Prenylation-deficient G protein gamma subunits disrupt GPCR signaling in the zebrafish

Prenylation of G protein gamma (γ) subunits is necessary for the membrane localization of heterotrimeric G proteins and for functional heterotrimeric G protein coupled receptor (GPCR) signaling. To evaluate GPCR signaling pathways during development, we injected zebrafish embryos with mRNAs encoding Gγ subunits mutated so that they can no longer be prenylated. Low-level expression of these prenylation-deficient Gγ subunits driven either ubiquitously or specifically in the primordial germ cells (PGCs) disrupts GPCR signaling and manifests as a PGC migration defect. This disruption results in a reduction of calcium accumulation in the protrusions of migrating PGCs and a failure of PGCs to directionally migrate. When co-expressed with a prenylation-deficient Gγ, 8 of the 17 wildtype Gγ isoforms individually confer the ability to restore calcium accumulation and directional migration. These results suggest that while the Gγ subunits possess the ability to interact with G Beta (β) proteins, only a subset of wildtype Gγ proteins are stable within PGCs and can interact with key signaling components necessary for PGC migration. This in vivo study highlights the functional redundancy of these signaling components and demonstrates that prenylation-deficient Gγ subunits are an effective tool to investigate the roles of GPCR signaling events during vertebrate development.     

Germ cell migration in zebrafish is cyclopamine-sensitive but Smoothened-independent

Primordial germ cells (PGCs) are the progenitors of reproductive cells in metazoans and are an important model for the study of cell migration in vivo. Previous reports have suggested that Hedgehog (Hh) protein acts as a chemoattractant for PGC migration in the Drosophila embryo and that downstream signaling proteins such as Patched (Ptc) and Smoothened (Smo) are required for PGC localization to somatic gonadal precursors. Here we interrogate whether Hh signaling is required for PGC migration in vertebrates, using the zebrafish as a model system. We find that cyclopamine, an inhibitor of Hh signaling, causes strong defects in the migration of PGCs in the zebrafish embryo. However, these defects are not due to inhibition of Smoothened (Smo) by cyclopamine; rather, we find that neither maternal nor zygotic Smo is required for PGC migration in the zebrafish embryo. Cyclopamine instead acts independently of Smo to decrease the motility of zebrafish PGCs, in part by dysregulating cell adhesion and uncoupling cell polarization and translocation. These results demonstrate that Hh signaling is not required for zebrafish PGC migration, and underscore the importance of regulated cell-cell adhesion for cell migration in vivo.     

Gβγ signaling controls the polarization of zebrafish primordial germ cells by regulating Rac activity

During development, primordial germ cells (PGCs) migrate from the sites of their specification towards the region in which the future gonad develops. This cell migration requires polarization of PGCs and their responsiveness to external guidance cues. In zebrafish, the directed migration and polarization of PGCs are regulated independently, by the chemokine Cxcl12a and the Rho GTPase Rac1, respectively. However, the upstream signals controlling Rac activity in this context have not yet been identified. By investigating the role of G proteins in PGC migration, we found that signaling mediated by G protein subunits Gβγ is required to regulate cell polarization. PGCs that are defective for Gβγ signaling failed to polarize, and developed multiple protrusions in random locations, resembling the defects observed in PGCs with decreased Rac activity. These defects render PGCs incapable of migrating actively and responding to directional cues. FRET-based assays showed that PGCs require Gβγ signaling for polarized Rac activation and actin organization at the leading front, as well as for maintaining overall Rac levels in these cells. Conversely, overexpression of Gβγ in PGCs increases Rac activity. Our results indicate that during PGC migration in vivo, Gβγ signaling regulates Rac activity to control cell polarity, which is required for the responsiveness to chemokine signaling.     

