Molecular cytogenetic characterization of a familial der(1)del(1)(p36.33)dup(1)(p36.33p36.22) with variable phenotype.

Chromosome deletions involving 1p36 are the most common known terminal rearrangements occurring at a frequency of approximately 1 in 5,000 live births. In contrast, duplications of the same region have been reported rarely. We describe a familial rearrangement der(1)del(1)(p36.33)dup(1)(p36.33p36.22) identified in a mother, daughter, and son. These individuals help define a syndrome with variable mental disability, attention deficit-hyperactivity disorder, and a distinctive facial appearance with wide palpebral fissures, broad nasal root, macrostomia, ear malformations, and prominent incisors. Based on our results we suggest that the complex rearrangement seen in our family could be the result of the breakage-fusion-bridge (BFB) cycles model of formation.

Modification of human 5-HT(2C) receptor function by Cys23Ser, an abundant, naturally occurring amino-acid substitution.

A human serotonin (5-HT)(2C) receptor gene polymorphism leads to the substitution of cysteine for serine at codon 23 (Cys23Ser); the frequency of the Ser23 allele in unrelated Caucasians is approximately 0.13. In the present study, we assessed whether Cys23Ser could affect receptor function. The two alleles were functionally compared following expression in COS-7 cells. The constitutive activity of the receptor in an in situ reconstitution system was also evaluated following expression of each allele in Sf9 cells. Using radioligands, Ser23-expressed membranes showed reduced high-affinity binding to meta-chlorophenylpiperazine (m-CPP) and 5-HT. Although the amplitude of the 5-HT-induced intracellular Ca(2+) peak did not differ between the alleles, Ser23 required higher 5-HT concentrations to elicit the same response. These differences might be due to more extensive desensitization in the Ser23 form. In the in situ reconstitution system, the 5-HT(2C) receptor displayed considerable constitutive activity, with the Ser23 allele being significantly higher in this regard than the Cys23 form. After prolonged serum deprivation in order to resensitize the receptor, four of the 15 cells expressing Ser23 showed abnormally higher m-CPP-induced sensitivity of the Ca(2+) response. These results indicate that the Ser23 allele may be constitutively more active than Cys23. Thus, Ser23 appears to be an abundant candidate allele capable of directly influencing inter-individual variation in behavior, susceptibility to mental disorder, and response to drugs including atypical antipsychotic and some antidepressant drugs that are potent 5-HT(2C) inverse agonists or antagonists.

Gbetagamma affinity for bovine rhodopsin is determined by the carboxyl-terminal sequences of the gamma subunit.

Two native betagamma dimers, beta(1)gamma(1) and beta(1)gamma(2), display very different affinities for receptors. Since these gamma subunits differ in both primary structure and isoprenoid modification, we examined the relative contributions of each to Gbetagamma interaction with receptors. We constructed baculoviruses encoding gamma(1) and gamma(2) subunits with altered CAAX (where A is an aliphatic amino acid) motifs to direct alternate or no prenylation of the gamma chains and a set of gamma(1) and gamma(2) chimeras with the gamma(2) CAAX motif at the carboxyl terminus. All the gamma constructs coexpressed with beta(1) in Sf9 cells yielded beta(1)gamma dimers, which were purified to near homogeneity, and their affinities for receptors and Galpha were quantitatively determined. Whereas alteration of the isoprenoid of gamma(1) from farnesyl to geranylgeranyl and of gamma(2) from geranylgeranyl to farnesyl had no impact on the affinities of beta(1)gamma dimers for Galpha(t), the non-prenylated beta(1)gamma(2) dimer had significantly diminished affinity. Altered prenylation resulted in a <2-fold decrease in affinity of the beta(1)gamma(2) dimer for rhodopsin and a <3-fold change for the beta(1)gamma(1) dimer. In each case with identical isoprenylation, the beta(1)gamma(2) dimer displayed significantly greater affinity for rhodopsin compared with the beta(1)gamma(1) dimer. Furthermore, dimers containing chimeric Ggamma chains with identical geranylgeranyl modification displayed rhodopsin affinities largely determined by the carboxyl-terminal one-third of the protein. These results indicate that isoprenoid modification of the Ggamma subunit is essential for binding to both Galpha and receptors. The isoprenoid type influences the binding affinity for receptors, but not for Galpha. Finally, the primary structure of the Ggamma subunit provides a major contribution to receptor binding of Gbetagamma, with the carboxyl-terminal sequence conferring receptor selectivity.

