and/or Gi2 and Gi3 are coupled in approximately equal proportions to the brain 125I-MK 678-binding SST receptor, accounting for all of the G protein coupling of this receptor.     

Reconstitution of resolved muscarinic cholinergic receptors with purified GTP-binding proteins

The association of agonists with muscarinic receptors in membranes from bovine brain was affected only slightly by guanine nucleotides. However, solubilization of these membranes with deoxycholate and subsequent removal of detergent resulted in a preparation of receptors with increased affinity for agonists and a large increase in response to guanine nucleotides. Chromatography of deoxycholate extracts of membranes on DEAE-Sephacel resulted in the separation of receptors from 95% of the guanine nucleotide-binding activity. Guanine nucleotides had no effect on the binding of agonists to these resolved receptors. The effect of guanine nucleotides was restored after the addition of either of two purified guanine nucleotide-binding proteins from bovine brain. One of these proteins, presumably brain GI, is composed of subunits with the same molecular weights (alpha, 41,000; beta, 35,000; gamma, 11,000) and functions as the inhibitory guanine nucleotide-binding protein isolated from liver. The other protein, termed Go, is a novel guanine nucleotide-binding protein that possesses a similar subunit composition (alpha, 39,000; beta, 35,000; gamma, 11,000) but whose function is not yet known. Addition of either protein to the resolved receptor preparation increased agonist affinity by at least 10-20-fold, and low concentrations of guanine nucleotides specifically reversed this effect. Reconstitution of receptors with the resolved subunits of Go demonstrates that the beta subunit alone had no effect on agonist binding, but that this subunit does appear to enhance the effects observed with the alpha subunit alone.     

Purification and characterization of predominant G-protein from bovine lung membranes. Biochemical and immunochemical comparison with Gi1 and Go purified from brain.

The predominant guanine nucleotide-binding protein (G-protein) of bovine lung membranes, termed GL, has been purified and compared biochemically, immunochemically and functionally with Gi and Go purified from rabbit brain. The purified GL appeared to have a similar subunit structure to Gi and Go, being composed of alpha, beta and possibly gamma subunits. On Coomassie Blue-stained SDS/polyacrylamide gels and immunoblots, the alpha subunit of GL (GL alpha) displayed an intermediate mobility (40 kDa) between those of Gi and Go (Gi alpha and Go alpha). GL alpha was [32P]ADP-ribosylated in the presence of pertussis toxin and [32P]NAD+. Analysis of [32P]ADP-ribosylated alpha subunits by SDS/polyacrylamide-gel electrophoresis and isoelectric focusing showed that GL alpha was distinct from Gi alpha and Go alpha, but very similar to the predominant G-protein in neutrophil membranes. Immunochemical characterization also revealed that GL was distinct from Gi and Go, but was indistinguishable from the G-protein of neutrophils, which has been tentatively identified as Gi2 [Goldsmith, Gierschik, Milligan, Unson, Vinitsky, Maleck & Spiegel (1987) J. Biol. Chem. 262, 14683-14688]. In functional studies, higher Mg2+ concentrations were required for guanosine 5'-[gamma-[35S]thio]triphosphate (GTP[35S]) binding to GL than were required for nucleotide binding to Go, whereas Gi showed a Mg2+-dependence similar to that of GL. The kinetics of GTP[35S] binding to GL was quite different from those of Gi and Go; t1/2 values of maximal binding were 30, 15 and 5 min respectively. In contrast, the rate of hydrolysis of [gamma-32P]GTP by GL (t1/2 approximately 1 min) was approx. 4 times faster than that by Gi or Go. These results indicated that the predominant G-protein purified from lung is structurally and functionally distinct from Gi and Go of brain, but structurally indistinguishable from Gi2 of neutrophils.     

