The N54-αs Mutant Has Decreased Affinity for ßγ and Suggests a Mechanism for Coupling Heterotrimeric G Protein Nucleotide Exchange with Subunit Dissociation.

Ser54 of Gsα binds guanine nucleotide and Mg2+ as part of a conserved sequence motif in GTP binding proteins. Mutating the homologous residue in small and heterotrimeric G proteins generates dominant-negative proteins, but by protein-specific mechanisms. For αi/o, this results from persistent binding of α to ßγ, whereas for small GTP binding proteins and αs this results from persistent binding to guanine nucleotide exchange factor or receptor. This work examined the role of ßγ interactions in mediating the properties of the Ser54-like mutants of Gα subunits. Unexpectedly, WT-αs or N54-αs coexpressed with α1B-adrenergic receptor in human embryonic kidney 293 cells decreased receptor stimulation of IP3 production by a cAMP-independent mechanism, but WT-αs was more effective than the mutant. One explanation for this result would be that αs, like Ser47 αi/o, blocks receptor activation by sequestering ßγ; implying that N54-αS has reduced affinity for ßγ since it was less effective at blocking IP3 production. This possibility was more directly supported by the observation that WT-αs was more effective than the mutant in inhibiting ßγ activation of phospholipase Cß2. Further, in vitro synthesized N54-αs bound biotinylated-ßγ with lower apparent affinity than did WT-αs The Cys54 mutation also decreased ßγ binding but less effectively than N54-αs Substitution of the conserved Ser in αo with Cys or Asn increased ßγ binding, with the Cys mutant being more effective. This suggests that Ser54 of αs is involved in coupling changes in nucleotide binding with altered subunit interactions, and has important implications for how receptors activate G proteins.

Synthesis and assembly of G protein ßγ dimers: comparison of in vitro and in vivo studies.

The heterotrimeric GTP-binding proteins (G proteins) are the canonical cellular machinery used with the approximately 700 G protein-coupled receptors (GPCRs) in the human genome to transduce extracellular signals across the plasma membrane. The synthesis of the constituent G protein subunits, and their assembly into Gßγ dimers and G protein heterotrimers, determines the signaling repertoire for G-protein/GPCR signaling in cells. These synthesis/assembly -processes are intimately related to two other overlapping events in the intricate pathway leading to formation of G protein signaling complexes, posttranslational modification and intracellular trafficking of G proteins. The assembly of the Gßγ dimer is a complex process involving multiple accessory proteins and organelles. The mechanisms involved are becoming increasingly appreciated, but are still incompletely understood. In vitro and in vivo (cellular) studies provide different perspectives of these processes, and a comparison of them can provide insight into both our current level of understanding and directions to be taken in future investigations.

Sequence dependence and differential expression of Ggamma5 subunit isoforms of the heterotrimeric G proteins variably processed after prenylation in mammalian cells.

Between 1 and 2% of proteins coded for in the human genome, including all G protein gamma subunits, are predicted to be prenylated. Subsequently, prenylated proteins are proteolytically cleaved at the C terminus and carboxymethylated. These reactions are generally obligatory events required for functional expression of prenylated proteins. The biological role of prenyl substrates has made these reactions significant targets for anticancer drug development. Understanding the enzymology of this pathway will be key to success for this strategy. When Ggamma1, -2, -4, -10, -11, -12, and -13 were expressed in HEK293 cells they were completely processed according to the current understanding of the prenylation reaction. In contrast, Ggamma5 was processed to two forms; a minor one, fully processed as predicted, and a major one that was prenylated without further processing. When the Ca(1)a(2)X motif of Ggamma5, CSFL, was exchanged for that of Ggamma2, CAIL, Ggamma5 was completely processed. Conversely, Ggamma2-SFL was incompletely processed. Differential processing of Ggamma5 was found due to the presence of an aromatic amino acid in its Ca(1)a(2)X motif. Retrieving endogenous Ggamma subunits from HEK293 or Neuro-2a cells with FLAG-Gbeta constructs identified multiple Ggamma subunits by mass spectrometry in either cell, but in both cases the most prominent one was Ggamma5 expressed without C-terminal processing after prenylation. This work indicates that post-prenylation reactions can generate multiple products determined by the C-terminal Ca(1)a(2)X motif. Within the human genome 10% of predicted prenylated proteins have aromatic amino acids in their Ca(1)a(2)X sequence and would likely generate the prenylation pattern described here.