Independent and synergistic interaction of retinal G-protein subunits with bovine rhodopsin measured by surface plasmon resonance.

We have used surface plasmon resonance (SPR) measurements for the kinetic analysis of G-protein-receptor interaction monitored in real time. Functionally active rhodopsin was immobilized on an SPR surface, with full retention of biochemical specific activity for catalysis of nucleotide exchange on the retinal G-protein alpha subunit, via binding to immobilized concanavalin A. The binding interactions of bovine retinal alpha(t) and beta(1)gamma(1) subunits with rhodopsin measured by SPR were profoundly synergistic. Synergistic binding of the retinal G-protein subunits to rhodopsin was not observed for guanosine 5'-[gamma-thio]triphosphate-bound Galpha(t), nor was binding observed with squid retinal Galpha(q), which is not activated by bovine rhodopsin. The binding affinity (336+/-171 nM; mean value+/-S.D.) of retinal betagamma for rhodopsin in the presence of retinal alpha subunit measured by SPR confirmed the apparent affinity of 254 nM determined previously by nucleotide exchange assays. Binding of beta(1)gamma(1), beta(1)gamma(2), and beta(1)gamma(8-olf) dimers to rhodopsin, independently of the alpha subunit, was readily observable by SPR. Further, these dimers, differing only in their gamma subunit compositions, displayed markedly distinct binding affinities and kinetics. The beta(1)gamma(2) dimer bound with a kinetically determined K(d) of 13+/-3 nM, a value nearly identical with the biochemically determined K(1/2) of 10 nM. The physiologically appropriate beta(1)gamma(1) displayed rapid association and dissociation kinetics, whereas the other beta(1)gamma dimers dissociated at a rate less than 1/100 as fast. Thus rhodopsin interaction with its native signalling partners is both rapid and transient, whereas the interaction of rhodopsin with heterologous Gbetagamma dimers is markedly prolonged. These results suggest that the duration of a G-protein-coupled receptor signalling event is an intrinsic property of the G-protein coupling partners; in particular, the betagamma dimer.

Phosphorylation uncouples the gastrin-releasing peptide receptor from G(q).

Previous work on the desensitization of G protein-coupled receptors has focused on the role of arrestin binding following receptor phosphorylation. We have examined the hypothesis that phosphorylation alone contributes to desensitization. In this study we demonstrate that for the G(q)-coupled gastrin-releasing peptide receptor (GRP-R), phosphorylation by GRK2 to a stoichiometry of approximately 1 mol PO(4)/mol GRP-R is sufficient in the absence of arrestin to reduce the rate of receptor catalyzed G protein activation by approximately 80%. Furthermore, GRP-Rs exposed in vivo to agonist are rapidly phosphorylated to a similar stoichiometry and are desensitized to a similar degree. Finally, the molecular mechanism for both in vitro GRK2-induced and in vivo agonist-induced desensitization is primarily a decrease in the maximum velocity (V(max)) for the catalysis of guanine nucleotide exchange by the GRP-R rather than a change in the affinity of the receptor for the alpha(q) or betagamma subunits. Based on these results, we suggest that, for some G protein-coupled receptors, phosphorylation has a role in desensitization that is independent of arrestin.

Agonist selective regulation of G proteins by cannabinoid CB(1) and CB(2) receptors.