Major pertussis-toxin-sensitive GTP-binding protein of bovine lung. Purification, characterization and production of specific antibodies

Two GTP-binding proteins which can be ADP-ribosylated by islet-activating protein, pertussis toxin, were purified from the cholate extract of bovine lung membranes. Both proteins had the same heterotrimeric structure (alpha beta gamma), but the alpha subunits were dissociated from the beta gamma when they were purified in the presence of AlCl3, MgCl2 and NaF. The molecular mass of the alpha subunit of the major protein (designated GLu, with beta gamma) was 40 kDa and that of the minor one was 41 kDa. The results of peptide mapping analysis of alpha subunits with a limited proteolysis indicated that GLu alpha was entirely different from the alpha of brain Gi or Go, while the 41-kDa polypeptide was identical with the alpha of bovine brain Gi. The kinetics of guanosine 5'-[3-O-thio]triphosphate (GTP[gamma S]) binding to GLu was similar to that to lung Gi but quite different from that to brain Go. On the other hand, incubation of GLu alpha at 30 degrees C caused a rapid decrease of GTP[gamma S] binding, the inactivation curve being similar to that of Go alpha but different from that of Gi alpha. The alpha subunits of lung Gi and GLu did not react with the antibodies against the alpha subunit of bovine brain Go. The antibodies were raised in rabbits against GLu alpha and were purified with a GLu alpha-Sepharose column. The purified antibodies reacted not only with GLu alpha but also with the 41-kDa protein and purified brain Gi alpha. However, the antibodies adsorbed with brain Gi alpha reacted only with GLu alpha, indicating antisera raised with GLu alpha contained antibodies that recognize both Gi alpha and GLu alpha, and those specific to GLu alpha. These results further indicate that GLu is different from Gi or Go. Anti-GLu alpha antibodies reacted with the 40-kDa proteins in the membranes of bovine brain and human leukemic (HL-60) cells. The beta gamma subunits were also purified from bovine lung. The beta subunit was the doublet of 36-kDa and 35-kDa polypeptides. The lung beta gamma could elicit the ADP-ribosylation of GLu alpha by islet-activating protein, increase the GTP[gamma S] binding to GLu and protect the thermal denaturation of GLu alpha. The antibodies raised against brain beta gamma cross-reacted with lung beta but not with lung gamma.     

Chronic Membrane Depolarization Regulates the Level of the Guanine Nucleotide Binding Protein Goα in Cultured Neuronal Cells

Chronic membrane depolarization results in an increase in muscarinic acetylcholine receptor (mAChR) number in N1E-115 neuroblastoma cells. Because the mAChR interacts with the guanine nucleotide binding regulatory (G) proteins, Gi and Go, the effect of chronic membrane depolarization on the levels of subunits of these G proteins was examined. Quantitation of G protein subunit levels was performed using affinity-purified, monospecific antibodies in a quantitative immunoblot assay. Incubation with 50 microM veratridine (VTN), an activator of voltage-sensitive Na+ channels, induced a 48 +/- 15% increase in the level of the alpha subunit of Go. The effect of VTN was blocked by tetrodotoxin. On removal of VTN, the level of Go alpha decreased to control levels within 24 h. The levels of the alpha subunit of Gi and the common beta subunit were not affected by VTN treatment. These results show that in N1E-115 cells, the level of the alpha subunit of Go is regulated in a manner similar to the level of mAChR in response to chronic membrane depolarization.     

A new GTP-binding protein in differentiated human leukemic (HL-60) cells serving as the specific substrate of islet-activating protein, pertussis toxin

