Loss-of-function mutations identified in the Helical domain of the G protein α-subunit,Gα2, of Dictyostelium discoideum

The guanine nucleotide binding regulatory proteins (G proteins) play essential roles in a wide variety of physiological processes, such as vision, hormone responses, olfaction, immune response, and development. The heterotrimeric G proteins consist of α-, β-, and γ-subunits and act as molecular switches to relay information from transmembrane receptors to intracellular effectors. The switch mechanism is a function of the inherent GTPase activity of the α-subunit. The α-subunit is comprised of two domains, the GTPase domain and the Helical domain. The GTPase domain performs all of the known α-subunit functions while little is know about the role of the Helical domain. To gain a better understanding of α-subunit function, we performed a screen for loss-of-function mutations, using the Gα2-subunit of Dictyostelium. Gα2 is essential for the developmental life cycle of Dictyostelium. It is known that the loss of Gα2 function results in a failure of cells to enter the developmental phase, producing a visibly abnormal phenotype. This allows the easy identification of amino acids essential to Gα2 function. A library of random point mutations in the gα2 cDNA was constructed using low fidelity polymerase chain reaction (PCR). The library was then expressed in a gα2 null cell line and screened for loss-of-function mutations. Mutations were identified in isolated clones by sequencing the gα2 insert. To date, sixteen single amino acids changes have been identified in Gα2 which result in loss-of-function. Of particular interest are seven mutations found in the Helical domain of the α-subunit. These loss-of-function mutations in the α-subunit Helical domain may provide important insight into its function.     

Cloning and targeted mutations of G alpha 7 and G alpha 8, two developmentally regulated G protein alpha-subunit genes in Dictyostelium.

GTP-binding protein (G protein)-mediated signal transduction pathways play essential roles during the aggregation and differentiation process of Dictyostelium. In addition to the five known G protein alpha-subunit genes, we recently identified three novel alpha-subunit genes, G alpha 6, G alpha 7, and G alpha 8, using the polymerase chain reaction technique. We present here a more complete analysis of G alpha 7 and G alpha 8. The cDNAs of these two genes were cloned, and their complete nucleotide sequences were determined. Sequence analyses indicate that G alpha 8 possesses some unusual features. It lacks the "TCATDT" motif, a sequence of amino acids highly conserved among G alpha subunits, and has an additional 50 amino acids at its C-terminus consisting of long stretches of asparagine. Moreover, G alpha 8 is unusually resistant to protease digestion, which may indicate a slow GTP hydrolysis rate. The possible functions of these alpha-subunits were assessed by generating mutants lacking G alpha 7 or G alpha 8 by gene targeting through homologous recombination and by overexpressing G alpha 7 or G alpha 8 protein. Overexpression of G alpha 7 resulted in abnormal morphogenesis starting at the slug stage, whereas analysis of the other strains failed to reveal any obvious growth or developmental defects under either normal or stressful conditions. The implications of these results are discussed.     

G alpha 3 regulates the cAMP signaling system in Dictyostelium.

The Dictyostelium discoideum developmental program is initiated by starvation and its progress depends on G-protein-regulated transmembrane signaling. Disruption of the Dictyostelium G-protein alpha-subunit G alpha 3 (g alpha 3-) blocks development unless the mutant is starved in the presence of artificial cAMP pulses. The function of G alpha 3 was investigated by examining the expression of several components of the cAMP transmembrane signaling system in the g alpha 3- mutant. cAMP receptor 1 protein, cyclic nucleotide phosphodiesterase, phosphodiesterase inhibitor, and aggregation-stage adenylyl cyclase mRNA expression were absent or greatly reduced when cells were starved without exogenously applied pulses of cAMP. However, cAMP receptor 1 protein and aggregation-stage adenylyl cyclase mRNA expression were restored by starving the g alpha 3- cells in the presence of exogenous cAMP pulses. Adenylyl cyclase activity was also reduced in g alpha 3- cells starved without exogenous cAMP pulses compared with similarly treated wild-type cells but was elevated to a level twofold greater than wild-type cells in g alpha 3- cells starved in the presence of exogenous cAMP pulses. These results suggest that G alpha 3 is essential in early development because it controls the expression of components of the transmembrane signaling system.     

Aggregation of Dictyostelium discoideum is dependent on myristoylation and membrane localization of the G protein alpha-subunit, G alpha 2.