We have examined the ligand regulation and G protein selectivity of the human cannabinoid CB(1) and CB(2) receptors by an in situ reconstitution technique directly measuring G protein activation. Membranes from Spodoptera frugiperda cells expressing CB(1) and CB(2) receptors were chaotrope extracted to denature endogenous GTP-binding proteins. The ability of the receptors to catalyze the GDP-GTP exchange of each G protein was then examined with purified bovine brain G(i) and G(o). Activation of CB(1) receptors produced a high-affinity saturable interaction for both G(i) and G(o). Agonist stimulation of CB(2) receptors also resulted in a high-affinity saturable interaction with G(i). In contrast, CB(2) receptors did not interact efficiently with G(o). G protein activation was then examined with a diverse group of ligands. For the interaction of CB(2) receptors with G(i), HU210 was the only compound tested that demonstrated maximal activation. In contrast, WIN55,212 (64%), anandamide (42%), and Delta(9)-tetrahydrocannabinol (Delta(9)-THC) (44%) all initiated submaximal levels of G protein activation. For CB(1) receptor-catalyzed activation of G(i), HU210, WIN55,212, and anandamide all elicited maximal activation, whereas Delta(9)-THC (56 +/- 6%) caused only partial G(i) activation. In contrast, only HU210 effected maximal CB(1) stimulation of G(o), with anandamide, WIN55, 212, and Delta(9)-THC all stimulating between 60 and 75% compared with HU210. These data demonstrate that different agonists induce different conformations of the CB(1) receptor, which in turn can distinguish between different G proteins. Our data thus demonstrate agonist-selective G protein signaling by the CB(1) receptor and suggest that therapeutic agents may be designed to regulate individual G protein-signaling pathways selectively.

An aspartate residue at the extracellular boundary of TMII and an arginine residue in TMVII of the gastrin-releasing peptide receptor interact to facilitate heterotrimeric G protein coupling.

The mammalian bombesin receptor subfamily of G protein-coupled receptors currently consists of the gastrin-releasing peptide receptor (GRP-R), neuromedin B receptor, and bombesin receptor subtype 3. All three receptors contain a conserved aspartate residue (D98) at the extracellular boundary of transmembrane domain II and a conserved arginine residue (R309) near the extracellular boundary of transmembrane domain VII. To evaluate the functional role of these residues, site-directed GRP-R mutants were expressed in fibroblasts and assayed for their ability to both bind agonist and catalyze exchange of guanine nucleotides. Alanine substitution at GRP-R position 98 or 309 reduced agonist binding affinity by 24- and 56-fold, respectively, compared to wild-type GRP-R. Single swap GRP-R mutations either resulted in no receptor expression in the membrane (D98R) or the protein was not able to bind agonist (R309D). In contrast, the double swap mutation (D98R/R309D) had high-affinity agonist binding, reduced from wild-type GRP-R by only 6-fold. In situ reconstitution of urea-extracted membranes expressing either wild-type or mutant (D98A or R309A) GRP-R with G(q) indicated that alanine substitution greatly reduced G protein catalytic exchange compared to wild-type GRP-R. The D98R/R309D GRP-R had both a higher intrinsic basal activity and a higher overall catalytic exchange activity compared to wild-type; however, the wild-type GRP-R produced a larger agonist-stimulated response relative to the double swap mutant. Taken together, these data show that GRP-R residues D98 and R309 are critical for efficient coupling of GRP-R to G(q). Furthermore, our findings are consistent with a salt bridge interaction between these two polar and oppositely charged amino acids that maintains the proper receptor conformation necessary to interact with G proteins.

The bombesin receptor subtypes have distinct G protein specificities.