A GTP-binding protein serving as the specific substrate of islet-activating protein (IAP), pertussis toxin, was partially purified from human leukemic (HL-60) cells that had been differentiated into neutrophil type. The partially purified protein, referred to as GHL, predominantly consisted of at least two polypeptides with molecular masses of 40,000 daltons (alpha) and 36,000 or 35,000 daltons (beta). The structure was similar to Gi or Go previously purified from rat brain as an alpha beta gamma-heterotrimeric IAP substrate (Katada, T., Oinuma, M., and Ui, M. (1986) J. Biol. Chem. 261, 8182-8191), although the existence of the gamma of GHL was unclear. The 40,000-dalton polypeptide contained the site for IAP-catalyzed ADP-ribosylation and the binding site for guanine nucleotide with a high affinity. The 36,000- and 35,000-dalton polypeptides were cross-reacted with the affinity-purified antibody raised against the beta of brain Gi and Go. Limited proteolysis with trypsin and immunoblot analyses with the use of the affinity-purified antibodies raised against the alpha of brain Gi or Go indicated that the alpha of GHL was different from the alpha of Gi or Go. Kinetics of guanosine 5'-(3-O-thio)triphosphate (GTP gamma S) binding to GHL was also quite different from that to brain Gi or Go. Incubation of GHL with GTP gamma S resulted in a resolution into GTP gamma S-bound alpha and beta(gamma) thus purified had abilities to inhibit a membrane-bound adenylate cyclase activity and to associate with the alpha of brain IAP substrate in a fashion similar to the beta gamma of brain IAP substrates, suggesting that there were no significant differences in the biological activities between the beta(gamma) of GHL and those of Gi or Go. Physiological roles of the new GTP-binding protein, GHL, purified from the neutrophil-like cells in receptor-mediated signal transduction are discussed.     

Identification of lung major GTP-binding protein as Gi2 and its distribution in various rat tissues determined by immunoassay

Antisera were raised in rabbits against the 40-kDa alpha subunit of bovine lung GTP-binding protein, which were identified as the alpha subunit of Gi2 (Gi2 alpha) by the analysis of the partial amino acid sequence. Antibodies were purified with a Gi2 alpha-coupled Sepharose column and then were passed through a Gi1 alpha-coupled Sepharose column to remove antibodies reactive also with 41-kDa alpha. Purified antibodies reacted with Gi2 alpha, but not with Gi1 alpha, Gi3 alpha, or Go alpha in an immunoblot assay. A sensitive enzyme immunoassay method for the quantification of Gi2 alpha was developed by using these purified antibodies. The assay system consisted of polystyrene balls with immobilized antibody F(ab')2 fragments and the same antibody Fab' fragments labeled with beta-D-galactosidase from Escherichia coli. The minimal detection limit of the assay was 1 fmol, or 40 pg. Samples from various tissues were solubilized with 2% sodium cholate and 1 M NaCl, and the concentrations of Gi2 alpha were determined. Gi2 alpha was detected in all the tissues examined in the rat. The highest concentration was found in platelets and leukocytes when the data were expressed as picomoles per milligram of protein. The spleen, lung, and cerebral cortex contained relatively high levels of Gi2 alpha. In the bovine brain, Gi2 alpha was distributed almost uniformly among the various regions. The concentrations of Gi2 alpha were constant in the rat brain throughout ontogenic development, in contrast with those of Go alpha which were markedly increased with age.     

Highly Sensitive Immunoassay for the α Subunit of the GTP-Binding Protein Go and Its Regional Distribution in Bovine Brain

Antisera were raised in rabbits against the alpha subunit of a GTP-binding protein, Go. Because the antisera cross-reacted weakly with the alpha subunit of inhibitory GTP-binding protein of adenylate cyclase (Gi), they were purified with a Go alpha-coupled Sepharose column. Purified antibodies reacted only with Go alpha and did not cross-react with the Gi alpha subunit or beta gamma subunits in an immunoblot assay. Using these purified antibodies, a highly sensitive enzyme immunoassay method for the quantification of bovine brain Go alpha was developed. The assay system consisted of polystyrene balls with immobilized antibody F(ab')2 fragments and the same antibody Fab' fragments labeled with beta-D-galactosidase from Escherichia coli. The minimal detection limit of the assay was 0.1 fmol, or 4 pg. The assay was specific for Go alpha, and it did not cross-react with Gi alpha or beta gamma. Samples from various regions of bovine brain were solubilized with 2% sodium cholate and 1 M NaCl, and the concentrations of Go alpha were determined. Go alpha was detected in all the regions, and the highest concentration was observed in the cerebral cortex. The immunohistochemical study showed that the neuropil was rich in Go alpha.     

