Subcellular distribution of GTP-binding proteins, Go and Gi2, in rat cerebral cortex

The localization of GTP-binding protein (G-protein) subunits, Go alpha, Gi2 alpha and beta, in subcellular fractions of rat cerebral cortex was determined by means of immunoassays specific for the respective subunits. High concentrations of all three subunits were observed in both crude mitochondrial and microsomal fractions. Muscarinic cholinergic receptors were also densely localized in these fractions. Then the crude mitochondrial and microsomal fractions were subfractionated by sucrose density gradient centrifugation. Each fraction obtained was evaluated morphologically by electron microscopy and biochemically by determination of membrane markers. The crude mitochondrial fraction was subfractionated into myelin, synaptic plasma membrane, and mitochondrial fractions. All the G-protein subunits examined and muscarinic receptors were exclusively localized in the synaptic plasma membrane fraction. Among the submicrosomal fractions, the heavy smooth-surfaced microsomal fraction showed the highest concentrations of all G-protein subunits and receptors, while the rough-surfaced microsomal fraction contained low amounts of them. The heavy smooth-surfaced microsomal fraction also contained high specific activity of (Na(+)-K+)-ATPase, a marker of the plasma membrane. These results indicated that the Go alpha, Gi2 alpha and beta subunits are mainly localized in the plasma membrane in the brain.     

Evidence for receptor-mediated inhibition of intrinsic activity of GTP-binding protein, Gi1 and Gi2, but not G0 in reconstitution experiments

The receptor-mediated inhibition of intrinsic activities of GTP-binding proteins (G-proteins) was studied. Pertussis toxin (IAP)-substrate G-protein, Gi1, Gi2 or G0, was prelabeled with [alpha-32P]GDP and reconstituted with synaptic membranes of the guinea pig cerebellum in the presence of 0.02% of Chaps. Intrinsic activities of G-proteins were evaluated by the release of [alpha-32P]GDP in exchange for added GppNHp or GDP in reconstituted preparations. U-50,488H (1 nM-10 microM), a specific kappa-subtype of opioid receptor agonist, inhibited the [alpha-32P]GDP release in exchange for added 1 microM GppNHp in Gi1-reconstituted preparations in a concentration-dependent manner. On the other hand, the kappa-opioid agonist at 10 microM increases the Km values of GppNHp, but not GDP in exchange for [alpha-32P]GDP release in preparations reconstituted with Gi1 or Gi2, but not with G0. These findings indicate that kappa-opioid receptor is coupled to inhibition of intrinsic activities of Gi1 and Gi2, but not G0, in guinea pig cerebellar membranes. In addition, it was revealed that the mode of action is mediated by a decrease in affinity of GTP (or its analog) for G proteins, but not by a change in affinity of GDP.     

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.     

Demonstration of GTP-binding proteins and ADP-ribosylated proteins in rat liver Golgi fraction

A Golgi-rich fraction isolated from rat liver was found to contain GTP-binding proteins with 20-25 kDa, which were tightly bound to the Golgi membrane. The Golgi fraction also contained two species of proteins which were ADP-ribosylated by bacterial toxins. Protein(s) which was ADP-ribosylated by botulinum toxin had a similar molecular mass as those with GTP-binding activity but was easily released from the membrane. Another protein with 46 kDa which was ADP-ribosylated by pertussis toxin was tightly bound to the membrane but had no significant GTP-binding activity under conditions tested here. These proteins were much less or negligible in the plasma membrane and the endoplasmic reticulum.     

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.     

Adenylyl cyclase regulates signal onset via the inhibitory GTP-binding protein, Gi

