G-protein mRNA levels during adipocyte differentiation

G-protein-mediated transmembrane signaling in 3T3-L1 cells is modulated by differentiation. The regulation of G-protein expression in differentiating 3T3-L1 cells was probed at the level of mRNA by DNA-excess solution hybridization. Pertussis toxin-catalyzed ADP-ribosylation of G-protein alpha-subunits increased as fibroblasts differentiate to adipocytes. Steady-state levels of mRNA for Gi alpha 2 and Go alpha, in contrast, declined sharply. Immunoblotting with antipeptide antibodies specific for Gi alpha 2, too, revealed a decline in the steady-state expression of this pertussis toxin substrate. ADP-ribosylation of Gs alpha by cholera toxin was less in the adipocyte than fibroblast. Analysis by immunoblotting revealed only a modest decline in Gs alpha. Analysis of mRNA levels also demonstrated a decline for Gs alpha. mRNA levels for the G beta-subunits rose initially (25%) on day 1, declined from day 1 to day 3, and remained 25% lower in adipocytes than in fibroblasts. In 3T3-L1 adipocytes the molar amounts of subunit mRNAs were: 60.6 (Gs alpha); 2.1 (Gi alpha 2); and 1.5 (Go alpha) amol/microgram total cellular RNA. In rat fat cells these mRNA levels were 19.4 (Gs alpha); 7.0 (Gi alpha 2); and 2.3 (Go alpha). These data demonstrate that for Gi alpha 2 and Go alpha alike mRNA and protein expression decrease, not increase, in differentiation. A substrate for pertussis toxin other than Gi alpha 2 and Go alpha appears to be responsible for the increase in toxin-catalyzed labeling that accompanies differentiation of 3T3-L1 cells.     

Thyroid hormones regulate G-protein beta-subunit mRNA expression in vivo

Thyroid hormones exert "permissive effects" on the hormone-sensitive adenylate cyclase. Regulation of the expression of Gi (Gi alpha 2) and Gs by thyroid hormones in vivo was investigated at the level of mRNA. Steady-state levels of the mRNA for Gi alpha 2 and Gs alpha, as well as the G beta-subunits, were quantified using DNA excess solution hybridization analysis. Regulation of protein and mRNA expression in adipose tissue was investigated in hypothyroid, euthyroid, and hyperthyroid rats. In euthyroid animals, steady-state levels of mRNA (amol/microgram RNA) were 13.8, 5.9, and 5.7 for Gs alpha, Gi alpha 2, and G beta 1,2, respectively. Activation of adenylate cyclase by Gs is unaffected by thyroid status. Both Gs alpha and Gs alpha mRNA levels in hypothyroid rats were the same as those of controls (euthyroid). The inhibitory control of adenylate cyclase, in contrast, is markedly potentiated in hypothyroid rats. The expression of G1 alpha s and G beta-subunits was increased in hypothyroidism. Whereas Gi alpha 2 mRNA levels remained essentially unchanged, G beta 1,2 mRNA levels were observed to increase 45% in the hypothyroid state. In the hyperthyroid state G beta 1,2 mRNA levels were observed to decline by 35%. Regulation of G-protein subunit expression, at the level of mRNA, appears to be one component of permissive hormone action on transmembrane signalling.     

Cholera toxin differentially decreases membrane levels of alpha and beta subunits of G proteins in NG108-15 cells