Comparative analysis of the efficacy of A1 adenosine receptor activation of Gi/o alpha G proteins following coexpression of receptor and G protein and expression of A1 adenosine receptor-Gi/o alpha fusion proteins

HEK293T cells were transiently transfected to express either the human A1 adenosine receptor together with pertussis toxin-resistant cysteine-to-glycine forms of the alpha subunits of Gi1 (C351G), Gi2 (C352G), and Gi3 (C351G) and wild-type Go1alpha or fusion proteins comprising the A1 adenosine receptor and these Gi/o G proteins to compare A1 adenosine receptor agonist-mediated activation of these Gi family G proteins upon coexpression of individual Gi/o G proteins and receptor versus expression as receptor-G protein fusion proteins. Addition of the adenosine receptor agonist 5'-N-ethylcarboxamidoadenosine (NECA) to membranes of pertussis toxin-treated cells resulted in a concentration-dependent stimulation of [35S]GTPgammaS binding with comparable amounts of NECA required to produce half-maximal stimulation following transfection of A1 adenosine receptor and Gi/o G proteins either as fusion proteins or as separate polypeptides. However, the magnitude of agonist-mediated activation of GTPgammaS binding was greatly enhanced by expressing the A1 adenosine receptor and Gi family G proteins from chimaeric open reading frames. This observation was consistent following the study of more than 40 agonists. No preferential activation of any G protein was observed with more than 40 A1 receptor agonists following cotransfection of receptor with G protein or transfection of receptor-G protein fusion proteins. These studies demonstrate the utility of using fusion proteins to study receptor-G protein interaction, show that the A1 adenosine receptor couples equally well to the Gi/o G proteins Gi1alpha, G i2alpha, Gi3alpha, and Go1alpha, and demonstrate that for a range of agonists there is no selectivity for activation of any particular A1 adenosine receptor-Gi/o G protein combination.     

G protein beta gamma subunits synthesized in Sf9 cells. Functional characterization and the significance of prenylation of gamma.

Heterotrimeric guanine nucleotide-binding regulatory proteins (G proteins) consist of a nucleotide-binding alpha subunit and a high-affinity complex of beta and gamma subunits. There is molecular heterogeneity of beta and gamma, but the significance of this diversity is poorly understood. Different G protein beta and gamma subunits have been expressed both singly and in combinations in Sf9 cells. Although expression of individual subunits is achieved in all cases, beta gamma subunit activity (support of pertussis toxin-catalyzed ADP-ribosylation of rGi alpha 1) is detected only when beta and gamma are expressed concurrently. Of the six combinations of beta gamma tested (beta 1 or beta 2 with gamma 1, gamma 2, or gamma 3), only one, beta 2 gamma 1, failed to generate a functional complex. Each of the other five complexes has been purified by subunit exchange chromatography using Go alpha-agarose as the chromatographic matrix. We have detected differences in the abilities of the purified proteins to support ADP-ribosylation of Gi alpha 1; these differences are attributable to the gamma component of the complex. When assayed for their ability to inhibit calmodulin-stimulated type-I adenylylcyclase activity or to potentiate Gs alpha-stimulated type-II adenylylcyclase, recombinant beta 1 gamma 1 and transducin beta gamma are approximately 10 and 20 times less potent, respectively, than the other complexes examined. Prenylation and/or further carboxyl-terminal processing of gamma are not required for assembly of the beta gamma subunit complex but are indispensable for high affinity interactions of beta gamma with either G protein alpha subunits or adenylylcyclases.     