Adenylyl cyclase, the enzyme that converts ATP to cAMP, is regulated by its stimulatory and inhibitory GTP-binding proteins, G(s) and G(i), respectively. Recently, we demonstrated that besides catalyzing the synthesis of cAMP, type V adenylyl cyclase (ACV) can act as a GTPase-activating protein for Galpha(s) and also enhance the ability of activated receptors to stimulate GTP-GDP exchange on heterotrimeric G(s) (Scholich, K., Mullenix, J. B., Wittpoth, C., Poppleton, H. M., Pierre, S. C., Lindorfer, M. A., Garrison, J. C., and Patel, T. B. (1999) Science 283, 1328-1331). This latter action of ACV would facilitate the rapid onset of signaling via G(s). Because the C1 region of ACV interacts with the inhibitory GTP-binding protein Galpha(i), we investigated whether the receptor-mediated activation of heterotrimeric G(i) was also regulated by ACV and its subdomains. Our data show that ACV and its C1 domain increased the ability of a muscarinic receptor mimetic peptide (MIII-4) to enhance activation of heterotrimeric G(i) such that the amount of peptide required to stimulate G(i) in steady-state GTPase activity assays was 3-4 orders of magnitude less than without the C1 domain. Additionally, the MIII-4-mediated binding of guanosine 5'-(gamma-thio)triphosphate (GTPgammaS) to G(i) was also markedly increased in the presence of ACV or its C1 domain. In contrast, the C2 domain of ACV was not able to alter either the GTPase activity or the GTPgammaS binding to G(i) in the presence of MIII-4. Furthermore, in adenylyl cyclase assays employing S49 cyc(-) cell membranes, the C1 (but not the C2) domain of ACV enhanced the ability of peptide MIII-4 as well as endogenous somatostatin receptors to activate endogenous G(i) and to inhibit adenylyl cyclase activity. These data demonstrate that adenylyl cyclase and its C1 domain facilitate receptor-mediated activation of G(i).     

Stimulation by GTP-binding proteins (Gi, Go) of partially purified phospholipase C activity from human platelet membranes

A phospholipase C exhibiting preferential hydrolytic activity for polyphosphoinositides was partially purified from the deoxycholate extract of human platelet membranes by Q-Sepharose and Heparin-Sepharose column chromatographies. The activity of this purified phospholipase C free of the GTP gamma S-binding activity was stimulated at a similar level by addition of purified rat brain Gi or Go. These results suggest that GTP-binding proteins may interact directly with a solubilized membrane phospholipase C to stimulate its activity.     

Novel G proteins, Rag C and Rag D, interact with GTP-binding proteins, Rag A and Rag B

Rag A/Gtr1p are G proteins and are known to be involved in the RCC1-Ran pathway. We employed the two-hybrid method using Rag A as the bait to identify proteins binding to Rag A, and we isolated two novel human G proteins, Rag C and Rag D. Rag C demonstrates homology with Rag D (81.1% identity) and with Gtr2p of Saccharomyces cerevisiae (46.1% identity), and it belongs to the Rag A subfamily of the Ras family. Rag C and Rag D contain conserved GTP-binding motifs (PM-1, -2, and -3) in their N-terminal regions. Recombinant glutathione S-transferase fusion protein of Rag C efficiently bound to both [(3)H]GTP and [(3)H]GDP. Rag A was associated with both Rag C and Rag D in their C-terminal regions where a potential leucine zipper motif and a coiled-coil structure were found. Rag C and D were associated with both the GDP and GTP forms of Rag A. Both Rag C and Rag D changed their subcellular localization, depending on the nucleotide-bound state of Rag A. In a similar way, the disruption of S. cerevisiae GTR1 resulted in a change in the localization of Gtr2p.     

Characterization of an orphan G protein-coupled receptor, GPR20, that constitutively activates Gi proteins

GPR20 was isolated as an orphan G protein-coupled receptor from genomic DNA by PCR amplification. Although GPR20 was closely related to nucleotide or lipid receptors, the functional role of this receptor, as well as its endogenous ligand, remains unclear. Here we demonstrate that GPR20 is constitutively active in the absence of ligand, leading to continuous activation of its coupled G proteins. When GPR20 was exogenously expressed in HEK293 cells, both the basal level and the prostaglandin E(2)-induced production of cAMP were significantly decreased. A remarkable increase in [(35)S]guanosine 5'-(gamma-thio)triphosphate (GTPgammaS) binding to membrane preparations was also observed in GPR20-expressing cells. These effects of GPR20 overexpression were diminished in cells treated with pertussis toxin, suggesting that the expression of GPR20 results in the activation of G(i/o) proteins. Involvement of GPR20 in the activation of G(i/o) proteins was also supported by evidence that the disruption of a conserved DRY motif in GPR20 attenuated both [(35)S]GTPgammaS incorporation and inhibition of the prostaglandin E(2)-induced cAMP production. Knockdown of GPR20 in PC12h cells resulted in an elevation of the basal cAMP level, suggesting that the endogenous GPR20 achieves a constitutively or spontaneously active conformation. Furthermore, enhancement of [(3)H]thymidine incorporation was also observed in the GPR20-silencing cells, implying that the GPR20 expression seems to attenuate PC12h cell growth. Taken together, these data indicate that GPR20 constitutively activates G(i) proteins without ligand stimulation. The receptor may be involved in cellular processes, including control of intracellular cAMP levels and mitogenic signaling.     