We used an in situ reconstitution assay to examine the receptor coupling to purified G protein alpha subunits by the bombesin receptor family, including gastrin-releasing peptide receptor (GRP-R), neuromedin B receptor (NMB-R), and bombesin receptor subtype 3 (BRS-3). Cells expressing GRP-R or NMB-R catalyzed the activation of squid retinal Galphaq and mouse Galphaq but not bovine retinal Galphat or bovine brain Galphai/o. The GRP-R- and NMB-R-catalyzed activations of Galphaq were dependent upon and enhanced by different betagamma dimers in the same rank order as follows: bovine brain betagamma > beta1gamma2 >> beta1gamma1. Despite these qualitative similarities, GRP-R and NMB-R had distinct kinetic properties in receptor-G protein coupling. GRP-R had higher affinities for bovine brain betagamma, beta1gamma1, and beta1gamma2 and squid retinal Galphaq. In addition, GRP-R showed higher catalytic activity on squid Galphaq. Like GRP-R and NMB-R, BRS-3 did not catalyze GTPgammaS binding to Galphai/o or Galphat. However, BRS-3 showed little, if any, coupling with squid Galphaq but clearly activated mouse Galphaq. GRP-R and NMB-R catalyzed GTPgammaS binding to both squid and mouse Galphaq, with GRP-R activating squid Galphaq more effectively, and NMB-R also showed slight preference for squid Galphaq. These studies reveal that the structurally similar bombesin receptor subtypes, in particular BRS-3, possess distinct coupling preferences among members of the Galphaq family.

Mechanism of allosteric regulation of the rod cGMP phosphodiesterase activity by the helical domain of transducin alpha subunit.

The G protein alpha subunit (Galpha) is composed of two distinct folding domains: a GTP-binding Ras-like domain and an alpha helical domain (HD). We have recently reported that the helical domain (HDt) of the vertebrate visual transducin alpha subunit (Galphat) synergizes activation of retinal cyclic GMP phosphodiesterase (PDE) by activated Galphat (Liu, W., and Northup, J. K., (1998) Proc. Natl. Acad. Sci. U. S. A. 95, 12878-12883). Here, we examine the molecular basis for this HD-based signaling regulation, and we provide a new model for the activation of the target effector. The HD proteins derived from visual transducin or taste gustducin alpha subunits, but no other Galpha HD proteins, each attenuate the PDE catalytic core (Palphabeta) and synergize Galphat stimulation of the holoPDE (Palphabetagamma2) with similar apparent affinities. The data from studies of both HDt-mediated attenuation and stimulation indicate that the HDt and the PDE inhibitory subunit (Pgamma) interact with PDE at independent sites and that Palphabeta contains the binding sites for HD. The saturation of both processes by HDt displays positive cooperativity with Hill coefficients of 1.5 for the attenuation of Palphabeta activity and 2.1 for synergism of holoPDE activation. Our data suggest the that Galphat-HDt regulates PDE by allosterically decreasing the affinity of Palphabeta for Pgamma and thus simultaneously facilitating the interaction of the activated Galphat-Ras-like domain with Pgamma. Thus, we propose a new model for the high efficiency of PDE activation as well as deactivation, and, overall, a novel mechanism for controlling fidelity, sensitivity, and efficacy of G protein signaling.

The helical domain of a G protein alpha subunit is a regulator of its effector.

The alpha subunit (Galpha) of heterotrimeric G proteins is a major determinant of signaling selectivity. The Galpha structure essentially comprises a GTPase "Ras-like" domain (RasD) and a unique alpha-helical domain (HD). We used the vertebrate phototransduction model to test for potential functions of HD and found that the HD of the retinal transducin Galpha (Galphat) and the closely related gustducin (Galphag), but not Galphai1, Galphas, or Galphaq synergistically enhance guanosine 5'-gamma[-thio]triphosphate bound Galphat (GalphatGTPgammaS) activation of bovine rod cGMP phosphodiesterase (PDE). In addition, both HDt and HDg, but not HDi1, HDs, or HDq attenuate the trypsin-activated PDE. GalphatGDP and HDt attenuation of trypsin-activated PDE saturate with similar affinities and to an identical 38% of initial activity. These data suggest that interaction of intact Galphat with the PDE catalytic core may be caused by the HD moiety, and they indicate an independent site(s) for the HD moiety of Galphat within the PDE catalytic core in addition to the sites for the inhibitory Pgamma subunits. The HD moiety of GalphatGDP is an attenuator of the activated catalytic core, whereas in the presence of activated GalphatGTPgammaS the independently expressed HDt is a potent synergist. Rhodopsin catalysis of Galphat activation enhances the PDE activation produced by subsaturating levels of Galphat, suggesting a HD-moiety synergism from a transient conformation of Galphat. These results establish HD-selective regulations of vertebrate retinal PDE, and they provide evidence demonstrating that the HD is a modulatory domain. We suggest that the HD works in concert with the RasD, enhancing the efficiency of G protein signaling.