Cloning and functional analysis of the Gβ gene Mgb1 and the Gγ gene Mgg1 in Monascus ruber

The ascomycetous fungus Monascus ruber is one of the most well-known species widely used to produce Monascus-fermentation products for natural food colorants and medicine. Our previous research on the Gα subunit Mga1 and the regulator of G protein signaling MrflbA indicated that heterotrimeric G protein signaling pathways were involved in aspects of growth, sporulation and secondary metabolite production in M. ruber. To better understand the G protein signaling pathways in this fungus, a Gβ subunit gene (Mgb1) and a GΓ subunit gene (Mgg1) were cloned and investigated in the current study. The predicted Mgb1 protein consisted of 353 amino acids and Mgg1 consisted of 94 amino acids, sharing marked similarity with Aspergillus Gβ and GΓ subunits, respectively. Targeted deletion (Δ) of Mgb1 or Mgg1 resulted in phenotypic alterations similar to those resulting from ΔMga1, i.e., restricted vegetative growth, lowered asexual sporulation, impaired cleistothecial formation, and enhanced citrinin and pigment production. Moreover, deletion of Mgg1 suppressed the defects in asexual development and in biosynthesis of citrinin and pigment caused by the absence of MrflbA function. These results provide evidence that Mgb1 and Mgg1 form a functional GβΓ dimer and the dimer interacts with Mga1 to mediate signaling pathways, which are negatively controlled by MrflbA, for growth, reproduction and citrinin and pigment biosynthesis in M. ruber.     

Brain-specific Gαz interacts with Src tyrosine kinase to regulate Mu-opioid receptor-NMDAR signaling pathway

There is a certain cross-talk in the nervous system between N-methyl-D-aspartate receptors (NMDARs) and Mu-opioid receptors (MORs). While NMDARs participate in the desensitization of MORs, these in turn modulate NMDAR-mediated glutamate responses. The G protein coupled receptors (GPCRs) activate NMDARs via Src although the role of Gα subunits in this process is not well defined. We have found that in the absence of MOR activation, the brain specific Gαz subunit binds to and stabilizes Src in its inactive form. The administration of morphine provokes the phosphorylation of specific cytosolic tyrosine residues in NMDAR2A subunits. This was achieved by PKCγ disrupting this Gαz–Src complex, enabling Src to be activated (pTyr416) by binding to GαiGTP proteins. These changes increased the activation of the calcium/calmodulin-dependent protein kinase II (CaMKII), thereby promoting MOR desensitization. This regulatory pathway is disrupted by inhibiting PKC, preventing MOR-activated Gαi2 subunits from gaining control over Src. Thus, in neural cells the Gαz subunits exert a negative control on Src function reducing the activating influence of MORs on this tyrosine kinase. This MOR-triggered signaling pathway recruits PKCγ and Gαi subunits to activate Src tyrosine kinase, resulting in the potentiation of NMDAR function. Most relevant, this mechanism which operates in neural cells is essential for the development of tolerance to the analgesic effects of morphine.     

Saccharomyces cerevisiae Gpi2, an accessory subunit of the enzyme catalyzing the first step of glycosylphosphatidylinositol (GPI) anchor biosynthesis,selectively complements some of the functions of its homolog in Candida albicans

GPI2 encodes for one of the six accessory subunits of the GPI-N-acetylglucosaminyltransferase (GPI-GnT) complex that catalyzes the first step of GPI biosynthesis in S. cerevisiae and C. albicans. It has been previously reported in S. cerevisiae that this subunit physically interacts with and negatively modulates Ras signaling. On the other hand, studies from our lab have shown that the homologous subunit in C. albicans is a positive modulator of Ras signaling. Are the functions of this subunit therefore strictly species dependent? We present here functional complementation studies on GPI2 from S. cerevisiae and C. albicans that were carried out to address this issue. Expression of CaGPI2 in a ScGPI2 conditional lethal mutant could not restore its growth defects. Likewise, ScGPI2 overexpression in a CaGPI2 heterozygous mutant could not restore its deficient GPI-GnT activity or reverse defects in its cell wall integrity and could only poorly restore filamentation. However, interestingly, ScGPI2 could restore lanosterol demethylase (CaERG11) levels and reverse azole resistance of the CaGPI2 heterozygote. It appeared to do this by regulating levels of another GPI-GnT subunit, CaGPI19, which we have previously shown to be involved in cross-talk with CaERG11. Thus, the effect of CaGPI2 on sterol biosynthesis in C. albicans is independent of its interaction with the GPI-GnT complex and Ras signaling pathways. In addition, the interaction of Gpi2 with other subunits of the GPI-GnT complex as well as with Ras signaling appears to have evolved differently in the two organisms.     

