The role of electrostatic interactions in the regulation of the membrane association of G protein beta gamma heterodimers

In this paper we report calculations of electrostatic interactions between the transducin (G(t)) betagamma heterodimer (G(t)betagamma) and phospholipid membranes. Although membrane association of G(t)betagamma is due primarily to the hydrophobic penetration into the membrane interior of a farnesyl chain attached to the gamma subunit, structural studies have revealed that there is a prominent patch of basic residues on the surface of the beta subunit surrounding the site of farnesylation that is exposed upon dissociation from the G(t)alpha subunit. Moreover, phosducin, which produces dissociation of G(t)betagamma from membranes, interacts directly with G(t)betagamma and introduces a cluster of acidic residues into this region. The calculations, which are based on the finite difference Poisson-Boltzmann method, account for a number of experimental observations and suggest that charged residues play a role in mediating protein-membrane interactions. Specifically, the calculations predict the following. 1) Favorable electrostatic interactions enhance the membrane partitioning due to the farnesyl group by an order of magnitude although G(t)betagamma has a large net negative charge (-12). 2) This electrostatic attraction positions G(t)betagamma so that residues implicated in mediating the interaction of G(t)betagamma with its membrane-bound effectors are close to the membrane surface. 3) The binding of phosducin to G(t)betagamma diminishes the membrane partitioning of G(t)betagamma by an order of magnitude. 4) Lowering the ionic strength of the solution converts the electrostatic attraction into a repulsion. Sequence analysis and homology model building suggest that our conclusions may be generalized to other Gbetagamma and phosducin isoforms as well.     

Role of the isoprenyl pocket of the G protein beta gamma subunit complex in the binding of phosducin and phosducin-like protein

Phosducin (Pdc) and phosducin-like protein (PhLP) regulate G protein-mediated signaling by binding to the betagamma subunit complex of heterotrimeric G proteins (Gbetagamma) and removing the dimer from cell membranes. The binding of Pdc induces a conformational change in the beta-propeller structure of Gbetagamma, creating a pocket between blades 6 and 7. It has been proposed that the isoprenyl group of Gbetagamma inserts into this pocket, stabilizing the Pdc.Gbetagamma structure and decreasing the affinity of the complex for the lipid bilayer. To test this hypothesis, the binding of Pdc and PhLP to several Gbetagamma dimers containing variants of the beta or gamma subunit was measured. These variants included modifications of the isoprenyl group (gamma), residues involved in the conformational change (beta), and residues lining the proposed prenyl pocket (beta). Switching prenyl groups from farnesyl to geranylgeranyl or vice versa had little effect on binding. However, alanine substitution of one residue in the beta subunit involved in the conformational change (W332) decreased binding 5-fold. Alanine substitution of certain residues within the prenyl pocket caused only minor decreases in binding, while a lysine substitution of T329 within the pocket inhibited binding 10-fold. Molecular modeling of the binding energy of the Pdc.Gbeta(1)gamma(2) complex required insertion of the geranylgeranyl group into the prenyl pocket in order to accurately predict the effects of prenyl pocket amino acid substitutions. Finally, a dimer containing a gamma subunit with no prenyl group (gamma(2)-C68S) decreased binding by nearly 20-fold. These results support the structural model in which the prenyl group escapes contact with the aqueous milieu by inserting into the prenyl pocket and stabilizing the Pdc-binding conformation of Gbetagamma.     

Characterizing the interactions between the two subunits of the p101/p110gamma phosphoinositide 3-kinase and their role in the activation of this enzyme by G beta gamma subunits.

Recently, we have reported the purification and cloning of a novel G protein betagamma subunit-activated phosphoinositide 3-kinase from pig neutrophils. The enzyme comprises a p110gamma catalytic subunit and a p101 regulatory subunit. Now we have cloned the human ortholog of p101 and generated panels of p101 and p110gamma truncations and deletions and used these in in vitro and in vivo assays to determine the protein domains responsible for subunit interaction and activation by betagamma subunits. Our results suggest large areas of p101 including both N- and C-terminal portions interact with the N-terminal half of p110gamma. While modifications of the N terminus of p110gamma could modulate its intrinsic catalytic activity, binding to the N-terminal region of p101 was found to be indispensable for activation of heterodimers with Gbetagamma.     

Phosphorylation of phosducin and phosducin-like protein by G protein-coupled receptor kinase 2

G protein-coupled receptor kinase 2 (GRK2) is able to phosphorylate a variety of agonist-occupied G protein-coupled receptors (GPCR) and plays an important role in GPCR modulation. However, recent studies suggest additional cellular functions for GRK2. Phosducin and phosducin-like protein (PhLP) are cytosolic proteins that bind Gbetagamma subunits and act as regulators of G-protein signaling. In this report, we identify phosducin and PhLP as novel GRK2 substrates. The phosphorylation of purified phosducin and PhLP by recombinant GRK2 proceeds rapidly and stoichiometrically (0.82 +/- 0.1 and 0.83 +/- 0.09 mol of P(i)/mol of protein, respectively). The phosphorylation reactions exhibit apparent K(m) values in the range of 40-100 nm, strongly suggesting that both proteins could be endogenous targets for GRK2 activity. Our data show that the site of phosducin phosphorylation by GRK2 is different and independent from that previously reported for the cAMP-dependent protein kinase. Analysis of GRK2 phosphorylation of a variety of deletion mutants of phosducin and PhLP indicates that the critical region for GRK2 phosphorylation is localized in the C-terminal domain of both phosducin and PhLP (between residues 204 and 245 and 195 and 218, respectively). This region is important for the interaction of these proteins with G beta gamma subunits. Phosphorylation of phosducin by GRK2 markedly reduces its G beta gamma binding ability, suggesting that GRK2 may modulate the activity of the phosducin protein family by disrupting this interaction. The identification of phosducin and PhLP as new substrates for GRK2 further expands the cellular roles of this kinase and suggests new mechanisms for modulating GPCR signal transduction.     