Selective reconstitution of gastrin-releasing peptide receptor with G alpha q.

Identification of the molecular mechanisms that determine specificity of coupling interactions between gastrin-releasing peptide receptors (GRPrs) and their cognate heterotrimeric GTP-binding proteins is a fundamental step in understanding the signal transduction cascade initiated by receptor-ligand interaction. To explore these mechanisms in greater detail, we have developed an in situ reconstitution assay in chaotrope-extracted membranes from mouse fibroblasts expressing the GRPr, and we have used it to measure GRPr-catalyzed binding of GTP gamma S to purified G protein alpha subunits. Binding studies with 125I-labeled [D-Tyr6]bombesin(6-13) methyl ester (125I-Tyr-ME), a GRPr specific antagonist, show a single binding site with a Kd = 1.4 nM +/- 0.4 (mean +/- SD, n = 3) and capacity of 15-22 pmol of receptor per mg of protein in the extracted membrane preparations, representing a 2- to 3-fold enrichment of binding sites compared with the membranes before extraction. Quantitative ligand displacement analysis using various unlabeled GRPr agonists shows a rank order of potency characteristic of the GRPr: bombesin > or = GRP > > neuromedin B. Reconstitution of urea extracted membranes with a purified G alpha q showed that receptor-catalyzed binding of GTP gamma S was dependent on agonist (GRP) and G beta gamma subunits. The EC50 for GRP was 3.5 nM, which correlates well with the reported Kd of 3.1 nM for GRP binding to GRPr expressed in mouse fibroblasts [Benya, R. V., et al. (1994) Mol. Pharmacol. 46, 235-245]. The apparent Kd for bovine brain G beta gamma in this assay was 60 nM, and the Km for squid retinal G alpha q was 90 nM. The GRPr-catalyzed binding of GTP gamma S is selective for G alpha q, since we did not detect receptor-catalyzed exchange using either G alpha i/o or G alpha t. These data demonstrate that GRPr can functionally couple to G alpha q but not to the pertussis toxin-sensitive G alpha i/o or retinal specific G alpha t. This in situ receptor reconstitution method will allow molecular characterization of G protein coupling to other heptahelical receptors.

Functional reconstitution in situ of 5-hydroxytryptamine2c (5HT2c) receptors with alphaq and inverse agonism of 5HT2c receptor antagonists.

Membranes prepared after infection of Sf9 cells with recombinant baculovirus containing the rat 5HT2c receptor DNA, but not after infection with wild-type virus, expressed high affinity binding sites for 125I-lysergic acid diethylamide and [3H]mesulergine. The receptor site density reached an optimum of 50-70 pmol/mg membrane protein at 60 h postinfection. Extraction of peripheral membrane proteins from the postnuclear membrane fraction with 6 M urea depleted GTPgammaS-binding 4-fold without decreasing 5HT2c receptor binding activity. Urea-extracted Sf9 membranes expressing the 5HT2c receptor catalyzed the activation of squid retinal alphaq but not bovine retinal alphat or bovine alphao/alphai. Productive interaction of 5HT2c receptors with squid alphaq was enhanced by the addition of betagamma dimers prepared from either bovine brain or bovine rod outer segment discs. While the addition of serotonin increased 5HT2c receptor-catalyzed GTPgammaS binding to alphaq, the unoccupied receptor was also catalytically active. The 5HT2c receptor antagonists, mesulergine, mianserin, and ketanserin competitively inhibited 5HT activation of the receptor with predicted rank-order affinities; and mianserin and ketanserin markedly inhibited basal 5HT2c receptor activity. Interestingly, this "inverse agonist" efficacy did not correlate with antagonist affinity for the 5HT2c receptor. Baculoviral expression of the 5HT2c receptor and urea extraction of postnuclear Sf9 cell membranes have provided a high density of in situ, uncoupled, G-protein-linked receptor useful for reconstitution with purified G-protein subunits. This has allowed for independent manipulation of receptor and G-protein chemical concentrations and has revealed that a G-protein-linked receptor can possess a significant basal catalytic activity and that antagonist compounds can act as inverse agonists of this basal activity at the level of receptor activation of G-proteins.

