Characterization of four G0-type proteins purified from bovine brain membranes

Recently we reported there were at least four types of G0 or G0-like proteins in bovine brain membranes based on their elution profiles from Mono Q columns and their immunological reactivities; one of the proteins was purified as an alpha-monomeric form, and the others as alpha beta gamma-trimers. The four proteins, of which alpha-subunits were confirmed to be a family of G0-type by an immunoblot analysis, were thus referred to as alpha (0)1, G(0)2, G(0)3 and G(0)4, respectively, in order of their elutions from the column. Immunostained peptide mappings arising from proteolytic digestions of the four alpha-subunits, together with their fragmentation patterns containing radiolabeled ADP-ribose that had been incorporated by pertussis toxin-catalyzed ADP-ribosylation, suggested that the four G0-alpha were classified into either of two groups such as alpha (0)1 and G(0)2-alpha, or G(0)3-alpha and G(0)4-alpha. The kinetic parameters of their GTPase activities, however, revealed that there were different properties between alpha (0)1 and G(0)2-alpha or G(0)3-alpha and G(0)4-alpha. Thus, the four G0-type proteins appeared to be different entities from one another.     

Purification and characterization of subforms of the guanine-nucleotide-binding proteins G alpha i and G alpha o

Five different pertussis-toxin-sensitive guanine-nucleotide-binding proteins (G proteins) were purified from bovine brain. Immunochemical characterization of alpha subunits identified two G alpha o proteins (G alpha o-I and G alpha o-II), two 41-kDa G alpha i proteins (G alpha i-I and G alpha i-II) and the 40-kDa G alpha i2 protein. Site-directed antisera specific for G alpha o proteins did not differentiate between G alpha o-I and G alpha o-II. However, in situ peptide mapping using polyacrylamide gel electrophoresis revealed distinct cleavage products with different proteases for each of these proteins. Additionally comparison of Rf values demonstrated a slightly faster migration for G alpha o-II than for G alpha o-I, which is the only type of G alpha o protein present in cell membranes of the neuroblastoma/glioma cell line NG 108-15. The importance of these structural differences and possible functional implications are discussed.     

Identification of G Protein Subtypes in Peripheral Nerve and Cultured Schwann Cells

In this study, we investigated the expression of various G proteins in whole sciatic nerves, in myelin and nonmyelin fractions from these nerves, and in membranes of immortalized Schwann cells. In myelin, nonmyelin, and Schwann cell membranes we detected two 39-40-kDa pertussis toxin substrates that were resolved on separation on urea-gradient gels. Two cholera toxin substrates with apparent molecular masses of 42 and 47 kDa were present in nerve and brain myelin and in Schwann cell membranes. In these membranes, a third 45-kDa cholera toxin substrate, which displayed the highest labeling, was also present. Immunoblotting with specific antisera allowed the identification of G(o) alpha, Gi1 alpha, Gi2 alpha, Gi3 alpha, Gq/G11 alpha, and the two isoforms of Gs alpha in nerve homogenates, nerve, and brain myelin fractions. In Schwann cell membranes we identified G(o) alpha, Gi2 alpha, Gi3 alpha, and proteins from the Gq family, but no immunoreactivity toward anti-Gi1 alpha antiserum was detected. In these membranes, anti-Gs alpha antibody recognized the three cholera toxin substrates mentioned above, with the 45-kDa band displaying the highest immunoreactivity. Relative to sciatic nerve myelin, the Schwann cell membranes revealed a significantly higher expression of Gi3 alpha and the absence of Gi1 alpha. The different distribution of G proteins among the different nerve compartments might reflect the very specialized function of Schwann cells and myelin within the nerve.     

Possible interaction of alpha 1-adrenergic receptor with pertussis-toxin-sensitive guanine-nucleotide-binding regulatory proteins (G proteins) responsible for phospholipase C activation in rat liver plasma membranes