Role of the chaperonin CCT/TRiC complex in G protein betagamma-dimer assembly.

Gbetagamma dimer formation occurs early in the assembly of heterotrimeric G proteins. On nondenaturing (native) gels, in vitro translated, (35)S-labeled Ggamma subunits traveled primarily according to their pI and apparently were not associated with other proteins. In contrast, in vitro translated, (35)S-labeled Gbeta subunits traveled at a high apparent molecular mass (approximately 700 kDa) and co-migrated with the chaperonin CCT complex (also called TRiC). Different FLAG-Gbeta isoforms coprecipitated CCT/TRiC to a variable extent, and this correlated with the ability of the different Gbeta subunits to efficiently form dimers with Ggamma. When translated Ggamma was added to translated Gbeta, a new band of low apparent molecular mass (approximately 50 kDa) was observed, which was labeled by either (35)S-labeled Gbeta or Ggamma, indicating that it is a dimer. Formation of the Gbetagamma dimer was ATP-dependent and inhibited by either adenosine 5'-O-(thiotriphosphate) or aluminum fluoride in the presence of Mg(2+). This inhibition led to increased association of Gbeta with CCT/TRiC. Although Ggamma did not bind CCT/TRiC, addition of Ggamma to previously synthesized Gbeta caused its release from the CCT/TRiC complex. We conclude that the chaperonin CCT/TRiC complex binds to and folds Gbeta subunits and that CCT/TRiC mediates Gbetagamma dimer formation by an ATP-dependent reaction.

Bring your own G protein.

G protein-coupled receptor (GPCR)-Galpha fusion proteins were first characterized more than 10 years ago as a strategy for studying receptor-G protein signaling. A large number of studies have used this approach to characterize receptor coupling to members of the Gs, Gi, and Gq families of Galpha subunits, but this strategy has not been widely used to study Galpha12 and Galpha13. As described in the article by Zhang et al. in this issue of Molecular Pharmacology (p. 1433) characterization of the signaling properties of thromboxane A2 receptor (TPalpha) -Galpha12 and -Galpha13 fusion constructs demonstrates the applicability of this strategy to members of this unique family of Galpha subunits, and how this strategy can be used to resolve otherwise difficult problems of receptor pharmacology associated with these proteins. The general strategy of making receptor-Galpha fusion constructs has wide applicability to a number of research problems, but there are perhaps also "hidden messages" in how different receptor-Galpha subunit fusion pairs behave.

Proteomic analysis of bovine brain G protein gamma subunit processing heterogeneity.

We characterized the variable processing of the G protein gamma subunit isoforms associated with bovine brain G proteins, a primary mediator of cellular communication. Ggamma subunits were isolated from purified brain G proteins and characterized by Edman sequencing, by MALDI MS, by chemical and/or enzymatic fragmentation assayed by MALDI MS, and by MS/MS fragmentation and sequencing. Multiple forms of six different Ggamma isoforms were detected. Significant variation in processing was found at both the amino termini and particularly the carboxyl termini of the proteins. All Ggamma isoforms contain a carboxyl-terminal CAAX motif for prenylation, carboxyl-terminal proteolysis, and carboxymethylation. Characterization of these proteins indicates significant variability in the normal processing of all of these steps in the prenylation reaction, including a new variation of prenyl processing resulting from cysteinylation of the carboxyl terminus. These results have multiple implications for intracellular signaling mechanisms by G proteins, for the role of prenyl processing variation in cell signaling, and for the site of action and consequences of drugs that target the prenylation modification.

Genomic analysis of G protein gamma subunits in human and mouse - the relationship between conserved gene structure and G protein betagamma dimer formation.

