Nuclear localization of G protein beta 5 and regulator of G protein signaling 7 in neurons and brain

The role that Gbeta(5) regulator of G protein signaling (RGS) complexes play in signal transduction in brain remains unknown. The subcellular localization of Gbeta(5) and RGS7 was examined in rat PC12 pheochromocytoma cells and mouse brain. Both nuclear and cytosolic localization of Gbeta(5) and RGS7 was evident in PC12 cells by immunocytochemical staining. Subcellular fractionation of PC12 cells demonstrated Gbeta(5) immunoreactivity in the membrane, cytosolic, and nuclear fractions. Analysis by limited proteolysis confirmed the identity of Gbeta(5) in the nuclear fraction. Subcellular fractionation of mouse brain demonstrated Gbeta(5) and RGS7 but not Ggamma(2/3) immunoreactivity in the nuclear fraction. RGS7 and Gbeta(5) were tightly complexed in the brain nuclear extract as evidenced by their coimmunoprecipitation with anti-RGS7 antibodies. Chimeric protein constructs containing green fluorescent protein fused to wild-type Gbeta(5) but not green fluorescent fusion proteins with Gbeta(1) or a mutant Gbeta(5) impaired in its ability to bind to RGS7 demonstrated nuclear localization in transfected PC12 cells. These findings suggest that Gbeta(5) undergoes nuclear translocation in neurons via an RGS-dependent mechanism. The novel intracellular distribution of Gbeta(5).RGS protein complexes suggests a potential role in neurons communicating between classical heterotrimeric G protein subunits and/or their effectors at the plasma membrane and the cell nucleus.     

Regulators of G protein signaling exhibit distinct patterns of gene expression and target G protein specificity in human lymphocytes

The newly recognized regulators of G protein signaling (RGS) attenuate heterotrimeric G protein signaling pathways. We have cloned an IL-2-induced gene from human T cells, cytokine-responsive gene 1, which encodes a member of the RGS family, RGS16. The RGS16 protein binds Gialpha and Gqalpha proteins present in T cells, and inhibits Gi- and Gq-mediated signaling pathways. By comparison, the mitogen-induced RGS2 inhibits Gq but not Gi signaling. Moreover, the two RGS genes exhibit marked differences in expression patterns. The IL-2-induced expression of the RGS16 gene in T cells is suppressed by elevated cAMP, whereas the RGS2 gene shows a reciprocal pattern of regulation by these stimuli. Because the mitogen and cytokine receptors that trigger expression of RGS2 and RGS16 in T cells do not activate heterotrimeric G proteins, these RGS proteins and the G proteins that they regulate may play a heretofore unrecognized role in T cell functional responses to Ag and cytokine activation.     

Snapin interacts with the N-terminus of regulator of G protein signaling 7

The N-terminus of regulator of G protein signaling 7 (RGS7) contains a dishevelled/egl-10/pleckstrin (DEP) domain of unknown function. To gain insight into its function, we used yeast two-hybrid analysis to screen a human whole brain cDNA library in order to identify proteins that interact specifically with the N-terminus of human RGS7 (amino acid residues 1-248). From this analysis, we identified snapin, a protein associated with the SNARE complex in neurons, as an interactor with the N-terminus of RGS7. Deletion mutation analysis in yeast demonstrated that the interaction between RGS7 and snapin is specific and is mediated primarily by amino acid residues 1-69 of RGS7 (which contains the proximal portion of the DEP domain). The interaction between RGS7 and snapin was also demonstrated in mammalian cells by coimmunoprecipitation and pull-down assays. Our results suggest that RGS7 could play a role in synaptic vesicle exocytosis through its interaction with snapin.     