Islet-activating protein (IAP; pertussis toxin) was employed to test the hypothesis that IAP-sensitive GTP-binding regulatory proteins (G proteins) are coupled with alpha 1-adrenergic receptor in rat liver plasma membranes. The high-affinity state of the binding of alpha 2-adrenergic agonist, which is known to be coupled with IAP-sensitive G protein, was abolished in IAP-treated plasma membranes. IAP treatment of plasma membranes could also diminish the high-affinity state of the alpha 1-adrenergic receptor for the agonist. Restoration of the high-affinity state of the alpha 1-adrenergic receptor for the agonist occurred on reconstitution of the bovine brain IAP-sensitive G proteins. The alpha 1-adrenergic receptor agonist stimulated inositol triphosphate (InsP3) production from [3H]inositol-labeled liver plasma membranes in a concentration-dependent manner. IAP treatment also decreased alpha 1-adrenergic-agonist-induced InsP3 production but not completely. From these results, we concluded that there is a possibility that both IAP-sensitive and IAP-insensitive G proteins were involved in alpha 1-adrenergic-receptor-stimulated phospholipase C activation in rat liver plasma membranes.     

Release of dog polymorphonuclear leukocyte cathepsin G, normally and in endotoxin and pancreatitic shock. Isolation and partial characterization of dog polymorphonuclear leukocyte cathepsin G

Dog polymorphonuclear leukocyte cathepsin G was isolated from a granule extract using a two-step procedure including affinity chromatography on a Trasylol-Sepharose gel and ion-exchange chromatography on a CM 52 column. 22 of the first 24 N-terminal amino acids were determined and showed 83% and 71% identity to those of human and rat cathepsin G, respectively. Total amino-acid composition demonstrated the basic nature of the protein. In an SDS/polyacrylamide-gel electrophoresis the protein showed an Mr of 29,400 compared to the Mr of 26,800 calculated from the total amino-acid composition. The enzyme was shown to form complexes with alpha 1 alpha 2-macroglobulin and alpha 1-proteinase inhibitor. A specific enzyme-linked immunosorbent assay was developed for the determination of cathepsin G/alpha 1-proteinase inhibitor complex in dog plasma and tissue fluids. The mean concentration of cathepsin G in normal dog plasma was determined to be 38 micrograms/l, measured as cathepsin G/alpha 1-proteinase inhibitor complex. When active dog cathepsin G was added to normal dog plasma in vitro, approximately 56% could be measured by the assay. Slow intravenous infusion of a lethal dose of endotoxin in dogs was followed by a marked drop in white blood cell count and thrombocytes and a simultaneous rapid increase in plasma cathepsin G concentration, reaching a maximum level of 150 micrograms/l. Bile-induced experimental pancreatitis in dogs was accompanied by successive increase in cathepsin G levels in plasma as well as in peritoneal exudates, reaching a maximum level of about 300 micrograms/l in plasma and 18 mg/l in the exudates during the late stages of disease.     

Differential distribution of alpha subunits and beta gamma subunits of heterotrimeric G proteins on Golgi membranes of the exocrine pancreas

Heterotrimeric G proteins are well known to be involved in signaling via plasma membrane (PM) receptors. Recent data indicate that heterotrimeric G proteins are also present on intracellular membranes and may regulate vesicular transport along the exocytic pathway. We have used subcellular fractionation and immunocytochemical localization to investigate the distribution of G alpha and G beta gamma subunits in the rat exocrine pancreas which is highly specialized for protein secretion. We show that G alpha s, G alpha i3 and G alpha q/11 are present in Golgi fractions which are > 95% devoid of PM. Removal of residual PM by absorption on wheat germ agglutinin (WGA) did not deplete G alpha subunits. G alpha s was largely restricted to TGN- enriched fractions by immunoblotting, whereas G alpha i3 and G alpha q/11 were broadly distributed across Golgi fractions. G alpha s did not colocalize with TGN38 or caveolin, suggesting that G alpha s is associated with a distinct population of membranes. G beta subunits were barely detectable in purified Golgi fractions. By immunofluorescence and immunogold labeling, G beta subunits were detected on PM but not on Golgi membranes, whereas G alpha s and G alpha i3 were readily detected on both Golgi and PM. G alpha and G beta subunits were not found on membranes of zymogen granules. These data indicate that G alpha s, G alpha q/11, and G alpha i3 associate with Golgi membranes independent of G beta subunits and have distinctive distributions within the Golgi stack. G beta subunits are thought to lock G alpha in the GDP-bound form, prevent it from activating its effector, and assist in anchoring it to the PM. Therefore the presence of free G alpha subunits on Golgi membranes has several important functional implications: it suggests that G alpha subunits associated with Golgi membranes are in the active, GTP-bound form or are bound to some other unidentified protein(s) which can substitute for G beta gamma subunits. It further implies that G alpha subunits are tethered to Golgi membranes by posttranslational modifications (e.g., palmitoylation) or by binding to another protein(s).     