Analysis of the genomic sequences, cDNAs and expressed sequence tags (ESTs) in human and mouse for the 12 genes of the gamma subunits of the heterotrimeric G proteins has allowed us to identify the common versus unique elements of the organization and expression of the members of this important gene family. All of the G protein gamma subunit genes are organized around two coding exons, each containing about 100 nucleotides coding for 30-40 amino acids. These two exons each correspond to a functional domain of the protein, which interestingly appears to impose constraints on both the structure of the protein and the structure of the gene. There is large variation in the intron size between these two coding exons, the number and size of 5' and 3' UTRs, and the overall size of the genes. There is general but not absolute conservation in the size and structure of these genes between humans and mice. Alternative splicing and potential differential promoter usage were detected for several Ggamma subunits, indicating possible differential regulation in expression. Only for Ggamma10, however, did we find an alternative coding transcript. This alternative transcript appears to code for a hybrid protein containing a DnaJ domain in place of its Ggamma exon 1 domain, joined to the Ggamma10 second exon domain. The predicted mRNA is expressed in humans, and the protein coded by it is readily translated in vitro. This protein does not form a functional G protein betagamma dimer, but it could generate a chaperone-like protein related to its DNA-J domain. These studies suggest that alternative splicing is not a prominent mechanism for generating G protein subunit diversity from within the human or mouse genomes. Instead, each of the known 12 gamma subunit genes generate transcripts with one prevalent protein.

G Protein betagamma dimer formation: Gbeta and Ggamma differentially determine efficiency of in vitro dimer formation.

The Gbeta and Ggamma subunit of the heterotrimeric G proteins form a functional dimer that is stable once assembled in vivo or in vitro. The requirements, mechanism, and specificity of dimer formation are still incompletely understood, but represent important biochemical processes involved in the specificity of cellular signaling through G proteins. Here, seven Gbeta and 12 FLAG-epitope-tagged Ggamma subunits were separately synthesized in vitro using a rabbit reticulocyte lysate expression system. The translation products were combined and dimers isolated by immunoprecipitation. Gbeta1 and Gbeta4 formed dimers with all Ggamma subunit isoforms, generally with Gbeta/Ggamma stoichiometries between 0.2:1 and 0.5:1. Gbeta5, Gbeta5L, and Gbeta3s did not form significant amounts of dimer with any of the gamma subunit isoforms. Gbeta2 and Gbeta3 formed dimers with selected Ggamma isoforms to levels intermediate between that of Gbeta1/Gbeta4 and Gbeta3s/Gbeta5/Gbeta5L. We also expressed selected Gbetagamma in HEK293 cells and measured PLCbeta2 activity. Gbetagamma dimer-dependent increases in IP3 production were seen with most Gbeta1, Gbeta2, and Gbeta5 combinations, indicating functional dimer expression in intact cells. These results define the complete set of G protein betagamma dimers that are formed using a single biochemical assay method and suggest that there are Gbeta isoform-specific factors in rabbit reticulocyte lysates that determine the efficacy of Gbetagamma dimer formation.

Complex haplotype structure of the human GNAS gene identifies a recombination hotspot centred on a single nucleotide polymorphism widely used in association studies.

The alpha subunit of the heterotrimeric G protein Gs (Gsalpha) is involved in numerous physiological processes and is a primary determinant of cellular responses to extracellular signals. Genetic variations in the Gsalpha gene may play an important role in complex diseases and drug responses. To characterize the genetic diversity in this locus, we resequenced exons and flanking introns of the gene in 44 genomic samples and analysed the haplotype structure of the gene in an additional 50 African-Americans and 50 Caucasians. Significant differences in allele frequency for nearly all the genotyped single nucleotide polymorphism (SNPs) were detected between the two ethnic groups. Linkage disequilibrium (LD) analysis of this locus revealed two haplotype blocks characterized by strong LD and reduced haplotype diversity, especially in Caucasians. Between the two blocks is a narrow (approximately 3 kb) recombination hotspot centred on exons 4 and 5, and a widely used genetic marker in association studies in this region (rs7121) was in linkage equilibrium with the rest of the gene. The haplotype structure of the GNAS locus warrants reevaluation of previous association studies that used marker rs7121 and affects choice of SNP markers to be used in future studies of this locus.

A dominant negative Galphas mutant that prevents thyroid-stimulating hormone receptor activation of cAMP production and inositol 1,4,5-trisphosphate turnover: competition by different G proteins for activation by a common receptor.