The heterotrimeric G protein, G2, from the eukaryotic organism Dictyostelium discoideum participates in signal transduction pathways which are essential to Dictyostelium's developmental life cycle. G2 is activated by cell surface cAMP receptors and in turn is required for the activation of a host of effectors, including adenylyl cyclase, guanylyl cyclase, and phospholipase C. Myristoylation of G protein alpha-subunits is known to affect alpha-subunit association with the beta gamma subunits and membrane localization. The putative site for N-terminal myristoylation of G alpha 2 was mutated from Gly to Ala (G2A) and expressed in the g alpha 2-null cell line, MYC2. Transformants expressing G alpha 2-G2A exhibit physiological and biochemical changes from wild-type cells. G alpha 2-G2A expressing cells fail to rescue the aggregation-minus phenotype of MYC2 cells on developmental agar plates. G alpha 2-G2A expressing cells are also not chemotactic to cAMP in a standard drop assay. G alpha 2-WT is found in both the pellet and supernatant fractions following lysis of the cells. G alpha 2-G2A however is found almost exclusively in the lysate supernatant. G alpha 2 is radiolabeled upon incubation of cells in [3H]myristate, while G alpha 2-G2A is not labeled. Examination of activation of the effectors adenylyl cyclase and guanylyl cyclase reveals that G alpha 2-G2A expressing cells partially activate adenylyl cyclase but show no cAMP-stimulation of guanylyl cyclase. The physiological deviations from wild-type can be explained by the variations in effector activation, possibly due to improper localization of the non-myristoylated G alpha 2-G2A to the cytosol.     

Regulation and function of G alpha protein subunits in Dictyostelium

We have examined the developmental regulation and function of two G alpha protein subunits, G alpha 1 and G alpha 2, from Dictyostelium. G alpha 1 is expressed in vegetative cells through aggregate stages while G alpha 2 is inducible by cAMP pulses and preferentially expressed in aggregation. Our results suggest that G alpha 2 encodes the G alpha protein subunit associated with the cAMP receptor and mediates all known receptor-activated intracellular signal transduction processes, including chemotaxis and gene regulation. G alpha 1 appears to function in both the cell cycle and development. Overexpression of G alpha 1 results in large, multinucleated cells that develop abnormally. The central role that these G alpha proteins play in signal transduction processes and in controlling Dictyostelium development is discussed.     

Genetic and structural analysis of G protein alpha subunit regulatory domains.

Genetic and structural analysis of the alpha chain polypeptides of heterotrimeric G proteins defines functional domains for GTP/GDP binding, GTPase activity, effector activation, receptor contact and beta gamma subunit complex regulation. The conservation in sequence comprising the GDP/GTP binding and GTPase domains among G protein alpha subunits readily allows common mutations to be made for the design of mutant polypeptides that function as constitutive active or dominant negative alpha chains when expressed in different cell types. Organization of the effector activation, receptor and beta gamma contact domains is similar in the primary sequence of the different alpha subunit polypeptides relative to the GTP/GDP binding domain sequences. Mutation within common motifs of the different G protein alpha chain polypeptides have similar functional consequences. Thus, what has been learned with the Gs and Gi proteins and the regulation of adenylyl cyclase can be directly applied to the analysis of newly identified G proteins and their coupling to receptors and regulation of putative effector enzymes.     

Cloning and characterization of a cDNA coding for the alpha-subunit of a stimulatory G protein from Schistosoma mansoni.

Guanine nucleotide-binding proteins (G proteins) mediate signals between serotonin receptors and adenylate cyclase in Schistosoma mansoni. A bovine Gs alpha cDNA probe was used to isolate a cDNA clone, SG12, encoding the entire alpha-subunit of a G protein of S. mansoni. The cDNA is 1897 base pairs long, contains an open reading frame of 1137 base pairs, and codes for a deduced protein of 379 amino acids. The putative protein encoded by the clone has an exact amino acid match with bovine Gs alpha of 65% and a 78% match when conserved amino acid substitutions are considered. In contrast, the exact and conserved matches of the schistosome alpha-subunit with bovine Gi are 41 and 61%, respectively. A comparison of the deduced amino acid sequence of SG12 with a variety of different G alpha proteins indicates that all the major structural features characteristic of a Gs alpha protein are present in the S. mansoni gene. The schistosome clone contains the putative site for ADP-ribosylation by cholera toxin found in Gs alpha but does not contain the ADP-ribosylation site for pertussis toxin present in Gi alpha. The amino acids are completely conserved at the GTP-binding sites. On a Northern blot, the cDNA hybridizes to a major band of 3.1 kilobases in RNA from adult schistosomes. The message appears to be absent in miracidia and cercariae, but a faint 3.1-kilobase band is visible in the early schistosomule stage preceding adulthood. This evidence, when added to previous biochemical data, indicates that the expression of this gene is developmentally controlled.     