GPR158/179 regulate G protein signaling by controlling localization and activity of the RGS7 complexes

The extent and temporal characteristics of G protein-coupled receptor (GPCR) signaling are shaped by the regulator of G protein signaling (RGS) proteins, which promote G protein deactivation. With hundreds of GPCRs and dozens of RGS proteins, compartmentalization plays a key role in establishing signaling specificity. However, the molecular details and mechanisms of this process are poorly understood. In this paper, we report that the R7 group of RGS regulators is controlled by interaction with two previously uncharacterized orphan GPCRs: GPR158 and GPR179. We show that GPR158/179 recruited RGS complexes to the plasma membrane and augmented their ability to regulate GPCR signaling. The loss of GPR179 in a mouse model of night blindness prevented targeting of RGS to the postsynaptic compartment of bipolar neurons in the retina, illuminating the role of GPR179 in night vision. We propose that the interaction of RGS proteins with orphan GPCRs promotes signaling selectivity in G protein pathways.     

Regulators of G protein signaling (RGS proteins): novel central nervous system drug targets.

Many drugs of abuse signal through receptors that couple to G proteins (GPCRs), so the factors that control GPCR signaling are likely to be important to the understanding of drug abuse. Contributions by the recently identified protein family, regulators of G protein signaling (RGS) to the control of GPCR function are just beginning to be understood. RGS proteins can accelerate the deactivation of G proteins by 1000-fold and in cell systems they profoundly inhibit signaling by many receptors, including mu-opioid receptors. Coupled with the known dynamic regulation of RGS protein expression and function, they are of obvious interest in understanding tolerance and dependence mechanisms. Furthermore, drugs that could inhibit their activity could be useful in preventing the development of or in treating drug dependence.     

Purification and identification of G protein-coupled receptor protein complexes under native conditions

G protein-coupled receptors (GPCRs) constitute the largest family of membrane receptors and are of major therapeutic importance. The identification of GPCR-associated proteins is an important step toward a better understanding of these receptors. However, current methods are not satisfying as only isolated receptor domains (intracellular loops or carboxyl-terminal tails) can be used as "bait." We report here a method based on tandem affinity purification coupled to mass spectrometry that overcomes these limitations as the entire receptor is used to identify protein complexes formed in living mammalian cells. The human MT(1) and MT(2) melatonin receptors were chosen as model GPCRs. Both receptors were tagged with the tandem affinity purification tag at their carboxyl-terminal tails and expressed in human embryonic kidney 293 cells. Receptor solubilization and purification conditions were optimized. The method was validated by the co-purification of G(i) proteins, which are well known GPCR interaction partners but which are difficult to identify with current protein-protein interaction assays. Several new and functionally relevant MT(1)- and MT(2)-associated proteins were identified; some of them were common to both receptors, and others were specific for each subtype. Taken together, our protocol allowed for the first time the purification of GPCR-associated proteins under native conditions in quantities suitable for mass spectrometry analysis.     

Regulators of G protein signaling proteins as determinants of the rate of desensitization of presynaptic calcium channels.

Norepinephrine inhibits omega-conotoxin GVIA-sensitive presynaptic Ca2+ channels in chick dorsal root ganglion neurons through two pathways, one mediated by Go and the other by Gi. These pathways desensitize at different rates. We have found that recombinant Galpha interacting protein (GAIP) and regulators of G protein signaling (RGS)4 selectively accelerate the rate of desensitization of Go- and Gi-mediated pathways, respectively. Blockade of endogenous RGS proteins using antibodies raised against Galpha interacting protein and RGS4 slows the rate of desensitization of these pathways in a selective manner. These results demonstrate that different RGS proteins may interact with Gi and Go selectively, giving rise to distinct time courses of transmitter-mediated effects.     

A conserved protein interaction interface on the type 5 G protein beta subunit controls proteolytic stability and activity of R7 family regulator of G protein signaling proteins

Regulators of G protein signaling (RGS) proteins of the R7 subfamily limit signaling by neurotransmitters in the brain and by light in the retina. They form obligate complexes with the Gβ5 protein that are subject to proteolysis to control their abundance and alter signaling. The mechanisms that regulate this proteolysis, however, remain unclear. We used genetic screens to find mutations in Gβ5 that selectively destabilize one of the R7 RGS proteins in Caenorhabditis elegans. These mutations cluster at the binding interface between Gβ5 and the N terminus of R7 RGS proteins. Equivalent mutations within mammalian Gβ5 allowed the interface to still bind the N-terminal DEP domain of R7 RGS proteins, and mutant Gβ5-R7 RGS complexes initially formed in cells but were then rapidly degraded by proteolysis. Molecular dynamics simulations suggest the mutations weaken the Gβ5-DEP interface, thus promoting dynamic opening of the complex to expose determinants of proteolysis known to exist on the DEP domain. We propose that conformational rearrangements at the Gβ5-DEP interface are key to controlling the stability of R7 RGS protein complexes.     