Analysis of SDF-1/CXCR4 signaling in primordial germ cell migration and survival or differentiation in Xenopus laevis

Directional migration of primordial germ cells (PGCs) toward future gonads is a common feature in many animals. In zebrafish, mouse and chicken, SDF-1/CXCR4 chemokine signaling has been shown to have an important role in PGC migration. In Xenopus, SDF-1 is expressed in several regions in embryos including dorsal mesoderm, the target region that PGCs migrate to. CXCR4 is known to be expressed in PGCs. This relationship is consistent with that of more well-known animals. Here, we present experiments that examine whether chemokine signaling is involved in PGC migration of Xenopus. We investigate: (1) Whether injection of antisense morpholino oligos (MOs) for CXCR4 mRNA into vegetal blastomere containing the germ plasm or the precursor of PGCs disturbs the migration of PGCs? (2) Whether injection of exogenous CXCR4 mRNA together with MOs can restore the knockdown phenotype? (3) Whether the migratory behavior of PGCs is disturbed by the specific expression of mutant CXCR4 mRNA or SDF-1 mRNA in PGCs? We find that the knockdown of CXCR4 or the expression of mutant CXCR4 in PGCs leads to a decrease in the PGC number of the genital ridges, and that the ectopic expression of SDF-1 in PGCs leads to a decrease in the PGC number of the genital ridges and an increase in the ectopic PGC number. These results suggest that SDF-1/CXCR4 chemokine signaling is involved in the migration and survival or in the differentiation of PGCs in Xenopus.     

Extra-large G proteins have extra-large effects on agronomic traits and stress tolerance in maize and rice

Heterotrimeric G proteins – comprising Gα, Gβ, and Gγ subunits – are ubiquitous elements in eukaryotic cell signaling. Plant genomes contain both canonical Gα subunit genes and a family of plant-specific extra-large G protein genes (XLGs) that encode proteins consisting of a domain with Gα-like features downstream of a long N-terminal domain. In this review we summarize phenotypes modulated by the canonical Gα and XLG proteins of arabidopsis and highlight recent studies in maize and rice that reveal dramatic phenotypic consequences of XLG clustered regularly interspaced short palindromic repeats (CRISPR) mutagenesis in these important crop species. XLGs have both redundant and specific roles in the control of agronomically relevant plant architecture and resistance to both abiotic and biotic stresses. We also point out areas of current controversy, suggest future research directions, and propose a revised, phylogenetically-based nomenclature for XLG protein genes.     

Identification and isolation of common and tissue-specific geranylgeranylated gamma subunits of guanine-nucleotide-binding regulatory proteins in various tissues.

Heterotrimeric guanine-nucleotide-binding regulatory proteins (G proteins) have been classified into several subtypes on the basis of the properties of their alpha subunits, though a notable multiplicity of gamma subunits has also been demonstrated. To investigate whether each subtype of alpha subunit is associated with a particular gamma subunit, various oligomeric G proteins, purified from bovine tissues, were subjected to gel electrophoresis in a Tricine buffer system. All G proteins examined were shown to have more than two kinds of gamma subunit. Of the brain G proteins, GoA, GoB, and Gi1 contain the same set of three gamma subunits, but Gi2 contains only two of these subunits. Lung Gi1 and Gi2 and spleen Gi2 and Gi3 had similar sets of two gamma subunits, one of which was distinct from the gamma subunits of brain G proteins. These observations indicate that each subtype of alpha subunit is associated with a variety of beta gamma subunits, and that the combinations differ among cells. For analyses of the structural diversity of the gamma subunits, beta gamma subunits were purified from the total G proteins of each tissue and subjected to reverse-phase HPLC under denaturing conditions, where none of the beta subunits were eluted from the column. Three distinct gamma subunits were isolated in this way from brain beta gamma subunits. In contrast, lung and spleen beta gamma subunits contained at least five gamma subunits, the elution positions and electrophoretic mobilities of which were indistinguishable between the two tissues. Among several gamma subunits, two subspecies appeared to be common to the three tissues. In fact, in each case, the partial amino acid sequence of the most abundant gamma subunit in each tissue was identical, and the sequences coincided exactly with that of 'gamma 6' [Robishaw, J. D., Kalman, V. K., Moomaw, C. R. & Slaughter, C. A. (1989) J. Biol. Chem. 264, 15758-15761]. Fast-atom-bombardment mass spectrometry analysis indicated that this abundant gamma subunit in lung and spleen was geranylgeranylated and carboxymethylated at the C-terminus, as was 'gamma 6' from brain. In addition to abundant gamma subunits, other tissue-specific gamma subunits were also shown to be geranylgeranylated by gas-chromatography-coupled mass spectrometry analysis of Raney nickel-treated gamma subunits. These results suggest that most gamma subunits associated with many different subtypes of alpha subunit are geranylgeranylated in a variety of tissues, with the single exception being the retina where the G protein transducin has a farnesylated gamma subunit.     