Treatment of NG108-15 neuroblastoma x glioma cells (24 h) with cholera toxin (0.1-10 micrograms/ml) resulted in a concentration-dependent reduction of the membrane levels of subunits of GTP-binding regulatory proteins (G proteins), as determined by quantitative immunoblot procedures. The extent of reduction differed for different types of subunits: the levels of Go alpha and G beta 1 were reduced by 40-50%, whereas those of G alpha common immunoreactivity and Gi2 alpha were only reduced by 10-20% following treatment with 10 micrograms/ml cholera toxin. This effect of the toxin could not be mimicked by incubation with the resolved B oligomer of cholera toxin, nor by exposure of cells to agents able to raise the intracellular levels of cAMP. Basal adenylate cyclase was stimulated in a biphasic manner by cholera toxin, being stimulated at low concentrations (0.01-10 ng/ml) and then decreased at high (0.1-10 micrograms/ml) concentrations. Thus, the down regulation of G-protein subunits produced by cholera toxin requires its (ADP-ribosyl)transferase activity but does not result from a cAMP-mediated mechanism. The toxin-mediated decrease of Go alpha in the membrane was correlated with a diminution of opioid-receptor-mediated stimulation of high-affinity GTPase activity, suggesting that opioid receptors interact with Go in native membranes of NG108-15 cells. Northern-blot analysis of cytoplasmic RNA prepared from cells treated with cholera toxin showed that the levels of mRNA coding for G beta 1 did not change. Thus, the cholera-toxin-induced decrease of G-protein subunits may not result from an alteration in mRNA levels, but may involve a direct effect of the toxin on the process of insertion and/or clearance of G proteins into and/or from the membrane. These data indicate that cholera toxin, besides catalyzing the ADP-ribosylation of Gs and Gi/Go types of G proteins, can also reduce the steady state levels of Go alpha and G beta 1 subunits in the membrane and thus alter by an additional mechanism the function of inhibitory receptor systems.     

Localization of mRNAs encoding the alpha-subunits of signal-transducing G-proteins within rat brain and among peripheral tissues

The sequence of the mRNAs which encode the alpha-subunits of the signal-transducing G-proteins Gs, Go and two forms of Gi (termed Gi1 and Gi2) have recently been reported. Based on rat sequences we prepared oligodeoxynucleotide probes for measurement of these mRNAs in rat brain and peripheral tissues. The relative abundance of these mRNA species in brain was Gs greater than Go approximately Gi2 greater than Gi1. The Gs and Gi2 mRNAs had somewhat lower levels in heart, kidney and liver than in brain, and Go and Gi1 mRNAs were not detected in the peripheral tissues. Using in situ hybridization we localized each of these mRNAs within slices of the rat brain. The patterns of distribution of Gs and Gi2 mRNA were very similar, but very different from that of Go and Gi1 mRNA. These data illustrate that receptor-effector coupling G-proteins are regionally specialized in their expression. This regional specialization may reflect a selective coupling of individual G-proteins with the various neurotransmitter receptors and effector pathways.     

Influence of thyroid hormone status on expression of genes encoding G protein subunits in the rat heart.

We have studied the influence of thyroid hormone status in vivo on expression of the genes encoding guanine nucleotide-binding regulatory protein (G protein) alpha-subunits Gs alpha, Gi alpha(2), Gi alpha(3), and both the 36-kDa form (beta 1) and the 35-kDa form (beta 2) of the beta-subunit in rat ventricle. The relative amounts of immunoactive Gi alpha(2) and Gi alpha(3) were greater in ventricular membranes from hypothyroid animals than from euthyroid animals (1.9- and 2.6-fold, respectively). A corresponding 2.3-fold increase in Gi alpha(2) mRNA was observed as well as a 1.5-fold increase in Gi alpha(3) mRNA. The relative amounts of immunoactive beta 1 and beta 2 polypeptides were also increased (2.8- and 1.8-fold, respectively) in the hypothyroid state and corresponded with comparable increases in the relative levels of beta 1 and beta 2 mRNAs. No difference was seen between the amounts of Gi alpha(2), Gi alpha(3), beta 1, and beta 2 in the euthyroid state and the hyperthyroid state. In contrast to these effects of thyroid hormone status on Gi alpha and beta, the steady-state amounts of Gs alpha protein and mRNA were not altered by thyroid hormone status. Thyroid hormone status did not alter sensitivity of adenylyl cyclase to stimulation by sodium fluoride or guanyl-5'-yl imidodiphosphate (GppNHp), nor did it influence GppNHp-induced inhibition of forskolin-stimulated enzyme activity. These results demonstrate that thyroid hormone status in vivo can regulate expression of specific G protein subunits in rat myocardium. However, the physiological consequences of these changes remain unclear.     

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.     

Glucocorticoids modulate mRNA levels for G-protein beta-subunits.