Chimeric G alpha i2/G alpha 13 proteins reveal the structural requirements for the binding and activation of the RGS-like (RGL)-containing Rho guanine nucleotide exchange factors (GEFs) by G alpha 13

The alpha-subunit of G proteins of the G(12/13) family stimulate Rho by their direct binding to the RGS-like (RGL) domain of a family of Rho guanine nucleotide exchange factors (RGL-RhoGEFs) that includes PDZ-RhoGEF (PRG), p115RhoGEF, and LARG, thereby regulating cellular functions as diverse as shape and movement, gene expression, and normal and aberrant cell growth. The structural features determining the ability of G alpha(12/13) to bind RGL domains and the mechanism by which this association results in the activation of RGL-RhoGEFs are still poorly understood. Here, we explored the structural requirements for the functional interaction between G alpha(13) and RGL-RhoGEFs based on the structure of RGL domains and their similarity with the area by which RGS4 binds the switch region of G alpha(i) proteins. Using G alpha(i2), which does not bind RGL domains, as the backbone in which G alpha(13) sequences were swapped or mutated, we observed that the switch region of G alpha(13) is strictly necessary to bind PRG, and specific residues were identified that are critical for this association, likely by contributing to the binding surface. Surprisingly, the switch region of G alpha(13) was not sufficient to bind RGL domains, but instead most of its GTPase domain is required. Furthermore, membrane localization of G alpha(13) and chimeric G alpha(i2) proteins was also necessary for Rho activation. These findings revealed the structural features by which G alpha(13) interacts with RGL domains and suggest that molecular interactions occurring at the level of the plasma membrane are required for the functional activation of the RGL-containing family of RhoGEFs.     

The Aspergillus nidulans sfaD gene encodes a G protein beta subunit that is required for normal growth and repression of sporulation.

flbA encodes an Aspergillus nidulans RGS (regulator of G protein signaling) domain protein that antagonizes FadA (G(i)alpha-subunit of heterotrimeric G protein)-mediated growth signaling to allow asexual development. We previously defined and characterized five suppressors of flbA (sfa) loss-of-function mutations and showed that one suppressor (sfaB) resulted from a novel dominant-negative allele of fadA. In this report we show that a second suppressor gene (sfaD) is predicted to encode the beta subunit of a heterotrimeric G protein. Deletion of sfaD suppressed all defects resulting from complete loss-of-flbA function mutations, caused a hyperactive sporulation phenotype and severely reduced vegetative growth. However, the sfaD deletion could not suppress the growth activation caused by dominant-activating fadA alleles, indicating that constitutively active FadA can cause proliferative growth in the absence of Gbetagamma signaling. We propose that SfaD and FadA are both positive growth regulators with partially overlapping functions and that FlbA has an important role in controlling the activities of both proteins. Inactivation of signaling events stimulated by both components of the heterotrimeric G protein is essential for both sexual and asexual sporulation.     

Hydrolysis of GTP by the alpha-chain of Gs and other GTP binding proteins

The functions of G proteins--like those of bacterial elongation factor (EF) Tu and the 21 kDa ras proteins (p21ras)--depend upon their abilities to bind and hydrolyze GTP and to assume different conformations in GTP- and GDP-bound states. Similarities in function and amino acid sequence indicate that EF-Tu, p21ras, and G protein alpha-chains evolved from a primordial GTP-binding protein. Proteins in all three families appear to share common mechanisms for GTP-dependent conformational change and hydrolysis of bound GTP. Biochemical and molecular genetic studies of the alpha-chain of Gs (alpha s) point to key regions that are involved in GTP-dependent conformational change and in hydrolysis of GTP. Tumorigenic mutations of alpha s in human pituitary tumors inhibit the protein's GTPase activity and cause constitutive elevation of adenylyl cyclase activity. One such mutation replaces a Gln residue in alpha s that corresponds to Gln-61 of p21ras; mutational replacements of this residue in both proteins inhibit their GTPase activities. A second class of GTPase inhibiting mutations in alpha s occurs in the codon for an Arg residue whose covalent modification by cholera toxin also inhibits GTP hydrolysis by alpha s. This Arg residue is located in a domain of alpha s not represented in EF-Tu or p21ras. We propose that this domain constitutes an intrinsic activator of GTP hydrolysis, and that it performs a function analogous to that performed for EF-Tu by the programmed ribosome and for p21ras by the recently discovered GTPase-activating protein.(ABSTRACT TRUNCATED AT 250 WORDS)     