Development of opiate receptors and GTP-binding regulatory proteins in neonatal rat brain

The mu and delta opiate receptors present in rat brain were measured independently during postnatal development. The numbers of delta receptors were almost undetectable at birth and increased substantially during the first few weeks, whereas the numbers of mu receptors remained relatively constant. Activation of either of these receptors caused inhibition of adenylate cyclase, but inhibition coupled to mu receptors was much smaller than that associated with delta receptors at all ages. Attempts to use pertussis toxin-catalyzed ADP-ribosylation as an assay for the GTP-binding proteins Ni and No were hampered by the development of an NADase with age. However, specific antibodies directed against the alpha subunits of Ni or No allowed separate quantitation of these transducer proteins. Both increased with age. No is present at levels at least 5-fold higher than Ni in the adult rat brain. The N proteins are in vast excess over receptors and as such are unlikely to be limiting factors in receptor function. The data further suggest that the number of opiate receptors present throughout neonatal development is in excess over that required for optimal function.     

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.     

Small GTP-binding proteins on rat liver lysosomal membranes.

GTP-binding proteins have been identified on the membranes of highly purified dextran-filled lysosomes (dextranosomes) and Triton-filled lysosomes (tritosomes) obtained from rat liver. Autoradiography of blots of lysosomal membrane proteins incubated with [alpha-32P]GTP revealed the presence of several specific GTP-binding proteins with a relative molecular mass (M(r)) predominantly in the range of 26-30 kDa. These GTP-binding proteins migrated slower in polyacrylamide gels than purified c-Ha-ras protein expressed in E. coli, whose apparent M(r) was 23 kDa in the same blot. The relative contents of GTP-binding proteins in lysosomal membranes were comparable or greater than that of plasma membranes and of microsomes. Chemical extraction showed that lysosomal GTP-binding proteins were more tightly associated with the membranes than with microsomal GTP-binding proteins. The possible involvement of lysosomal GTP-binding proteins in cellular functions including vacuolar (lysosomal) acidification and organellar dynamics are discussed.     

Involvement of GTP-binding "G" proteins in transport through the Golgi stack

GTP gamma S irreversibly inhibits protein transport between successive compartments of the Golgi stack in a cell-free system. Fluoride, potentiated by the addition of aluminum ion, also causes a strong inhibition. These are hallmarks of the involvement of a guanine nucleotide-binding or regulatory "G" protein. Inhibition by GTP gamma S requires a cytosolic inhibitory factor that binds to Golgi membranes during inhibition. Preincubation experiments reveal that GTP gamma S blocks the function of acceptor Golgi but not donor Golgi membranes. More specifically, a processing step in between vesicle attachment and the actual fusion event seems to be affected. Electron microscopy demonstrates a corresponding 5-fold accumulation of non-clathrin-coated buds and vesicles associated with the Golgi cisternae during inhibition by GTP gamma S.     

Cholecystokinin activates Gi1-, Gi2-, Gi3- and several Gs-proteins in rat pancreatic acinar cells.

On separation of rat pancreatic plasma membrane proteins by two-dimensional gel electrophoresis, 15 GTP-binding protein (G-protein) alpha-subunits could be detected immunochemically using an alpha common antibody. These consisted of five 48 kDa proteins (pI 5.70, 5.80, 5.90, 6.10 and 6.25) and five 45 kDa proteins (pI 5.90, 6.05, 6.25, 6.30 and 6.70), presumably corresponding to low- and high-molecular mass forms of the Gs-protein, as well as three 40/41 kDa proteins (pI 5.50, 5.70 and 6.00) and two 39 kDa proteins (pI 5.50 and 6.00). All of these proteins except for the more acidic 39 kDa protein were ADP-ribosylated by cholera toxin (CT). In addition, the three 40/41 kDa proteins and the more alkaline 39 kDa protein were also ADP-ribosylated by pertussis toxin (PT). CT- and PT-induced ADP-ribosylation changed the pI values of G-protein alpha-subunits by 0.2 pI units to more acidic values. Preincubation of isolated pancreatic membranes with cholecystokinin octapeptide (CCK-OP), which stimulates phospholipase C in acinar cells, decreased CT-induced as well as PT-induced ADP-ribosylation of the three 40/41 kDa proteins, whereas CT-induced ADP-ribosylation of one 45 kDa (pI 5.80) and all 48 kDa proteins was enhanced in the presence of CCK. Carbachol, another stimulant of phospholipase C, had no effect. The three 40/41 kDa proteins and one 48 kDa protein could be labelled with the GTP analogue [alpha-32P]GTP-gamma-azidoanilide. CCK, but not carbachol, stimulated incorporation of the GTP analogue into all of these four proteins. Using different anti-peptide antisera specific for alpha-subunits of G-proteins we identified the three 40/41 kDa Gi-proteins as Gi1 (pI 6.00), Gi2 (pI 5.50) and Gi3 (pI 5.70). The Gi3-protein was found to be the major Gi-protein of pancreatic plasma membranes. One of the 39 kDa proteins (pI 6.0) was identified as Go. These results indicate that CCK receptors functionally interact with six Gs-proteins and with Gi1, Gi2 and Gi3-proteins. Since evidence suggests that a 40/41 kDa CT substrate is involved in the stimulation of phospholipase C in pancreatic acinar cells, it is likely that one, two or all three 40/41 kDa Gi-proteins are involved in the coupling of CCK receptors with phospholipase C.     