A Ser to Asn mutation at position 54 of the alpha subunit of G(s) (designated N54-alpha(s)) was characterized after transient expression of it with various components of the receptor-adenylyl cyclase pathway in COS-1, COS-7, and HEK 293 cells. Previous studies of the N54-alpha(s) mutant revealed that it has a conditional dominant negative phenotype that prevents hormone-stimulated increases in cAMP without interfering with the regulation of basal cAMP levels (Cleator, J. H., Mehta, N. D., Kurtz, D. K., Hildebrandt, J. D. (1999) FEBS Lett. 243, 205-208). Experiments reported here were conducted to localize the mechanism of the dominant negative effect of the mutant. Competition studies conducted with activated alpha(s)* (Q212L) showed that the N54 mutant did not work down-stream by blocking the interaction of endogenous alpha(s) with adenylyl cyclase. The co-expression of wild type or N54-alpha(s) along with the thyroid-stimulating hormone (TSH) receptor and adenylyl cyclase isotypes differing with respect to betagamma stimulation (AC II or AC III) revealed that the phenotype of the mutant is not dependent upon the presence of adenylyl cyclase isoforms regulated by betagamma. These studies ruled out a downstream site of action of the mutant. To investigate an upstream site of action, N54-alpha(s) was co-expressed with either the TSH receptor that activates both alpha(s) and alpha(q) or with the alpha(1B)-adrenergic receptor that activates only alpha(q). N54-alpha(s) failed to inhibit alpha(1B)-adrenergic receptor stimulation of inositol 1,4,5-trisphosphate production but did inhibit TSH stimulation of inositol 1,4,5-trisphosphate. These results show that G(s) and G(q) compete for activation by the TSH receptor. They also indicate that the N54 protein has a dominant negative phenotype by blocking upstream receptor interactions with normal G proteins. This phenotype is different from that seen in analogous mutants of other G protein alpha subunits and suggests that either regulation or protein-protein interactions differ among G protein alpha subunits.

Gamma 2 subunit of G protein heterotrimer is an N-end rule ubiquitylation substrate.

Heterotrimeric G proteins transduce signals from activated transmembrane G protein-coupled receptors to appropriate downstream effectors within cells. Signaling specificity is achieved in part by the specific alpha, beta, and gamma subunits that compose a given heterotrimer. Additional structural and functional diversity in these subunits is generated at the level of posttranslational modification, offering alternate regulatory mechanisms for G protein signaling. Presented here is the identification of a variant of the gamma(2) subunit of G protein heterotrimer purified from bovine brain and the demonstration that this RDTASIA gamma(2) variant, containing unique amino acid sequence at its N terminus, is a substrate for ubiquitylation and degradation via the N-end rule pathway. Although N-end-dependent degradation has been shown to have important functions in peptide import, chromosome segregation, angiogenesis, and cardiovascular development, the identification of cellular substrates in mammalian systems has remained elusive. The isolation of RDTASIA gamma(2) from a native tissue represents identification of a mammalian N-end rule substrate from a physiological source, and elucidates a mechanism for the targeting of G protein gamma subunits for ubiquitylation and degradation.

Pertussis toxin-insensitive activation of the heterotrimeric G-proteins Gi/Go by the NG108-15 G-protein activator.

A ligand-independent activator of heterotrimeric brain G-protein was partially purified from detergent-solubilized extracts of the neuroblastoma-glioma cell hybrid NG108-15. The G-protein activator (NG108-15 G-protein activator (NG-GPA)) increased [(35)S]guanosine 5'-O-(thiotriphosphate) ([(35)S]GTPgammaS) to purified brain G-protein in a magnesium-dependent manner and promoted GDP dissociation from Galpha(o). The NG-GPA also increased GTPgammaS binding to purified, recombinant Galpha(i2), Galpha(i3), and Galpha(o), but minimally altered nucleotide binding to purified transducin. The NG-GPA increased GTPgammaS binding to membrane-bound G-proteins and inhibited basal, forskolin- and hormone-stimulated adenylyl cyclase activity in DDT(1)-MF-2 cell membranes. In contrast to G-protein coupled receptor-mediated activation of heterotrimeric G-proteins in DDT(1)-MF-2 cell membrane preparations, the action of the NG-GPA was not altered by treatment of the cells with pertussis toxin. ADP-ribosylation of purified brain G-protein also failed to alter the increase in GTPgammaS binding elicited by the NG-GPA. Thus, the NG-GPA acts in a manner distinct from that of a G-protein coupled receptor and other recently described receptor-independent activators of G-protein signaling. These data indicate the presence of unexpected regulatory domains on G(i)/G(o) proteins and suggest the existence of pertussis toxin-insensitive modes of signal input to G(i)/G(o) signaling systems.