Comparison of cDNA-derived protein sequences of the human fibronectin and vitronectin receptor alpha-subunits and platelet glycoprotein IIb

The fibronectin receptor (FnR), the vitronectin receptor (VnR), and the platelet membrane glycoprotein (GP) IIb-IIIa complex are members of a family of cell adhesion receptors, which consist of noncovalently associated alpha- and beta-subunits. The present study was designed to compare the cDNA-derived protein sequences of the alpha-subunits of human FnR, VnR, and platelet GP IIb. cDNA clones for the alpha-subunit of the FnR (FnR alpha) were obtained from a human umbilical vein endothelial (HUVE) cell library by using an oligonucleotide probe designed from a peptide sequence of platelet GP IIb. cDNA clones for platelet GP IIb were isolated from a cDNA expression library of human erythroleukemia cells by using antibodies. cDNA clones of the VnR alpha-subunit (VnR alpha) were obtained from the HUVE cell library by using an oligonucleotide probe from the partial cDNA sequence for the VnR alpha. Translation of these sequences showed that the FNR alpha, the VnR alpha, and GP IIb are composed of disulfide-linked large (858-871 amino acids) and small (137-158 amino acids) chains that are posttranslationally processed from a single mRNA. A single hydrophobic segment located near the carboxyl terminus of each small chain appears to be a transmembrane domain. The large chains appear to be entirely extracellular, and each contains four repeated putative Ca2+-binding domains of about 30 amino acids that have sequence similarities to other Ca2+-binding proteins. The identity among the protein sequences of the three receptor alpha-subunits ranges from 36.1% to 44.5%, with the Ca2+-binding domains having the greatest homology. These proteins apparently evolved by a process of gene duplication.     

G alpha i-G alpha s chimeras define the function of alpha chain domains in control of G protein activation and beta gamma subunit complex interactions

Gs and Gi2 are G proteins whose alpha subunits are 65% homologous. Within the 355 amino acid alpha i2 polypeptide, substitution of residues Ile213-Lys319 with the corresponding alpha s region (Ile235-Arg356) generated a chimera that activated adenylyl cyclase, indicating that the alpha s activation domain resides within this 122 amino acid alpha s sequence. Mutation within alpha s residues Glu15-Pro144 resulted in an alpha s polypeptide having an enhanced rate of GDP dissociation. Mutation within two regions of the N-terminus influenced the ability of pertussis toxin to ADP-ribosylate the alpha subunit polypeptide, a reaction controlled by the beta gamma subunit complex. The findings define the G protein alpha subunit N-terminus as a regulatory region controlling beta gamma subunit interactions and GDP dissociation independent of the GTPase and effector activation domains.     

New insights into the role of conserved, essential residues in the GTP binding/GTP hydrolytic cycle of large G proteins

The GTP hydrolytic (GTPase) reaction terminates signaling by both large (heterotrimeric) and small (Ras-related) GTP-binding proteins (G proteins). Two residues that are necessary for GTPase activity are an arginine (often called the "arginine finger") found either in the Switch I domains of the alpha subunits of large G proteins or contributed by the GTPase-activating proteins of small G proteins, and a glutamine that is highly conserved in the Switch II domains of Galpha subunits and small G proteins. However, questions still exist regarding the mechanism of the GTPase reaction and the exact role played by the Switch II glutamine. Here, we have characterized the GTP binding and GTPase activities of mutants in which the essential arginine or glutamine residue has been changed within the background of a Galpha chimera (designated alpha(T)*), comprised mainly of the alpha subunit of retinal transducin (alpha(T)) and the Switch III region from the alpha subunit of G(i1). As expected, both the alpha(T)*(R174C) and alpha(T)*(Q200L) mutants exhibited severely compromised GTPase activity. Neither mutant was capable of responding to aluminum fluoride when monitoring changes in the fluorescence of Trp-207 in Switch II, although both stimulated effector activity in the absence of rhodopsin and Gbetagamma. Surprisingly, each mutant also showed some capability for being activated by rhodopsin and Gbetagamma to undergo GDP-[(35)S]GTPgammaS exchange. The ability of the mutants to couple to rhodopsin was not consistent with the assumption that they contained only bound GTP, prompting us to examine their nucleotide-bound states following their expression and purification from Escherichia coli. Indeed, both mutants contained bound GDP as well as GTP, with 35-45% of each mutant being isolated as GDP-P(i) complexes. Overall, these findings suggest that the R174C and Q200L mutations reveal Galpha subunit states that occur subsequent to GTP hydrolysis but are still capable of fully stimulating effector activity.     