IL-6 and IL-12 specifically regulate the expression of Rab5 and Rab7 via distinct signaling pathways

Recent studies have shown that phagosome maturation depends on the balance between pro-inflammatory and anti-inflammatory cytokines, indicating that cytokine modulates phagosome maturation. However, the mechanism of cytokine-mediated modulation of intracellular trafficking remains to be elucidated. Here, we have shown that treatment of macrophages with IL-6 specifically induce the expression of Rab5 through the activation of extracellular signal-regulated kinase, whereas IL-12 exclusively upregulate the expression of Rab7 through the activation of p38 MAPK. We have cloned the 5'-flanking regions of the rab5c or rab7 into the promoterless reporter vector. Our results have shown that cells transfected with rab5c chimera are transactivated by IL-6, and IL-12 specifically transactivates cells containing rab7 chimera. Moreover, our results also show that IL-12 induces lysosomal transport, whereas IL-6 stimulates the fusion between early compartments in macrophages and accordingly modulates Salmonella trafficking and survival in macrophages. This is the first demonstration showing that cytokine differentially regulates endocytic trafficking by controlling the expression of appropriate Rab GTPase, and provides insight into the mechanism of cytokine-mediated regulation of intracellular trafficking.     

Population differences in the frequency of the agouti signaling protein g.8818a>G polymorphism

The role of agouti signaling protein (ASIP) in human pigmentation pathways is not definitively understood although its murine homologue regulates, in part, pheomelanogenesis. We have reported an association of a polymorphism in the 3'-untranslated region of ASIP (g.8818A>G) with dark hair and eye color among a group of European-Americans (Am J Hum Genet 2002 March;70:770). Among 147 healthy control subjects, the frequency of the G-allele was 0.12. We hypothesized that this polymorphism would occur at different frequencies among different population groups. Using PCR-RFLP, we genotyped 25 East Asian, 86 African-American, and 207 West African individuals for the ASIP g.8818A>G polymorphism. The g.8818G-allele was present in the West African sample at a frequency of 0.80, in the African-American sample at a frequency of 0.62, and in the East Asian sample at 0.28. The difference in allele frequency among population groups was statistically significant (P < 0.0001). Although the effect of the g.8818A>G polymorphism upon ASIP function is unknown, the large difference in allele frequency between our West African and European-American sample populations lends support to the notion that this gene may be important in human pigmentation.     

Differential functions of G protein and Baz-aPKC signaling pathways in Drosophila neuroblast asymmetric division

Drosophila melanogaster neuroblasts (NBs) undergo asymmetric divisions during which cell-fate determinants localize asymmetrically, mitotic spindles orient along the apical-basal axis, and unequal-sized daughter cells appear. We identified here the first Drosophila mutant in the Ggamma1 subunit of heterotrimeric G protein, which produces Ggamma1 lacking its membrane anchor site and exhibits phenotypes identical to those of Gbeta13F, including abnormal spindle asymmetry and spindle orientation in NB divisions. This mutant fails to bind Gbeta13F to the membrane, indicating an essential role of cortical Ggamma1-Gbeta13F signaling in asymmetric divisions. In Ggamma1 and Gbeta13F mutant NBs, Pins-Galphai, which normally localize in the apical cortex, no longer distribute asymmetrically. However, the other apical components, Bazooka-atypical PKC-Par6-Inscuteable, still remain polarized and responsible for asymmetric Miranda localization, suggesting their dominant role in localizing cell-fate determinants. Further analysis of Gbetagamma and other mutants indicates a predominant role of Partner of Inscuteable-Galphai in spindle orientation. We thus suggest that the two apical signaling pathways have overlapping but different roles in asymmetric NB division.     