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.     

Structure-function relationships of a novel bacterial toxin, hemolysin E. The role of alpha G

The novel pore-forming toxin hemolysin E (HlyE, ClyA, or SheA) consists of a long four-helix bundle with a subdomain (beta tongue) that interacts with target membranes at one pole and an additional helix (alpha(G)) that, with the four long helices, forms a five-helix bundle (tail domain) at the other pole. Random amino acid substitutions that impair hemolytic activity were clustered mostly, but not exclusively, within the tail domain, specifically amino acids within, adjacent to, or interacting with alpha(G). Deletion of amino acids downstream of alpha(G) did not affect activity, but deletions encompassing alpha(G) yielded insoluble and inactive proteins. In the periplasm Cys-285 (alpha(G)) is linked to Cys-87 (alpha(B)) of the four-helix bundle via an intramolecular disulfide. Oxidized HlyE did not form spontaneously in vitro but could be generated by addition of Cu(II) or mimicked by treatment with Hg(II) salts to yield inactive proteins. Such treatments did not affect binding to target membranes nor assembly into non-covalently linked octameric complexes once associated with a membrane. However, gel filtration analyses suggested that immobilizing alpha(G) inhibits oligomerization in solution. Thus once associated with a membrane, immobilizing alpha(G) inhibits HlyE activity at a late stage of pore formation, whereas in solution it prevents aggregation and consequent inactivation.     

Small molecular weight GTP-binding proteins in human erythrocyte ghosts

GTP-binding proteins (G proteins) were extracted from human erythrocyte ghosts by sodium cholate and purified by gel filtration on an Ultrogel AcA-44 column followed by hydroxyapatite column chromatography. At least two peaks of G proteins were separated by hydroxyapatite column chromatography. The second peak contained G proteins recognized by the antibodies against the respective alpha subunits of Gs and Gi, and the ras protein, while the G protein of the first peak was not recognized by any of these antibodies. The G protein of the first peak was purified further by Mono Q HR5/5 column chromatography. The purified G protein showed a molecular weight of about 22 kDa on SDS-polyacrylamide gel electrophoresis. This G protein (22K G) specifically bound guanosine 5'-(3-O-thio) triphosphate (GTP gamma S), GTP and GDP with a Kd value for GTP gamma S of about 50 nM. GTP gamma S-binding to 22K G was inhibited by pretreatment with N-ethylmaleimide. The G proteins recognized by the antibodies against the alpha subunit of Go and the ADP-ribosylation factor for Gs, designated as ARF, were not detected in human erythrocyte ghosts. These results indicate that there are at least two species of small molecular weight G proteins in human erythrocyte ghosts: one is the ras protein and the other is a novel G protein of 22K G.     

Activation of phospholipase C by the alpha subunits of the Gq and G11 proteins in transfected Cos-7 cells.

High efficiency transient transfection was used to introduce cDNA corresponding to various G protein alpha subunits into Cos-7 cells. The proteins that were subsequently synthesized were detected with specific G protein alpha subunit antipeptide antiserum and were localized in the membrane fraction of the cell. Cells that were prelabeled with the [3H]inositol and transfected with G alpha q and G alpha 11 cDNA showed marked increases in formation of [3H]inositol phosphates after stimulation with aluminum fluoride. Co-transfection with cDNAs corresponding to phosphoinositide specific phospholipase C beta 1 (PI-PLC beta 1) and to G alpha q or G alpha 11 resulted in even higher levels of inositol phosphate formation. The introduction of mutations that convert residue glutamine 209 to leucine in G alpha q and G alpha 11 resulted in persistent activation of PI-PLC and high steady state levels of inositol phosphates. On the other hand, transfection with a variety of other G alpha subunit cDNAs, i.e. G alpha Z, G alpha OA, G alpha OB, transducin, and the glutamine 205 to leucine mutants of G alpha Z and of G alpha OA did not increase inositol phosphate formation. To further test the specificity of G protein activation of PI-PLC, a cell-free system was prepared by using washed membranes of transiently transfected cells and purified PI-PLC beta 1. Membranes derived from G alpha q and G alpha 11, but not G alpha OA transfected cells, showed guanosine 5-O-thiotriphosphate (GTP gamma S)-stimulated PIP2 hydrolysis. The activity seen in the system reconstituted with membranes derived from G alpha 11-transfected cells was blocked by preincubation with specific G alpha 11 antipeptide antibodies. All of these results are consistent with the conclusion that G alpha q and G alpha 11 cDNA encode proteins that in the presence of GTP gamma S specifically activate PI-PLC.     