Expression of Go alpha mRNA and protein in bovine tissues

Go alpha is a 39-kDa guanine nucleotide-binding protein (G protein) similar in structure and function to Gs alpha and Gi alpha of the adenylate cyclase complex and to transducin (Gt alpha) of the retinal photon receptor system. Although expression of Go alpha protein has been reported to be tissue-specific, other workers have found Go alpha mRNA in all rat tissues examined. In order to clarify this contradiction, studies to verify the distribution of Go alpha mRNA and protein in bovine and rat tissues were performed. Tissues were screened for the presence of Go alpha mRNA by use of a series of restriction fragments of a bovine retinal cDNA clone, lambda GO9, and oligonucleotide probes complementary to sequences specific among G alpha subunits for the 5' untranslated and coding regions of Go alpha. These probes hybridized predominantly with mRNA of 4.0 and 3.0 kb in bovine brain and retina. A 2.0-kb mRNA in retina also hybridized strongly with the cDNA but weakly with the oligonucleotide probes. In bovine lung, two mRNAs of 1.6 and 1.8 kb hybridized with the cDNA while only the 1.6-kb species hybridized with the coding-region oligonucleotide. In bovine heart, only a 4.0-kb mRNA was detected and in amounts much less than those in the other tissues. A similar distribution of Go alpha mRNAs was seen in rat tissues. In bovine tissues, Go alpha protein was identified with rabbit polyclonal antibodies directed against purified bovine brain Go alpha. An immunoreactive 39-kDa membrane protein was found principally in retina and brain, and in a lesser amount in heart.(ABSTRACT TRUNCATED AT 250 WORDS)     

Modification of Brain Guanine Nucleotide-Binding Regulatory Proteins by Tryptamine-4,5-Dione, a Neurotoxic Derivative of Serotonin

We have recently characterized a novel oxidation product of serotonin (5-hydroxytryptamine, 5-HT), tryptamine-4,5-dione, which increases 5-HT efflux from striatum and hippocampus and causes selective neuronal death. Exposure of striatal synaptosomes or the major brain guanine nucleotide-binding regulatory proteins Gi and Go to [3H]tryptamine-4,5-dione resulted in the radiolabeling of a major band with an apparent molecular mass equivalent to that of the alpha subunits of Gi and Go (approximately 40,000). The binding of [35S]guanosine-5'-O-(3-thiotriphosphate) ([35S]GTP-gamma-S) to Gi and Go and pertussis toxin-catalyzed [32P]ADP-ribosylation of the G protein alpha subunits were both inhibited in a dose-dependent manner by tryptamine-4,5-dione. Thus, neurotoxins such as tryptamine-4,5-dione may exert their effects through specific interactions with G proteins.     

Immunochemical and immunohistochemical localization of the G protein Gi1 in rat central nervous tissues

Antisera were raised in rabbits against purified alpha subunit of G protein Gi1 (Gi1 alpha) and also against a synthetic decapeptide corresponding to a sequence of Gi1 alpha. Antibodies in both antisera were purified with a Gi1-coupled Sepharose column, but purified anti-Gi1 alpha protein antibodies still reacted equally with both Gi1 alpha and Gi3 alpha, while anti-Gi1 alpha peptide antibodies reacted principally with Gi1 alpha. Using these antibodies, an enzyme immunoassay method for the quantification of Gi1 alpha was developed. The assay system consisted of polystyrene balls with immobilized anti-Gi1 alpha protein antibody F(ab')2 fragments and the anti-Gi1 alpha peptide antibody Fab' fragments labeled with beta-D-galactosidase from Escherichia coli. The minimum detection limit of the assay was 25 fmol of Gi1 alpha, and it did not cross-react with Gi2 alpha, Go alpha, or beta gamma. Samples from various regions of the rat central nervous system were homogenized in a 2% sodium cholate solution, and the concentration of Gi1 alpha in each extract was determined. Gi1 alpha was detected in all the regions, and the highest concentration was found in the olfactory bulb. Immunohistochemical study showed that Gi1 was mainly localized in the neuropil.     