Functional expression of the taste specific G-protein, alpha-gustducin.

The taste-specific G-protein alpha-subunit, alpha-gustducin, was expressed using a baculovirus based system. alpha-Gustducin was demonstrated to be myristoylated and was also palmitoylated in insect larval cells. Recombinant alpha-gustducin was purified to homogeneity. Neither receptors nor effectors that interact with gustducin in taste are known. However, alpha-gustducin has a close structural similarity to the visual G-protein, alpha-transducin. Therefore alpha-gustducin was reconstituted with components of the visual system to determine the degree of its functional similarity with alpha-transducin. Despite the fact that the sequences of alpha-gustducin and alpha-transducin share only 80% identity with each other, the interactions and functions of these two proteins were quantitatively identical. These included the interaction with receptor, bovine rhodopsin, with effector, bovine retinal cyclic GMP-phosphodiesterase, and with bovine brain and retinal G-protein beta gamma-heterodimers; receptor-catalysed GDP-GTP exchange and the intrinsic GTPase activity of alpha-gustducin and alpha-transducin were also identical. Gi alpha which is 70% identical with alpha-transducin interacts with different receptor and effector proteins and has very different guanine-nucleotide binding properties. Therefore, the functional equivalence of alpha-gustducin and alpha-transducin suggest that taste buds are likely to contain receptor and effector proteins that share many properties with their retinal equivalents.

Purification, characterization, and partial amino acid sequence of a G protein-activated phospholipase C from squid photoreceptors.

Invertebrate visual transduction is thought to be initiated by photoactivation of rhodopsin and its subsequent interaction with a guanyl nucleotide-binding protein (G protein). The identities of the G protein and its target effector have remained elusive, although evidence suggests the involvement of a phospholipase C (PLC). We have identified a phosphatidylinositol-specific PLC from the cytosol of squid retina. The enzyme was purified to near-homogeneity by a combination of carboxymethyl-Sepharose and heparin-Sepharose chromatography. The purified PLC, identified as an approximately 140-kDa protein by sodium dodecyl sulfate-polyacrylamide gels, hydrolyzed phosphatidylinositol 4,5-bisphosphate (PIP2) at a rate of 10-15 mumol/min/mg of protein with 1 microM Ca2+. The partial amino acid sequence of the protein showed homology with a PLC cloned from a Drosophila head library (PLC21) and lesser homology with Drosophila norpA protein and mammalian PLC beta isozymes. Reconstitution of purified squid PLC with an AlF(-)-activated 44-kDa G protein alpha subunit extracted from squid photoreceptor membranes resulted in a significant increase in PIP2 hydrolysis over a range of Ca2+ concentrations while reconstitution with mammalian Gt alpha or Gi 1 alpha was without effect. These results suggest that cephalopod phototransduction is mediated by G alpha-44 activation of a 140-kDa cytosolic PLC.

Prenyl modification of guanine nucleotide regulatory protein gamma 2 subunits is not required for interaction with the transducin alpha subunit or rhodopsin.