Molecular cloning of a new human G protein. Evidence for two Gi alpha-like protein families

The amino acid sequence of a novel G protein alpha subunit (Gx alpha) has been deduced from the nucleotide sequence of a human cDNA clone isolated from a differentiated HL-60 cDNA library. The cDNA encodes a polypeptide of 354 amino acids (Mr 40,519) which is closely related to Gi alpha proteins. The amino acid sequence homology between Gx alpha and human myeloid Gi alpha is 86% with 15 nonconservative substitutions. Gx alpha also shares 86% homology with both rat brain and mouse macrophage Gi alpha but is more homologous (94%) to bovine brain Gi alpha with only 5 nonconservative amino acid differences. G proteins previously termed Gi alpha may fall into at least two distinct groups, with one including human myeloid Gi alpha, rat brain Gi alpha and mouse macrophage Gi alpha; and other Gx alpha and bovine brain Gi alpha. One group probably contains true Gi and the other a new class of G protein whose function remains to be determined.     

Mutational analysis of the vesicular stomatitis virus glycoprotein G for membrane fusion domains.

The spike glycoprotein G of vesicular stomatitis virus (VSV) induces membrane fusion at low pH. We used linker insertion mutagenesis to characterize the domain(s) of G glycoprotein involved in low-pH-induced membrane fusion. Two or three amino acids were inserted in frame into various positions in the extracellular domain of G, and 14 mutants were isolated. All of the mutants expressed fully glycosylated proteins in COS cells. However, only seven mutant G glycoproteins were transported to the cell surface. Two of these mutants, D1 and A6, showed wild-type fusogenic properties. The mutant A2 had a temperature-sensitive defect in the transport of the mutant G glycoprotein to the cell surface. The other four mutants, H2, H5, H10, and A4, although present in cell surface, failed to induce cell fusion when cells expressing these mutant glycoproteins were exposed to acidic pH. These four mutant G proteins could form trimers, indicating that the defect in fusion was not due to defective oligomerization. One of these mutations, H2, is within a region of conserved, uncharged amino acids that has been proposed as a possible fusogenic sequence. The mutation in H5 was about 70 amino acids downstream of the mutation in H2, while mutations in H10 and A4 were about 300 amino acids downstream of the mutation in H2. Conserved sequences were also noted in the H10 and A4 segment. The results suggest that in the case of VSV G glycoprotein, the fusogenic activity may involve several spatially separated regions in the extracellular domain of the protein.     

Study of the constitutively active form of the alpha subunit of rice heterotrimeric G proteins

We used site-directed mutagenesis to engineer two constitutively active forms of the alpha subunit of a rice heterotrimeric G protein. The recombinant proteins produced from these novel cDNAs had GTP-binding activity but no GTPase activity. A chimeric gene for a constitutively active form of the alpha subunit was introduced into the rice mutant d1, which is defective for the alpha-subunit gene. All the transformants essentially showed a wild-type phenotype compared with normal cultivars, although seed sizes were substantially increased and internode lengths also showed some increase.     