Loss of cAMP-specific phosphodiesterase rescues spore development in G protein mutant in Dictyostelium

Cyclic AMP (cAMP) is an important intracellular signaling molecule for many G protein-mediated signaling pathways but the specificity of cAMP signaling in cells with multiple signaling pathways is not well-understood. In Dictyostelium, at least two different G protein signaling pathways, mediated by the Gα2 and Gα4 subunits, are involved with cAMP accumulation, spore production, and chemotaxis and the stimulation of these pathways results in the activation of ERK2, a mitogen-activated protein kinase that can down regulate the cAMP-specific phosphodiesterase RegA. The regA gene was disrupted in gα2⁻ and gα4⁻ cells to determine if the absence of this phosphodiesterase rescues the development of these G protein mutants as it does for erk2⁻ mutants. The regA⁻ mutation had no major effects on developmental morphology but enriched the distribution of the Gα mutant cells to the prespore/prestalk border in chimeric aggregates. The loss of RegA function had no effect on Gα4-mediated folate chemotaxis. However, the regA gene disruption in gα4⁻ cells, but not in gα2⁻ cells, resulted in a substantial rescue and acceleration of spore production. This rescue in sporulation required cell autonomous signaling because the precocious sporulation could not be induced through intercellular signaling in chimeric aggregates. However, intercellular signals from regA⁻ strains increased the expression of the prestalk gene ecmB and accelerated the vacuolization of stalk cells. Intercellular signaling from the gα4⁻regA⁻ strain did not induce ecmA gene expression indicating cell-type specificity in the promotion of prestalk cell development. regA gene disruption in a Gα4^HC (Gα4 overexpression) strain did not result in precocious sporulation or stalk cell development indicating that elevated Gα4 subunit expression can mask regA⁻ associated phenotypes even when provided with wild-type intercellular signaling. These findings indicate that the Gα2 and Gα4-mediated pathways provide different contributions to the development of spores and stalk cells and that the absence of RegA function can bypass some but not all defects in G protein regulated spore development.     

Dominant negative mutations in the α-factor receptor, a G protein-coupled receptor encoded by the STE2 gene of the yeast Saccharomyces cerevisiae

The α-mating pheromone receptor encoded by the STE2 gene of the yeast Saccharomyces cerevisiae is a G protein-coupled receptor (GPCR) that is homologous to the large family of GPCRs that mediate multiple types of signal transduction in mammals. We have screened libraries of mutant receptors to identify dominant negative alleles that are capable of interfering with the function of a co-expressed normal receptor. Two dominant negative alleles have been recovered in this manner. In addition, we find that previously isolated loss-of-function mutations in the α-factor receptor exhibit dominant negative effects. Detection of the dominant effects requires high-level expression of the mutant receptors but does not require a high ratio of mutant to normal receptors. Cellular levels of the normal receptors are not affected by co-expression of the dominant negative alleles. Expression of the mutant receptors does not interfere with constitutive signaling in a strain that lacks the G protein α subunit encoded by GPA1, indicating that interference with signaling occurs at the level of the receptor or the interacting G protein. Expression of increased levels of G protein subunits partially reverses the dominant negative effects. The dominant negative behavior of the mutant receptors is diminished by deletion of the SST2 gene, which encodes an RGS (Regulator of G protein Signaling) protein involved in desensitization of pheromone signaling. The most likely explanation for the dominant negative effects of the mutations appears to be the existence of an interaction between unactivated receptors and the trimeric G protein that titrates the G protein away from the normal receptors or renders the G protein insensitive to receptor activation. This interaction appears to be mediated by the SST2 gene product.     