Concurrent up-regulation of guanine-nucleotide-binding proteins Gi1 alpha, Gi2 alpha and Gi3 alpha in adipocytes of hypothyroid rats.

Rat white adipocytes express three distinct 'Gi-like' guanine-nucleotide-binding proteins (G-proteins) [Mitchell, Griffiths, Saggerson, Houslay, Knowler & Milligan (1989) Biochem. J. 262, 403-408]. We have previously noted elevated levels of Gi in membranes of adipocytes from hypothyroid rats [Milligan, Spiegel, Unson & Saggerson (1987) Biochem. J. 247, 223-227]. Using a series of anti-peptide antisera able to discriminate between the individual gene products we have examined levels of each Gi-like G-protein in adipocyte membranes of hypothyroid rats compared with euthyroid controls. We demonstrate that up-regulation of Gi in adipocytes of hypothyroid rats is not restricted to a single subtype of Gi but that each of Gi1 alpha, Gi2 alpha and Gi3 alpha is present at markedly higher levels compared with euthyroid animals. In contrast, levels of both the 45 and 42 kDa forms of Gs alpha were not altered substantially in the hypothyroid state.     

Immunodetection of ralA and ralB GTP-binding proteins in various rat tissues and platelets

Polyclonal antibodies were generated against a synthetic peptide corresponding to the C-terminal (amino acids 192-204) region of ralA and ralB GTP-binding proteins. The ralA and ralB antibodies recognized a 27 kDa protein in the human platelet particulate fraction. Incubation of ralA antibodies with ralB immunizing peptide and ralB antibodies with ralA immunizing peptide prior to Western blotting did not abolish the ability of antibodies to recognize the 27 kDa protein in human platelet particulate fraction. However, when antibodies were incubated with the respective immunizing peptide prior to Western blotting, the 27 kDa human platelet protein was no longer recognized by the antibodies. Incubation of nitrocellulose blots containing polypeptides separated using SDS-PAGE with [-³²P]GTP demonstrated the presence of GTP-binding proteins of molecular mass between 23-27 kDa in rat platelets and the various tissues tested. Analysis using subtype specific antibodies demonstrated that both ralA and ralB GTP-binding proteins were expressed in rat platelets and the various tissues tested. The protein recognized by the ralA and ralB antibodies in rat tissues and platelets had mobility on SDS-PAGE identical to that of the human platelet ral protein. Varying amounts of these proteins were detected in all the tissues tested except white muscle which contained very low level of ralB protein. The widespread distribution of ralA and ralB GTP-binding proteins suggests that they may participate in a common pathway in mammalian cells and tissues.     

Distribution of the small molecular weight GTP-binding proteins Rac1, Cdc42, RhoA and RhoB in the developing chick retina

Immunohistochemistry was used to determine the distribution of Rac1, Cdc42, RhoA and RhoB GTPases during development of the chick retina. All proteins appear as early as embryonic day 5 (E5) in cells of the vitreal margin, E7–8 in cells of the inner third of the inner nuclear layer and E9–10 in photoreceptors. From E10 until hatching, RhoA, Rac1 and Cdc42 were seen in perikarya and/or processes of amacrine, ganglion cells, and photoreceptors. Rho proteins were also observed in retinal Müller cells, with different distributions. RhoB showed a transient expression, being severely down regulated after E18. The distribution pattern of Rho proteins during the development of the chick retina suggests a concerted role in the differentiation of specific cell types, and probably during synaptogenesis.