Guanine nucleotide-binding regulatory protein (G protein) beta gamma dimers that were active in reconstitution assays were produced in insect cells using the baculovirus/Sf9 insect cell expression system. Sf9 cells were infected either singly or in combination with recombinant baculoviruses containing a human G-protein beta 1 gene or a bovine G-protein gamma 2 gene. It was possible to express the beta 1 and gamma 2 gene products independently of each other in this system, as determined by using immunological and metabolic labeling techniques. Further, the ability of recombinant beta and/or gamma chains to function in defined biochemical assays of beta gamma activity was assessed for membrane extracts and supernatant fractions from infected Sf9 cells. Extracts of cells expressing beta or gamma chain alone were inactive in these assays, whereas those from cells coinfected with beta 1 and gamma 2 did display activity. These assays were used to identify recombinant beta gamma dimer migration during chromatographic purification, and the recombinant dimers were purified to near homogeneity. Both the membrane-associated and soluble beta gamma dimers facilitated rhodopsin-catalyzed guanosine 5'-[gamma-thio]triphosphate binding to Gt alpha, the GTP-binding subunit of the retinal G protein transducin (K0.5 of 13 +/- 2 and 36 +/- 5 nM, respectively). Both recombinant beta gamma dimers also facilitated the pertussis toxin-catalyzed ADP-ribosylation of Gt alpha with equal potency (K0.5 of 9 +/- 1 and 10 +/- 3 nM for membrane and soluble dimers, respectively). [3H]Mevalonolactone labeling showed that the gamma 2 subunits of membrane-associated beta gamma dimers incorporated radiolabel, whereas in the soluble form they did not. Thus, prenyl modification of gamma 2 directs the membrane association of the beta 1 gamma 2 dimer and increases its apparent affinity for receptor, but it is not required for the functional interaction(s) of the dimer.

Defective guanyl nucleotide-binding protein beta gamma subunits in a forskolin-resistant mutant of the Y1 adrenocortical cell line.

Forskolin-resistant mutants derived from Y1 adrenocortical cells display decreased responsiveness both to receptor and postreceptor stimulators of adenylyl cyclase and decreased amounts of the alpha subunits of the GTP-binding proteins (G proteins) that mediate stimulation (Gs) and inhibition (Gi) of adenylyl cyclase--namely, Gs alpha and Gi alpha-2. This phenotype is suggestive of a mutation that affects the processing or plasma membrane incorporation of G protein alpha subunits. Since the membrane attachment of heterotrimeric G proteins has been ascribed in part to the beta gamma subunits, we examined the quantity and functional activity of beta gamma subunits in wild-type Y1 and forskolin-resistant Forsk-10r-9 and Forsk-10r-3 cells. We now show that two assays previously used to examine the activity of purified beta gamma subunits--namely, to support either rhodopsin-catalyzed guanyl nucleotide exchange on Gt alpha or pertussis toxin-catalyzed ADP-ribosylation of Gt alpha--can be used with detergent extracts of cells. In both assays the beta gamma activity in Forsk-10r-9 and Forsk-10r-3 extracts was decreased by 53-76% compared with wild-type Y1 extracts. When normalized for immunoreactive beta subunit, the beta gamma activity in the Forsk-10r-9 samples was decreased by 55-57% compared with the wild-type Y1 samples. These results suggest that a mutation of one of the G protein beta or gamma subunits may result in the multiple defects of adenylyl cyclase activity and apparent loss of G protein alpha subunits seen in the forskolin-resistant mutant cells. The frequency with which these spontaneous mutations arise in the Y1 cell line suggests that they may contribute more generally to genetic abnormalities in signal transduction.

Regulatory GTP-binding proteins (ADP-ribosylation factor, Gt, and RAS) are not activated directly by nucleoside diphosphate kinase.

The expression of nucleoside diphosphate kinase (NDK) genes has been implicated as a negative regulator of murine and human tumor metastases and is critical to proper development in Drosophila melanogaster. Molecular mechanisms for the role(s) of NDK in these complex processes have not yet been elucidated, but several reports have suggested that these and many other signal transduction pathways may be activated by NDK acting directly on a regulatory GTP-binding protein(s). To test this hypothesis, we examined the ability of NDK to catalyze the phosphorylation of the GDP bound to the following three members of the superfamily of regulatory GTP-binding proteins: Gt, Ha-ras p21, and ARF. We have found no evidence to support the hypothesis that NDK can directly activate any GTP-binding protein. Rather, evidence is presented which clearly shows that all of the GTP formed upon incubation of GTP-binding proteins with NDK is the result of NDK utilizing free GDP as substrate. The GDP bound to the regulatory proteins is not a substrate for NDK under conditions in which free nucleotides are rapidly and efficiently phosphorylated. The importance of appropriate controls for dissociation of GDP from the regulatory proteins both during the NDK reaction and during the analysis of product is demonstrated. We believe there is currently no experimental evidence to support the hypothesis that NDK can directly activate a regulatory GTP-binding protein.