Differential regulation of cellular adhesion and migration by recombinant laminin-5 forms with partial deletion or mutation within the G3 domain of alpha3 chain

The basement membrane protein laminin-5 promotes cell adhesion and migration. The carboxyl-terminal G3 domain in the alpha3 chain is essential for the unique activity of laminin-5. To investigate the function of the G3 domain, we prepared various recombinant laminin-5 forms with a partially deleted or mutated G3 domain. The deletion of the carboxyl-terminal 28 amino acids (region III) markedly decreased the cell adhesion activity with a slight loss of the cell motility activity toward BRL and EJ-1 cells. This change was attributed to the loss of Lys-Arg-Asp sequence. Further deletion of 83 amino acids (region II) led to almost complete loss of the cell motility activity. All charged amino acid residues tested in this region were not responsible for the activity loss. These results suggest that the G3 domain contains two distinct regions that differently regulate cell adhesion and migration. Analysis of laminin-5 receptors showed that integrins alpha3beta1, alpha6beta1, and alpha6beta4 had different but synergistic effects on cell adhesion and migration on laminin-5. However, the structural change of the G3 domain appeared not to change integrin specificity. The present study demonstrates that the G3 domain in laminin-5 plays a central role to produce different biological effects on cells.     

Regulation of G protein-mediated signal transduction by RGS proteins

RGS proteins form a new family of regulatory proteins of G protein signaling. They contain homologous core domains (RGS domains) of about 120 amino acids. RGS domains interact with activated Galpha subunits. Several RGS proteins have been shown biochemically to act as GTPase activating proteins (GAPs) for their interacting Galpha subunits. Other than RGS domains, RGS proteins differ significantly in size, amino acid sequences, and tissue distribution. In addition, many RGS proteins have other protein-protein interaction motifs involved in cell signaling. We have shown that p115RhoGEF, a newly identified GEF(guanine nucleotide exchange factor) for RhoGTPase, has a RGS domain at its N-terminal region and this domain acts as a specific GAP for Galpha12 and Galpha13. Furthermore, binding of activated Galpha13 to this RGS domain stimulated GEF activity of p115RhoGEF. Activated Galpha12 inhibited Galpha13-stimulated GEF activity. Thus p115RhoGEF is a direct link between heterotrimeric G protein and RhoGTPase and it functions as an effector for Galpha12 and Galpha13 in addition to acting as their GAP. We also found that RGS domain at N-terminal regions of G protein receptor kinase 2 (GRK2) specifically interacts with Galphaq/11 and inhibits Galphaq-mediated activation of PLC-beta, apparently through sequestration of activated Galphaq. However, unlike other RGS proteins, this RGS domain did not show significant GAP activity to Galphaq. These results indicate that RGS proteins have far more diverse functions than acting simply as GAPs and the characterization of function of each RGS protein is crucial to understand the G protein signaling network in cells.     

The regulator of G protein signaling RGS4 selectively enhances alpha 2A-adreoreceptor stimulation of the GTPase activity of Go1alpha and Gi2alpha

Agonist-stimulated high affinity GTPase activity of fusion proteins between the alpha(2A)-adrenoreceptor and the alpha subunits of forms of the G proteins G(i1), G(i2), G(i3), and G(o1), modified to render them insensitive to the action of pertussis toxin, was measured following transient expression in COS-7 cells. Addition of a recombinant regulator of G protein signaling protein, RGS4, did not significantly affect basal GTPase activity nor agonist stimulation of the fusion proteins containing Galpha(i1) and Galpha(i3) but markedly enhanced agonist-stimulation of the proteins containing Galpha(i2) and Galpha(o1.) The effect of RGS4 on the alpha(2A)-adrenoreceptor-Galpha(o1) fusion protein was concentration-dependent with EC(50) of 30 +/- 3 nm and the potency of the receptor agonist UK14304 was reduced 3-fold by 100 nm RGS4. Equivalent reconstitution with Asn(88)-Ser RGS4 failed to enhance agonist function on the alpha(2A)-adrenoreceptor-Galpha(o1) or alpha(2A)-adrenoreceptor-Galpha(i2) fusion proteins. Enzyme kinetic analysis of the GTPase activity of the alpha(2A)-adrenoreceptor-Galpha(o1) and alpha(2A)-adrenoreceptor-Galpha(i2) fusion proteins demonstrated that RGS4 both substantially increased GTPase V(max) and significantly increased K(m) of the fusion proteins for GTP. The increase in K(m) for GTP was dependent upon RGS4 amount and is consistent with previously proposed mechanisms of RGS function. Agonist-stimulated GTPase turnover number in the presence of 100 nm RGS4 was substantially higher for alpha(2A)-adrenoreceptor-Galpha(o1) than for alpha(2A)-adrenoreceptor-Galpha(i2). These studies demonstrate that although RGS4 has been described as a generic stimulator of the GTPase activity of G(i)-family G proteins, selectivity of this interaction and quantitative variation in its function can be monitored in the presence of receptor activation of the G proteins.