Adrenalectomy decreases, whereas glucocorticoid treatment increases, the steady-state levels of G-protein beta-subunits (G beta) in rat fat-cells. A DNA-excess solution-hybridization assay was established to define the steady-state mRNA levels for G beta [5.8 +/- 0.4 amol/micrograms of RNA (n = 5) in control fat-cells]. G beta mRNA levels decrease by 20% after adrenalectomy; dexamethasone treatment reverses the decline. Dexamethasone treatment itself increases G beta mRNA levels by 50%.     

Excitotoxin lesion of nucleus basalis causes a specific decrease in Go mRNA in cerebral cortex. Sensitivity to MK-801

Lesions of the ascending cholinergic pathway from nucleus basalis are known to have profound effects on cortical function. In particular, a substantial potentiation of carbachol-stimulated polyphosphoinositide turnover is detected from 1 day after lesion and is maintained for several days before returning to normal by 1 month. In this study the effect of this lesion was investigated on levels of three G-protein alpha-subunit mRNAs. Excitotoxin lesion of the nucleus basalis caused a selective reduction in the levels of Go alpha mRNA in cerebral cortex ipsilateral to the lesion, Gs alpha and Gi alpha mRNA being unaffected. The maximal effect was obtained at 3 days after lesion where levels of Go alpha mRNA were decreased by 40% compared to sham-operated animals. Levels of Go alpha mRNA returned to normal values by 28 days. Treatment with MK-801 caused a significant attenuation of the decrease in Go alpha mRNA, indicating the involvement of NMDA receptors in this response.     

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)     

Analysis by mRNA levels of the expression of six G protein alpha-subunit genes in mammalian cells and tissues.

The distribution and levels of expression of Gs alpha, Gi1 alpha, Gi2 alpha, Gi3 alpha, Go alpha, and Gx alpha mRNAs were compared by Northern blot analysis using several rat tissues and selected human and rat cell lines. Gi1 alpha, Go alpha, and Gx alpha, were detected in a limited number of tissue and cells whereas Gi2 alpha, Gi3 alpha, and Gs alpha, were expressed in all the tissues and cells tested albeit in varying amounts. The expression of these six genes appears to be differentially regulated during postnatal development of the rat brain. High expression levels particularly of Go alpha, in young rat brain may be related to the formation of neurites during differentiation of nerve cells.     

Membrane-Bound and cytosolic forms of heterotrimeric G proteins in young and adult rat myocardium: influence of neonatal hypo- and hyperthyroidism.

Membrane and cytosolic fractions prepared from ventricular myocardium of young (21-day-old) hypo- or hyperthyroid rats and adult (84-day-old) previously hypo- or hyperthyroid rats were analyzed by immunoblotting with specific anti-G-protein antibodies for the relative content of Gs alpha, Gi alpha/Go alpha, Gq alpha/G11 alpha, and G beta. All tested G protein subunits were present not only in myocardial membranes but were at least partially distributed in the cytosol, except for Go alpha2, and G11 alpha. Cytosolic forms of the individual G proteins represented about 5-60% of total cellular amounts of these proteins. The long (Gs alpha-L) isoform of Gs alpha prevailed over the short (Gs alpha-S) isoform in both crude myocardial membranes and cytosol. The Gs alpha-L/Gs alpha-S ratio in membranes as well as in cytosol increased during maturation due to a substantial increase in Gs alpha-L. Interestingly, whereas the amount of membrane-bound Gi alpha/Go alpha and Gq alpha/G11 alpha proteins tend to lower during postnatal development, cytosolic forms of these G proteins mostly rise. Neonatal hypothyroidism reduced the amount of myocardial Gs alpha and increased that of Gi alpha/Go alpha proteins. By contrast, neonatal hyperthyroidism increased expression of Gs alpha and decreased that of Gi alpha and G11 alpha in young myocardium. Changes in G protein content induced by neonatal hypo- and hyperthyroidism in young rat myocardium were restored in adulthood. Alterations in the membrane-cytosol balance of G protein subunits associated with maturation or induced by altered thyroid status indicate physiological importance of cytosolic forms of these proteins in the rat myocardium.     