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.     

Expression and purification of functional G protein alpha subunits using a baculovirus expression system.

The alpha subunits of the heterotrimeric guanine nucleotide-binding proteins Gi1, Gi2, Gi3, G0, and Gs have been overexpressed in Sf9 cells using a baculovirus expression system. The Gi1 alpha, Gi2 alpha, Gi3 alpha, and G0 alpha have been purified to homogeneity from infected Spodoptera frugiperda (SF9) cells and characterized. Yields of up to 1.8 mg of purified recombinant G alpha have been obtained from 300-ml cultures of infected cells. The recombinant alpha subunits are myristoylated and are ADP-ribosylated by pertussis toxin only in the presence of beta gamma subunits. They bind guanosine 5'-3-O-(thio)triphosphate (GTP gamma S) with low nM dissociation constants and stoichiometries of 0.8 mol/mol or greater. The rGi1 alpha, rGi2 alpha, and rGi3 alpha are capable of interacting with angiotensin II receptors based on their ability to restore high affinity angiotensin II binding in rat liver membranes shifted to a low affinity state with GTP gamma S.     

Identification of G proteins mediating fungal elicitor-induced dephosphorylation of host plasma membrane H+ -ATPase

Tomato cells (with the Cf-5 resistance gene) were treated withelicitor preparations containing the avr5 gene product fromtwo Cf-5 incompatible races of the fungal pathogen Cladosporiumfulvum (race 2.3 and race 4), or with elicitor preparationscontaining no avr5 gene product from two Cf-5 compatible races(race 5 and race 2.4.5.9 [EC] .11). Elicitor preparations from race2.3 or race 4 caused dephosphorylation of host plasma membraneH⁺ -ATPase in isolated plasma membranes, while the preparationsfrom race 5 or race 2.4.5.9 [EC] .11 did not. GTP()S, AlF₄^–and cholera toxin (CTX) each induced similar dephosphorylationin the absence of active elicitors. The elicitor-induced dephosphorylationof the H⁺ -ATPase was blocked by preincubation of membraneswith an antibody raised against a stimulatory G protein -subunit(anti-G_s This antibody cross-reacted with a 42 kDa polypeptidefrom tomato plasma membranes. A 42 kDa polypeptide was alsoADP-ribosylated by CTX. When plasma membranes were treated withelicitor preparations from race 4 and separated on non-dissociatingPAGE, two proteins were detected on Western blots with the antibodyraised against the -subunit, suggesting the dissociation ofthe trimeric complex. No dissociation of the complex was detectedwith antibodies raised against either the - or ß-subunitswhen the plasma membranes were treated with elicitor preparationsfrom race 5. The results provide evidence for the activationof a stimulatory subtype of trimeric G proteins in the stimulationof elicitor-induced host defences to fungal pathogens. Key words: G protein, dephosphorylation, H⁺ -ATPase, fungal elicitor, tomato     

Two alpha subunits of the Gq class of G proteins stimulate phosphoinositide phospholipase C-beta 1 activity.

Two G protein alpha subunits were detected in preparations of GTP gamma S-dependent, phosphoinositide-specific phospholipase C-activating proteins from bovine liver membranes. Partial resolution of the two alpha subunits, of molecular mass 42 and 43 kDa, was achieved by Mono Q chromatography. Quantitation of the levels of each alpha subunit and reconstitution assays demonstrated that each possessed stimulatory activity towards the beta 1 isozyme of phospholipase C. Immunoblot analysis showed that the 42 kDa protein was immunologically related to alpha q, whereas the 43 kDa protein was related to alpha 11, another member of the Gq class. The data thus show that two different alpha subunits of the Gq class of G proteins stimulate phospholipase C-beta 1 Activity.     