Chronic Exposure of NG 108-15 Cells to Opiate Agonists Does Not Alter the Amount of the Guanine Nucleotide-Binding Proteins Gi and GO

We have characterized the pertussis toxin substrate in NG 108-15 cell membranes using site-specific antisera and ADP-ribosylation. Cell membranes contain two pertussis toxin-sensitive guanine nucleotide-binding protein alpha-subunits (G alpha) whose Rf values in gel electrophoresis coincide with those of G alpha o and G alpha i2. The total quantity of Gi and Go immunoreactivity amounted to 24.3 +/- 2.8 pmol/mg, whereas only 1.5 +/- 0.2 pmol/mg are capable of undergoing ADP-ribosylation catalyzed by pertussis toxin. Pretreatment of cells with the agonist [D-Ala2,D-Leu2]-enkephalin (DADLE) for 24 h and DADLE or morphine for 72 h did not alter the incorporation of ADP-ribose or the immunoreactive amount of Gi and Go subunits. However, pretreatment for 72 h with naloxone increased the incorporation of ADP-ribose without an apparent change in affinity or in the immunochemically determined protein levels of Gi and Go. This indicates that the process of down-regulation and desensitization of the delta-opioid receptor neither requires quantitative alterations in the levels of Gi and Go nor changes in the degree of coupling among their subunits. In contrast, chronic exposure to antagonists seems to alter the degree of precoupling between alpha- and beta-subunits of Gi and/or Go.     

A1 adenosine receptors of bovine brain couple to guanine nucleotide-binding proteins Gi1, Gi2, and Go

A1 adenosine receptors and associated guanine nucleotide-binding proteins (G proteins) were purified from bovine cerebral cortex by affinity chromatography (Munshi, R., and Linden, J. (1989) J. Biol. Chem. 264, 14853-14859). In this study we have identified the pertussis toxin-sensitive G protein subunits that co-purify with A1 adenosine receptors by immunoblotting with specific antipeptide antisera. Gi alpha 1, Gi alpha 2, Go alpha, G beta 35, and G beta 36 were detected. Of the total [35S]guanosine 5'-O-(3-thio)triphosphate [( 35S]GTP gamma S) binding sites, Gi alpha 1 and Go alpha each accounted for greater than 37% whereas Gi alpha 2 comprised less than 13%. G beta 35 was found in excess over G beta 36. Low molecular mass (21-25 kDa) GTP-binding proteins were not detected. We also examined the characteristics of purified receptors and various purified bovine brain G proteins reconstituted into phospholipid vesicles. All three alpha-subunits restored GTP gamma S-sensitive high affinity binding of the agonist 125I-aminobenzyladenosine to a fraction (25%) of reconstituted receptors with a selectivity order of Gi2 greater than Go greater than or equal to Gi1 (ED50 values of G proteins measured as fold excess over the receptor concentration were 4.7 +/- 1.2, 24 +/- 5, and 34 +/- 7, respectively). Furthermore, receptors occupied with the agonist R-phenylisopropyladenosine catalytically increased the rate of binding of [35S]GTP gamma S to reconstituted G proteins by 6.5-8.5-fold. These results suggest that A1 adenosine receptors couple indiscriminately to pertussis toxin-sensitive G proteins.     

G protein betagamma11 complex translocation is induced by Gi, Gq and Gs coupling receptors and is regulated by the alpha subunit type