Activation of a small GTP-binding protein by nucleoside diphosphate kinase.

Genes that encode nucleoside diphosphate kinases (NDKs) have been implicated as regulators of mammalian tumor metastasis and development in Drosophila melanogaster. However, the cellular pathways through which NDKs function are not known. One potential mechanism of regulation is phosphorylation of guanosine diphosphate (GDP) bound to regulatory guanosine triphosphate (GTP) binding proteins. NDK-catalyzed phosphorylation of bound GDP was investigated for the adenosine diphosphate ribosylation factor (ARF), a 21-kilodalton GTP-binding protein that functions in the protein secretion pathway. Bovine liver NDK, recombinant human NDK, and the protein product of the mouse gene nm23-1, which suppresses the metastatic potential of certain tumor cells, used ARF-GDP as a substrate, thereby allowing rapid and efficient production of activated ARF (ARF-GTP) in the absence of nucleotide exchange. These data are consistent with the proposed function of NDK as an activator of a small GTP-binding protein and provide a mechanism of activation for a regulatory GTP-binding protein that is independent of nucleotide exchange.

Inhibitory GTP-binding regulatory protein Gi3 can couple angiotensin II receptors to inhibition of adenylyl cyclase in hepatocytes.

Angiotensin II can inhibit hormone-stimulated adenylyl cyclase in intact hepatocytes or in hepatic membrane preparations. Because the response can be blocked by pertussis toxin, the object of the present study was to determine which of the known variants of Gi can couple angiotensin II receptors to inhibition of adenylyl cyclase. The potential candidates were identified by probing RNA isolated from rat hepatocytes with cDNAs specific for the alpha subunits of known toxin-sensitive guanine nucleotide-binding regulatory proteins (G proteins). Hepatocytes contained no detectable RNA for the Go or Gi1 alpha subunits and similar levels of RNA coding for the Gi2 and Gi3 alpha subunits. To determine whether Gi3 could couple angiotensin receptors to inhibition of cyclase, membranes were prepared from hepatocytes whose G proteins were fully ADP-ribosylated with pertussis toxin, and the Gi3 holoprotein purified from rabbit liver was reconstituted into the membranes. The nature of the Gi3 reconstituted into the membrane was assessed by immunoblotting with antibodies specific for the Gi alpha subunits. Reconstitution of 6-10 pmol of Gi3/mg of membrane protein into the toxin-treated membranes restored the ability of 10 nM angiotensin II to inhibit adenylyl cyclase. Because pertussis toxin has nonspecific effects, an assay was developed to measure the interaction of the angiotensin receptor with reconstituted G proteins in normal membranes. In the presence of Mg2+, guanosine 5'-O-(3-thiotriphosphate) (GTP gamma S) caused a reduction of the affinity of the angiotensin II receptor for 125I-angiotensin II that was stable to washing and the detergents used to reconstitute G proteins into the membranes. Using this protocol to activate G proteins and "uncouple" receptors, the ability of the GDP-liganded form of Gi to restore high affinity binding was examined. Reconstitution of about 10-15 pmol of oligomeric Gi3/mg of membrane protein restored both the high affinity state of the angiotensin II receptor and the ability of GTP gamma S to shift the affinity to a lower state. The same shift in receptor affinity could be accomplished by reconstituting the Gi3 alpha subunit, resolved free of beta gamma subunits, into the membranes. Reconstitution of up to 50 pmol of Gs/mg of membrane protein had no effect on angiotensin II receptor affinity. The results suggest that a major form of Gi in hepatocytes is Gi3 and that it can couple angiotensin receptors to inhibition of adenylyl cyclase.