Ornithodoros moubata: host immunoglobulin G in tick hemolymph

Hemolymph proteins of a soft tick, Ornithodoros moubata, were analyzed immunochemically and biochemically. The components of tick hemolymph proteins were shown to be totally different from the host (rabbit) serum proteins by polyacrylamide gel electrophoresis with sodium dodecyl sulfate and Coomassie blue or silver stain. However, in the hemolymph of ticks engorged from rabbits immunoglobulin G was detected by immunoblotting analysis with goat anti-rabbit immunoglobulin G. The concentration of rabbit Immunoglobulin G in tick hemolymph changed with the physiological stages after a blood meal. Immunoglobulin G was isolated from tick hemolymph by affinity chromatography on a Protein A-Sepharose 4B column. Analysis of the isolated immunoglobulin G from tick hemolymph with sodium dodecyl sulfate-polyacrylamide gel electrophoresis and Ouchterlony double diffusion test showed it to be composed of the same subunits as heavy and light chains of host (rabbit) immunoglobulin G. Tracer experiments showed that 125I-labeled heavy and light chains of immunoglobulin G were detected in an intact form in hemolymph from ticks that sucked 125I-labeled rabbit immunoglobulin G through an artificial membrane. These facts suggested that the host rabbit immunoglobulin G ingested in the tick midgut passed through the gut wall without digestion. By solid-phase enzyme immunoassay, immunoglobulin in the hemolymph was shown to retain its antibody activity.     

Dominant portion of thyrotropin-releasing hormone receptor is excluded from lipid domains. Detergent-resistant and detergent-sensitive pools of TRH receptor and Gqalpha/G11alpha protein

Some G protein-coupled receptors might be spacially targetted to discrete domains within the plasma membrane. Here we assessed the localization in membrane domains of the epitope-tagged, fluorescent version of thyrotropin-releasing hormone receptor (VSV-TRH-R-GFP) expressed in HEK293 cells. Our comparison of three different methods of cell fractionation (detergent extraction, alkaline treatment/sonication and mechanical homogenization) indicated that the dominant portion of plasma membrane pool of the receptor was totally solubilized by Triton X-100 and its distribution was similar to that of transmembrane plasma membrane proteins (glycosylated and non-glycosylated forms of CD147, MHCI, CD29, CD44, transmembrane form of CD58, Tapa1 and Na,K-ATPase). As expected, caveolin and GPI-bound proteins CD55, CD59 and GPI-bound form of CD58 were preferentially localized in detergent-resistant membrane domains (DRMs). Trimeric G proteins G(q)alpha/G(11)alpha, G(i)alpha1/G(i)alpha2, G(s)alphaL/G(s)alphaS and Gbeta were distributed almost equally between detergent-resistant and detergent-solubilized pools. In contrast, VSV-TRH-R-GFP, Galpha, Gbeta and caveolin were localized massively only in low-density membrane fragments of plasma membranes, which were generated by alkaline treatment/sonication or by mechanical homogenization of cells. These data indicate that VSV-TRH-R-GFP as well as other transmembrane markers of plasma membranes are excluded from TX-100-resistant, caveolin-enriched membrane domains. Trimeric G protein G(q)alpha/G(11)alpha occurs in both DRMs and in the bulk of plasma membranes, which is totally solubilized by TX-100.     

Purification of GTP-binding proteins from bovine brain membranes. Identification of heterogeneity of the alpha-subunit of Go proteins

Using high-resolution Mono Q column chromatography, we purified 6 distinct peaks of GTP-binding proteins from bovine brain membranes. Five of them consisted of 3 polypeptides with alpha beta gamma-subunits and served as the substrate of islet-activating protein (IAP), pertussis toxin. The other one was purified as alpha-subunit alone and was also ADP-ribosylated by IAP in the presence of beta gamma-subunits. When each alpha-subunit was characterized by immunoblot analysis using various antibodies with defined specificity, the two of them were identified as Gi-1 and Gi-2, and other 4 appeared to be Go or Go-like G proteins. The alpha-subunits of immunologically Go-like proteins were apparently distinguishable from one another on elution profiles from the Mono Q column. Thus, there was a heterogeneity of the alpha-subunit of Go in the brain membranes.     