G protein activation by Gi/Go coupling M2 muscarinic receptors, Gq coupling M3 receptors and Gs coupling beta2 adrenergic receptors causes rapid reversible translocation of the G protein gamma11 subunit from the plasma membrane to the Golgi complex. Co-translocation of the beta1 subunit suggests that gamma11 translocates as a betagamma complex. Pertussis toxin ADP ribosylation of the alphai subunit type or substitution of the C terminal domain of alphao with the corresponding region of alphas inhibits gamma11 translocation demonstrating that alpha subunit interaction with a receptor and its activation are requirements for the translocation. The rate of gamma11 translocation is sensitive to the rate of activation of the G protein alpha subunit. alpha subunit types that show high receptor activated rates of guanine nucleotide exchange in vitro support high rates of gamma11 translocation compared to alpha subunit types that have a relatively lower rate of guanine nucleotide exchange. The results suggest that the receptor induced translocation of gamma11 is controlled by the rate of cycling of the G protein through active and inactive forms. They also demonstrate that imaging of gamma11 translocation can be used as a non-invasive tool to measure the relative activities of wild type or mutant receptor and alpha subunit types in a live cell.     

Specificity of receptor-G protein interactions. Discrimination of Gi subtypes by the D2 dopamine receptor in a reconstituted system

The selectivity of D2 dopamine receptor-guanine nucleotide-binding protein (G protein) coupling was studied by reconstitution techniques utilizing purified D2 dopamine receptors from bovine anterior pituitary and resolved G proteins from bovine brain, bovine pituitary, and human erythrocyte. Titration of a fixed receptor concentration with varying G protein concentrations revealed two aspects of receptor-G protein coupling. First, Gi2 appeared to couple selectively with the D2 receptor with approximately 10-fold higher affinity than any other tested Gi subtype. Second, the G proteins differed in the maximal receptor-mediated agonist stimulation of the intrinsic GTPase activity. Gi2 appeared to be maximally stimulated by agonist-receptor complex with turnover numbers of approximately 2 min-1. The other Gi subtypes, Gi1 and Gi3, could be only partially activated, resulting in maximal rates of GTPase of approximately 1 min-1. Agonist-stimulated GTPase activity was not detected in preparations containing Go from bovine brain. The differences in maximal agonist-stimulated GTPase rates observed among the Gi subtypes could be explained by differences in agonist-promoted guanyl nucleotide exchange. Both guanosine 5'-3-O-(thio)triphosphate (GTP gamma S) binding and GDP release parameters were enhanced 2-fold for the Gi2 subtype over the other Gi subtypes. These results suggest that even though several types of pertussis toxin substrate may exist in most tissues, a receptor may interact discretely with G proteins, thereby dictating signal transduction mechanisms.     

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.     

Go, a major brain GTP binding protein in search of a function: purification, immunological and biochemical characteristics

The GTP-binding proteins involved in signal transduction now constitute a large family of so called 'G proteins'. Among them, Gs and Gi mediate the stimulation and inhibition of adenyl cyclase, respectively. Recently, another G protein (Go) abundant in brain was purified, but its function is still unknown. Like other G proteins, Go is a heterotrimer (alpha, beta, gamma) and the beta-gamma subunits seem to be identical to those of Gs and Gi. The alpha subunit of Go (Go-alpha) has a molecular weight of 39 kDa lower than those of Gi (41 kDa) or Gs (45-52 kDa). A positive immunoreativity with antibodies against Go-alpha was found in peripheral nervous tissues, adrenal medulla, heart, adenohypophysis and adipocytes. Go ressembles Gi in its ability to be ADP-ribosylated by pertussis toxin, and sequence analysis reveals a 68% homology between their alpha subunits. The GTPase activity of Go is several times higher than that of Gi. The affinity of the beta-gamma entity is about 3 times higher for Gi than for Go. In reconstitution studies, Go does not mimic the inhibitory effect of Gi on adenyl cyclase-stimulated by Gs. On the contrary, Go is as efficient as Gi in reconstituting the functional coupling with the muscarinic, alpha 2-adrenergic and chemotactic agent f-Met-Leu-Phe (fMLP), receptors. Recent studies seem to rule out Go as the coupling G protein of phospholipase C, the enzyme involved in phosphatidyl inositol trisphosphate hydrolysis. However, Go remains a putative candidate for transduction mechanisms coupled to a potassium channel or to a voltage-dependent calcium channel.