Heterotrimeric G protein subunits differentially respond to endoplasmic reticulum stress in Arabidopsis

Canonical heterotrimeric G proteins in eukaryotes are major components that localize at plasma membrane and transmit extracellular stimuli into the cell. Genome of a seed plant Arabidopsis thaliana encodes at least one Gα (GPA1), one Gβ (AGB1), and 3 Gγ (AGG1, AGG2 and AGG3) subunits. The loss-of-function mutations of G protein subunit(s) cause multiple defects in development as well as biotic and abiotic stress responses. However, it remains elusive how these subunits differentially express these defects. Here, we report that Arabidopsis heterotrimeric G protein subunits differentially respond to the endoplasmic reticulum (ER) stress. An isolated homozygous mutant of AGB1, agb1-3, was more sensitive to the tunicamycin-induced ER stress compared to the wild type and the other loss-of-function mutants of G protein subunits. Moreover, ER stress responsive genes were highly expressed in the agb1-3 plant. Our results indicate that AGB1 positively contributes to ER stress tolerance in Arabidopsis.     

Evidence for an unusual transmembrane configuration of AGG3, a class C Gγ subunit of Arabidopsis

Heterotrimeric G proteins are crucial for the perception of external signals and subsequent signal transduction in animal and plant cells. In both model systems, the complex comprises one Gα, one Gβ, and one Gγ subunit. However, in addition to the canonical Gγ subunits (class A), plants also possess two unusual, plant‐specific classes of Gγ subunits (classes B and C) that have not yet been found in animals. These include Gγ subunits lacking the C–terminal CaaX motif (class B), which is important for membrane anchoring of the protein; the presence of such subunits gives rise to a flexible sub‐population of Gβ/γ heterodimers that are not necessarily restricted to the plasma membrane. Plants also contain class C Gγ subunits, which are twice the size of canonical Gγ subunits, with a predicted transmembrane domain and a large cysteine‐rich extracellular C–terminus. However, neither the presence of the transmembrane domain nor the membrane topology have been unequivocally demonstrated. Here, we provide compelling evidence that AGG3, a class C Gγ subunit of Arabidopsis, contains a functional transmembrane domain, which is sufficient but not essential for plasma membrane localization, and that the cysteine‐rich C–terminus is extracellular.     

Characterization of non-canonical G beta-like protein FvGbb2 and its relationship with heterotrimeric G proteins in Fusarium verticillioides

Fusarium verticillioides is a fungal pathogen that is responsible for maize ear rot and stalk rot diseases worldwide. The fungus also produces carcinogenic mycotoxins, fumonisins on infested maize. Unfortunately, we still lack clear understanding of how the pathogen responds to host and environmental stimuli to trigger fumonisin biosynthesis. The heterotrimeric G protein complex, consisting of canonical Gα, Gβ and Gγ subunits, is involved in transducing signals from external stimuli to regulate downstream signal transduction pathways. Previously, we demonstrated that Gβ protein FvGbb1 directly impacts fumonisin regulation but not other physiological aspects in F. verticillioides. In this study, we identified and characterized a RACK1 (Receptor for Activated C Kinase 1) homolog FvGbb2 as a putative Gβ-like protein in F. verticillioides. The mutant exhibited severe defects not only in fumonisin biosynthesis but also vegetative growth and conidiation. FvGbb2 was positively associated with carbon source utilization and stress agents but negatively regulated general amino acid control. While FvGbb2 does not interact with canonical G protein subunits, it may associate with diverse proteins in the cytoplasm to regulate vegetative growth, virulence, fumonisin biosynthesis and stress response in F. verticillioides.     

Ste18p Is a Positive Control Element in the Mating Process of Candida albicans

Heterotrimeric G proteins are an important class of eukaryotic signaling molecules that have been identified as central elements in the pheromone response pathways of many fungi. In the fungal pathogen Candida albicans, the STE18 gene (ORF19.6551.1) encodes a potential γ subunit of a heterotrimeric G protein; this protein contains the C-terminal CAAX box characteristic of γ subunits and has sequence similarity to γ subunits implicated in the mating pathways of a variety of fungi. Disruption of this gene was shown to cause sterility of MTLa mating cells and to block pheromone-induced gene expression and shmoo formation; deletion of just the CAAX box residues is sufficient to inactivate Ste18 function in the mating process. Intriguingly, ectopic expression behind the strong ACT1 promoter of either the Gα or the Gβ subunit of the heterotrimeric G protein is able to suppress the mating defect caused by deletion of the Gγ subunit and restore both pheromone-induced gene expression and morphology changes.     