Differential degradation rates of the G protein alpha o in cultured cardiac and pituitary cells

Signal transduction in biological membranes is modulated by a family of GTP-binding proteins termed G proteins. Differences in the tissue-specific expression of G protein subtypes suggest that the levels of individual G proteins may be an important determinant of the hormonal response in a given cell type. We have used a polyclonal antibody raised against the purified G protein, alpha o to study alpha o in the rat pituitary cell line GH4 and in primary rat cardiocytes in culture by quantitative immunoprecipitation. Biosynthetic labeling and specific immunoprecipitation of alpha o in pulse-chase experiments demonstrated that the t1/2 for alpha o degradation is 28 +/- 7 h (n = 4) in GH4 pituitary cells and is greater than 72 h (n = 4) in cardiocytes. The steady-state level of alpha o protein is similar in both cell types as measured by Western blots. Northern blots of poly(A)-selected mRNA from these two cell types were probed with labeled alpha o cDNA and showed they have similar alpha o mRNA levels. The observation of different degradation rates, but similar steady-state protein levels, suggests that the rate of alpha o synthesis is different in GH4 cells and cardiocytes. Since mRNA levels are approximately equal in both, our studies imply that protein translation controls may be important determinants of G protein alpha subunit concentrations in biological membranes.     

Characterization of G proteins in rat myometrium. A differential modulation of Gi2 alpha and Gi3 alpha during gestation

Myometrial membranes, obtained from estrogen-dominated (day 0) rat uteri, were immunoblotted with antiserum (SG1), which recognizes the alpha subunits of both Gi1 and Gi2, with antiserum (LE2) specific for Gi2 alpha, and with I3B antiserum, specific for Gi3 alpha. The data revealed the absence of detectable levels of Gi1 alpha and the simultaneous presence of Gi2 alpha and Gi3 alpha as Gi subunits in rat myometrium. The expression of Gi proteins during gestation (days 0, 12, 21) was studied with the above antibodies. No qualitative change in the nature of Gi alpha species was observed during gestation: Gi1 alpha remained undetectable, Gi2 alpha and Gi3 alpha were both present on days 12 and 21. Of significance was the increase (160%) in the amount of Gi2 alpha at midgestation (day 12) compared to days 0 and 21. A different pattern was observed with Gi3 alpha, which decreased with advancing gestation (day 0 greater than 12 greater than 21). Immunodetection of beta subunits of G proteins indicated the presence of a 35/36 kDa doublet on days 0, 12 and 21, with an increase at midgestation. The simultaneous increase in Gi2 alpha and beta subunits may provide an explanation for the previously demonstrated alteration in adenylate cyclase stimulability detected at midgestation.     

Detection of G Proteins in Purified Bovine Brain Myelin

Following a previous report on detection of muscarinic receptors in myelin with the implied presence of G proteins, we now demonstrate by more direct means the presence of such proteins and their quantification. Using [35S]guanosine 5'-O-(3-thiotriphosphate) ([35S]GTP gamma S) as the binding ligand, purified myelin from bovine brain was found to contain approximately half the binding activity of whole white matter (138 +/- 9 vs. 271 +/- 18 pmol/mg of protein). Scatchard analysis of saturation binding data revealed two slopes, a result suggesting at least two binding populations. This binding was inhibited by GTP and its analog but not by 5'-adenylylimidodiphosphate [App(NH)p], GMP, or UTP. Following sodium dodecyl sulfate (SDS)-polyacrylamide gel electrophoresis (PAGE) of myelin proteins and blotting on nitrocellulose, [alpha-32P]GTP bound to three bands in the 21-27-kDa range in a manner inhibited by GTP and GTP gamma S but not App(NH)p. ADP-ribosylation of myelin with [32P]NAD+ and cholera toxin labeled a protein of 43 kDa, whereas reaction with pertussis toxin labeled two components of 40 kDa. Cholate extract of myelin subjected to chromatography on a column of phenyl-Sepharose gave at least three major peaks of [35S]GTP gamma S binding activity. SDS-PAGE and immunoblot analyses of peak I indicated the presence of Go alpha, Gi alpha, and Gs alpha. Further fractionation of peak II by diethyl-aminoethyl-Sephacel chromatography gave one [35S]GTP gamma S binding peak with the low-molecular-mass (21-27 kDa) proteins and a second showing two major protein bands of 36 and 40 kDa on SDS-PAGE.(ABSTRACT TRUNCATED AT 250 WORDS)