Differential tissue expression and developmental regulation of guanine nucleotide binding regulatory proteins and their messenger RNAs in rat heart

The expression and developmental regulation of the alpha and beta subunits of the guanine nucleotide binding regulatory proteins, Gi and Go, were examined in rat atria and ventricles. Protein levels were determined by quantitative immunoblot analysis using affinity purified monospecific antibodies. Northern blot and dot blot analyses were used to characterize and quantitate relative amounts of mRNA encoding these G protein subunits. The concentrations of Go alpha, Gi alpha, and beta subunit protein were found to be greater in adult atrial than in adult ventricular membranes (5.2-, 1.5-, and 2.8-fold, respectively). A corresponding 3.4-fold difference in Go alpha mRNA level was also observed, as well as a 1.3-fold difference in Gi alpha-3 mRNA level. No difference was seen between the amount of beta, Gi alpha-1, Gi alpha-2 mRNA in adult atria and adult ventricles. Comparison of neonatal and adult tissues revealed a developmental decrease in ventricular Gi alpha protein and Gi alpha-2 mRNA levels (70 and 47%, respectively). Developmental decreases were also observed in the amount of mRNA encoding beta and Go alpha in ventricles (47 and 61%, respectively), and beta and Gi alpha-2 in atria (40 and 36%, respectively), while a developmental increase in atrial Gi alpha-3 mRNA levels was observed (57%). These results demonstrate differences in the expression of G protein subunits in rat atria and ventricles, as well as regulation of the levels of these subunits during cardiac development.     

Immunological and biochemical differentiation of guanyl nucleotide binding proteins: interaction of Go alpha with rhodopsin, anti-Go alpha polyclonal antibodies, and a monoclonal antibody against transducin alpha subunit and Gi alpha

Guanyl nucleotide binding proteins couple agonist interaction with cell-surface receptors to an intracellular enzymatic response. In the adenylate cyclase system, inhibitory and stimulatory effects are mediated through guanyl nucleotide binding proteins, Gi and Gs, respectively. In the visual excitation complex, the photon receptor rhodopsin is linked to its target, cGMP phosphodiesterase, through transducin (Gt). Bovine brain contains another guanyl nucleotide binding protein, Go. The proteins are heterotrimers of alpha, beta, and gamma subunits; the alpha subunits catalyze receptor-stimulated GTP hydrolysis. To examine the interaction of Go alpha with beta gamma subunits and rhodopsin, the proteins were reconstituted in phosphatidylcholine vesicles. The GTPase activity of Go alpha purified from bovine brain was stimulated by photolyzed, but not dark, rhodopsin and was enhanced by bovine retinal Gt beta gamma or by rabbit liver G beta gamma. Go alpha in the presence of G beta gamma is a substrate for pertussis toxin catalyzed ADP-ribosylation; the modification was inhibited by photolyzed rhodopsin and enhanced by guanosine 5'-O-(2-thiodiphosphate). ADP-Ribosylation of Go alpha by pertussis toxin inhibited photolyzed rhodopsin-stimulated, but not basal, GTPase activity. It would appear from this and prior studies that Go alpha is similar to Gt alpha and Gi alpha; all three proteins exhibit photolyzed rhodopsin-stimulated GTPase activity, are pertussis toxin substrates, and functionally couple to Gt beta gamma. Go alpha (39K) can be distinguished from Gi alpha (41K) but not from Gt alpha (39K) by molecular weight.(ABSTRACT TRUNCATED AT 250 WORDS)     

Regulation of G-proteins in differentiation. Altered ratio of alpha- to beta-subunits in 3T3-L1 cells