An antagonism between the AKT and beta-adrenergic signaling pathways mediated through their reciprocal effects on miR-199a-5p

We have recently reported that downregulation of miR-199a-5p is necessary and sufficient for inducing upregulation of its targets, including hypoxia-inducible factor-1alpha (Hif-1α) and Sirt1, during hypoxia preconditioning (HPC). Conversely, others and we have reported that miR-199a-5p is upregulated during cardiac hypertrophy. Thus, the objective of this study was to delineate the signaling pathways that regulate the expression of miR-199a-5p and its targets, and their role in myocyte survival during hypoxia. Since HPC is mediated through activation of the AKT pathway, we questioned if AKT is sufficient for inducing downregulation of miR-199a-5p. Our present study shows that overexpression of a constitutively active AKT (caAKT) induced 70% reduction in miR-199a-5p and was associated with a robust increase in HiF-1α (10 ± 2 fold) and Sirt1 (4 ± 0.8 fold) that was reversed by overexpression of miR-199a-5p. Similarly, insulin receptor-stimulated activation of the AKT pathway induced downregulation of miR-199a-5p and upregulation of its targets. In contrast, β-adrenergic receptor (βAR) activation in vitro and in vivo, induced 1.8–3.5-fold increase in miR-199a-5p. Accordingly, we predicted that βAR would antagonize AKT-induced, miR-199a-5p-dependent, upregulation of Hif-1α and Sirt1. Indeed, pre-treating the myocytes with isoproterenol before applying HPC, caAKT, or insulin resulted in 87 ± 3%, 75 ± 15%, and 100% reductions in Hif-1α expression, respectively, and sensitized the cells to hypoxic injury. Thus, activation of beta-adrenergic signaling counteracts the survival effects of the AKT pathway via upregulating miR-199a-5p.     

Specific inhibition of capped mRNA translation in vitro by m7G5''pppp5''G and m7G5''pppp5''m7G.

A unique set of diguanosine cap analogues containing a 5'-5' tetraphosphate linkage instead of the normal triphosphate was synthesized by chemical methylation of G5'pppp5'G. Both 7-methylguanosine products, m7G5'pppp5'G and m7G5'pppp5'm7G, acted as potent inhibitors of capped brome mosaic virus (BMV) RNA translation in the homologous wheat germ protein synthesis system. Inhibition of in vitro protein synthesis required the presence of the 7-methyl group on guanosine and was specific for capped mRNA. In comparison with the partial cap analogue, m7GTP, the methylated diguanosine tetraphosphate structures were 25-50 fold more potent inhibitors of in vitro protein synthesis. Analysis of the in vitro translation products of the four species of BMV RNA showed a differential sensitivity to inhibition by m7G5'pppp5'm7G.     

Role of cdk5 and tau phosphorylation in heterotrimeric G protein-mediated retinal growth cone collapse.

During axonal growth, repulsive guidance cues cause growth cone collapse and retraction. In the chick embryo, membranes from the posterior part of the optic tectum containing ephrins are original collapsing factors for axons growing from the temporal retina. We investigated signal transduction pathways in retinal axons underlying this membrane-evoked collapse. Perturbation experiments using pertussis toxin (PTX) showed that membrane-induced collapse is mediated via G(o/i) proteins, as is the case for semaphorin/collapsin-1-induced collapse. Studies with Indo-1 revealed that growth cone collapse by direct activation of G(o/i) proteins with mastoparan did not cause elevation of the intracellular Ca(2+) level, and thus this signal transduction pathway is Ca(2+) independent. Application of the protein phosphatase inhibitor okadaic acid alone induced growth cone collapse in retinal culture, suggesting signals involving protein dephosphorylation. In addition, pretreatment of retinal axons with olomoucine, a specific inhibitor of cdk5 (tau kinase II), prevented mastoparan-evoked collapse. Olomoucine also blocks caudal tectal membrane-mediated collapse. These results suggest that rearrangement of the cytoskeleton is mediated by tau phosphorylation. Immunostaining visualized complementary distributions of tau phospho- and dephosphoisoforms within the growth cone, which also supports the involvement of tau. Taking these findings together, we conclude that cdk5 and tau phosphorylation probably lie downstream of growth cone collapse signaling mediated by PTX-sensitive G proteins.