Chemotactic Signaling by Single-Chain Chemoreceptors

Bacterial chemoreceptors of the methyl-accepting chemotaxis protein (MCP) family operate in commingled clusters that enable cells to detect and track environmental chemical gradients with high sensitivity and precision. MCP homodimers of different detection specificities form mixed trimers of dimers that facilitate inter-receptor communication in core signaling complexes, which in turn assemble into a large signaling network. The two subunits of each homodimeric receptor molecule occupy different locations in the core complexes. One subunit participates in trimer-stabilizing interactions at the trimer axis, the other lies on the periphery of the trimer, where it can interact with two cytoplasmic proteins: CheA, a signaling autokinase, and CheW, which couples CheA activity to receptor control. As a possible tool for independently manipulating receptor subunits in these two structural environments, we constructed and characterized fused genes for the E. coli serine chemoreceptor Tsr that encoded single-chain receptor molecules in which the C-terminus of the first Tsr subunit was covalently connected to the N-terminus of the second with a polypeptide linker. We showed with soft agar assays and with a FRET-based in vivo CheA kinase assay that single-chain Tsr~Tsr molecules could promote serine sensing and chemotaxis responses. The length of the connection between the joined subunits was critical. Linkers nine residues or shorter locked the receptor in a kinase-on state, most likely by distorting the native structure of the receptor HAMP domain. Linkers 22 or more residues in length permitted near-normal Tsr function. Few single-chain molecules were found as monomer-sized proteolytic fragments in cells, indicating that covalently joined receptor subunits were responsible for mediating the signaling responses we observed. However, cysteine-directed crosslinking, spoiling by dominant-negative Tsr subunits, and rearrangement of ligand-binding site lesions revealed subunit swapping interactions that will need to be taken into account in experimental applications of single-chain chemoreceptors.     

Hypoxia impairs primordial germ cell migration in zebrafish (Danio rerio) embryos

Background

As a global environmental concern, hypoxia is known to be associated with many biological and physiological impairments in aquatic ecosystems. Previous studies have mainly focused on the effect of hypoxia in adult animals. However, the effect of hypoxia and the underlying mechanism of how hypoxia affects embryonic development of aquatic animals remain unclear.

Methodology/Principal Findings

In the current study, the effect of hypoxia on primordial germ cell (PGC) migration in zebrafish embryos was investigated. Hypoxic embryos showed PGC migration defect as indicated by the presence of mis-migrated ectopic PGCs. Insulin-like growth factor (IGF) signaling is required for embryonic germ line development. Using real-time PCR, we found that the mRNA expression levels of insulin-like growth factor binding protein (IGFBP-1), an inhibitor of IGF bioactivity, were significantly increased in hypoxic embryos. Morpholino knockdown of IGFBP-1 rescued the PGC migration defect phenotype in hypoxic embryos, suggesting the role of IGFBP-1 in inducing PGC mis-migration.

Conclusions/Significance

This study provides novel evidence that hypoxia disrupts PGC migration during embryonic development in fish. IGF signaling is shown to be one of the possible mechanisms for the causal link between hypoxia and PGC migration. We propose that hypoxia causes PGC migration defect by inhibiting IGF signaling through the induction of IGFBP-1.     

Ric-8 regulation of heterotrimeric G proteins

Abstract

Resistance to inhibitors of cholinesterase 8 proteins (Ric-8A and Ric-8B) collectively bind the four classes of heterotrimeric G protein α subunits. Ric-8A and Ric-8B act as non-receptor guanine nucleotide exchange factors (GEFs) toward the Gα subunits that each binds in vitro and seemingly regulate diverse G protein signaling systems in cells. Combined evidence from worm, fly and mammalian systems has shown that Ric-8 proteins are required to maintain proper cellular abundances of G proteins. Ric-8 proteins support G protein levels by serving as molecular chaperones that promote Gα subunit biosynthesis. In this review, the evidence that Ric-8 proteins act as non-receptor GEF activators of G proteins in signal transduction contexts will be weighed against the evidence supporting the molecular chaperoning function of Ric-8 in promoting G protein abundance. I will conclude by suggesting that Ric-8 proteins may act in either capacity in specific contexts. The field awaits additional experimentation to delineate the putative multi-functionality of Ric-8 towards G proteins in cells.