The complexion of the adenylate cyclase system and in particular, the regulation of G-proteins was examined in 3T3-L1 cells during differentiation from a fibroblast-like to an adipocyte-like phenotype. Gs alpha (the identified regulatory component of hormone-sensitive adenylate cyclase that mediates stimulation), measured by cholera toxin-catalyzed ADP-ribosylation, increased by approximately 6-fold from day 0 to day 8. Gs alpha, measured by functional reconstitution, increased in specific activity by approximately 3-fold from day 0 to day 8. Both Gi alpha (the G-protein with alpha-subunit Mr 40,000-41,000 whose function is in part the mediation of inhibition of adenylate cyclase) and Go alpha (the highly abundant G-protein first isolated from bovine brain whose effector system remains to be established) measured by pertussis toxin-catalyzed ADP-ribosylation increased by approximately 4-fold over this same period. 3T3-L1 cells possess beta-subunits of G-proteins displaying Mr = 36,000 (beta 36) and Mr = 35,000 (beta 35). The increase in the beta 35 as well as beta 36 subunits was approximately 2-fold. Using quantitative immunoblotting techniques and specific antisera, the total amount of beta-subunits was determined to be 150 as compared to 70 pmol/mg of membrane protein, while the amount of Go alpha was 40 and 10 pmol/mg of membrane protein in adipocytes and fibroblasts, respectively. Since Go alpha is the most abundant G-protein alpha-subunit observed to date in both phenotypes, the overall ratio of beta- to alpha-subunits of G-proteins appears to decrease from approximately 4.7 in fibroblasts to 2.5 in adipocytes. These data suggest that in differentiation not only is the complexion of G-proteins altered but more importantly, the relative amounts of alpha- to beta-subunits are regulated.     

Membrane attachment of recombinant G-protein alpha-subunits in excess of beta gamma subunits in a eukaryotic expression system

Recombinant cDNAs encoding the alpha-subunits of Gi1, Gi2, Gi3, Go and Gs were transfected into COS cells with the pCD-PS mammalian expression vector. Expression of each G alpha was verified using subtype-specific peptide antisera on immunoblots. Quantitative immunoblotting of alpha and beta subunits indicated: i) that there was no change in expression of endogenous beta subunits, and ii) overexpression of alpha subunits could achieve a ratio of alpha:beta greater than 25:1. Despite the excess of alpha over beta, the G alpha subunits were found predominantly in the membrane fraction. The results demonstrate that G alpha subunits can attach to the membrane independently of beta gamma subunits.     

Selectivity of the beta-adrenergic receptor among Gs, Gi's, and Go: assay using recombinant alpha subunits in reconstituted phospholipid vesicles.

The selective regulation of Gs (long and short forms), Gi's (1, 2, and 3), and Go by the beta-adrenergic receptor was assessed quantitatively after coreconstitution of purified receptor, purified G-protein beta gamma subunits, and individual recombinant G-protein alpha subunits that were expressed in and purified from Escherichia coli. Receptor and beta gamma subunits were incorporated into phospholipid vesicles, and the alpha subunits bound to the vesicles stoichiometrically with respect to beta gamma. Efficient regulation of alpha subunit by receptor required the presence of beta gamma. Regulation of G proteins was measured according to the stimulation of the initial rate of GTP gamma S binding, steady-state GTPase activity, and equilibrium GDP/GDP exchange. The assays yielded qualitatively similar results. GDP/GDP exchange was a first-order reaction for each subunit. The rate constant increased linearly with the concentration of agonist-liganded receptor, and the dependence of the rate constant on receptor concentration was a reproducible measurement of the efficiency with which receptor regulated each G protein. Reconstituted alpha s (long or short form) was stimulated by receptor to approximately the extent described previously for natural Gs. Both alpha i,1 and alpha i,3 were regulated with 25-33% of that efficiency. Stimulation of alpha o and alpha i,2 was weak, and stimulation of alpha o was barely detectable over its high basal exchange rate. Reduction of the receptor with dithiothreitol increased the exchange rates for all G proteins but did not alter the relative selectivity of the receptor.     

Relationships within the family of GTP-binding proteins isolated from bovine central nervous system

Four members of a family of GTP-binding proteins (G-proteins) which translate stimulation of extracellular receptors into regulation of intracellular enzymes were isolated from the bovine central nervous system. These proteins were examined for functional similarities and cross-reactivity with antibodies to the G-protein (transducin, Gt) from the photoreceptor system. Two proteins, Gs and Gi, can be distinguished by their respective abilities to stimulate or inhibit adenylate cyclase. The activated alpha subunits of Gt and a fourth member of the family, Go, did not affect this enzyme. Gt was shown to be unique in its ability to stimulate cGMP-dependent phosphodiesterase. While functionally diverse, the G-proteins were shown to have some common antigenic properties. Antibodies directed against the beta subunit of Gt recognize the beta 36 subunits of all preparations but not a putative second beta 35 subunit. Antibodies specific for the alpha subunit of Gt did not recognize other alpha subunits when immune blots from sodium dodecyl sulfate gels were examined. However, Go alpha, but not Gs alpha or Gi alpha, reacted strongly with the antibodies when the native subunit was spotted directly. This suggests that Go alpha and Gt alpha have homologous structural determinants. An antiserum that recognized Gt gamma did not recognize gamma subunits from other sources. These data support the proposed diversity of function and similarity of structure among the four G-proteins. The alpha and potentially gamma subunits appear to be responsible for the specificity of function.     

Functional interactions of recombinant alpha 2 adrenergic receptor subtypes and G proteins in reconstituted phospholipid vesicles.

The functional interaction of the recombinant alpha 2 adrenergic receptor subtypes, alpha 2-C10 (the human platelet alpha 2 receptor, equivalent to the alpha 2 A subtype) and alpha 2-C4 (an alpha 2 receptor subtype cloned from a human kidney cDNA library), with G proteins was characterized in an in vitro reconstitution system. These receptor subtypes were overexpressed in COS-7 cells and were purified to a specific activity of 1.1-3.3 nmol/mg of protein. The G proteins consisted of Gs (adenylyl cyclase stimulatory) and members of the inhibitory family, including Gi1, Gi2, and Gi3, and G0. The cloned alpha subunits of these G proteins were overexpressed in Escherichia coli and were purified to homogeneity. Prior to use, G holoproteins were prepared by mixing the alpha subunits with beta gamma subunits that had been purified from bovine brain. Following reconstitution into phospholipid vesicles, both alpha 2 receptor subtypes could couple to the inhibitory G proteins but not to Gs, as assessed by agonist stimulation of GTPase activity. The pharmacological specificity of this interaction was preserved with respect to the two receptor subtypes. Between the different inhibitory G proteins, the alpha 2-C10 adrenergic receptor subtype showed the following preference: Gi3 greater than Gi1 greater than or equal to Gi2 greater than G0. The stimulation of GTPase activity (turnover number) ranged from 6.4-fold (Gi3) to 1.5-fold (G0). The preference of G-protein interaction for the alpha 2-C4 receptor subtype was the same as that observed for the alpha 2-C10, but the extent of activation was slightly lower. The results show that in vitro each of the alpha 2 adrenergic receptor subtypes can activate multiple G proteins but that clear preferences exist with respect to the individual inhibitory G-protein subtypes. Additionally, it appears that alpha 2-C10 is coupled more efficiently to G-protein activation than is alpha 2-C4.     

Differential localization of G proteins, Gi and Go, in the olfactory epithelium and the main olfactory bulb of the rat.

The immunohistochemical localization of proteins Gi1 (plus Gi3). Gi2 and Go was studied in the olfactory epithelium and the main olfactory bulb of rats, using purified antibodies to the respective alpha subunits and beta gamma subunits of these G proteins. In the olfactory epithelium, only a restricted population of olfactory cells was immunopositive for Gi2 alpha, but others were not. The immunoreactivity for Gi1 alpha/Gi3 alpha was not observed. The olfactory epithelium was immunopositive for both Go alpha and beta gamma, but its apical surface was immunopositive only for beta gamma. In the main olfactory bulb, all layers were intensely immunopositive for Go alpha and beta gamma but weakly for Gi2 alpha. In contrast to the negative or weak immunostainings in the olfactory nerve fiber layer and glomeruli, the molecular and the internal granular layers were intensely immunopositive for Gi1 alpha/Gi3 alpha. These findings suggest the functional difference among Gi1/Gi3, Gi2 and Go in the signal transduction in the olfactory system.