Regulation of angiotensin II-induced G protein signaling by phosducin-like protein

Phosducin-like protein (PhLP) is a broadly expressed member of the phosducin (Pd) family of G protein betagamma subunit (Gbetagamma)-binding proteins. Though PhLP has been shown to bind Gbetagamma in vitro, little is known about its physiological function. In the present study, the effect of PhLP on angiotensin II (Ang II) signaling was measured in Chinese hamster ovary cells expressing the type 1 Ang II receptor and various amounts of PhLP. Up to 3.6-fold overexpression of PhLP had no effect on Ang II-stimulated inositol trisphosphate (IP(3)) formation, whereas further increases caused an abrupt decrease in IP(3) production with half-maximal inhibition occurring at 6-fold PhLP overexpression. This threshold level for inhibition corresponds to the cellular concentration of cytosolic chaperonin complex, a recently described binding partner that preferentially binds PhLP over Gbetagamma. Results of pertussis toxin sensitivity, GTPgammaS binding, and immunoprecipitation experiments suggest that PhLP inhibits phospholipase Cbeta activation by dual mechanisms: (i) steric blockage of Gbetagamma activation of PLCbeta and (ii) interference with Gbetagamma-dependent cycling of G(q)alpha by the receptor. These results suggest that G protein signaling may be regulated through controlling the cellular concentration of free PhLP by inducing its expression or by regulating its binding to the chaperonin.     

The phosducin-like protein PhLP1 is essential for G{beta}{gamma} dimer formation in Dictyostelium discoideum

Phosducin proteins are known to inhibit G protein-mediated signaling by sequestering Gbetagamma subunits. However, Dictyostelium discoideum cells lacking the phosducin-like protein PhLP1 display defective rather than enhanced G protein signaling. Here we show that green fluorescent protein (GFP)-tagged Gbeta (GFP-Gbeta) and GFP-Ggamma subunits exhibit drastically reduced steady-state levels and are absent from the plasma membrane in phlp1(-) cells. Triton X-114 partitioning suggests that lipid attachment to GFP-Ggamma occurs in wild-type cells but not in phlp1(-) and gbeta(-) cells. Moreover, Gbetagamma dimers could not be detected in vitro in coimmunoprecipitation assays with phlp1(-) cell lysates. Accordingly, in vivo diffusion measurements using fluorescence correlation spectroscopy showed that while GFP-Ggamma proteins are present in a complex in wild-type cells, they are free in phlp1(-) and gbeta(-) cells. Collectively, our data strongly suggest the absence of Gbetagamma dimer formation in Dictyostelium cells lacking PhLP1. We propose that PhLP1 serves as a cochaperone assisting the assembly of Gbeta and Ggamma into a functional Gbetagamma complex. Thus, phosducin family proteins may fulfill hitherto unsuspected biosynthetic functions.     

Phosducin-like proteins in Dictyostelium discoideum: implications for the phosducin family of proteins

Retinal phosducin is known to sequester transducin Gbetagamma, thereby modulating transducin activity. Phosducin is a member of a family of phosducin-like proteins (PhLP) found in eukaryotes. Phylogeny of 33 phosducin-like proteins from metazoa, plants and lower eukaryotes identified three distinct groups named phosducin-I-III. We discovered three phlp genes in Dictyostelium, each encoding a phosducin-like protein of a different group. Disruption of the phlp1 gene strongly impaired G-protein signalling, apparently due to mislocalization of Gbetagamma in phlp1-null cells. GFP-Gbeta and GFP-Ggamma are membrane associated in wild-type cells, but cytosolic in phlp1-null cells. Phlp2 disruption is lethal due to a synchronous collapse of the cells after 16-17 cell divisions. Phlp3 disruptants show no abnormal phenotype. These results establish a role for phosducin-like proteins in facilitating folding, localization or function of proteins, in addition to modulating G-protein signalling.     

Ubiquitylation of the transducin betagamma subunit complex. Regulation by phosducin

G proteins (Galphabetagamma) are essential signaling molecules, which dissociate into Galpha and Gbetagamma upon activation by heptahelical membrane receptors. We have identified the betagamma subunit complex of the photoreceptor-specific G protein, transducin (T), as a target of the ubiquitin-proteasome pathway. Ubiquitylated species of the transducin gamma-subunit (Tgamma) but not the alpha- or beta-subunits were assembled de novo in bovine photoreceptor preparations. In addition, Tgamma was exclusively ubiquitylated when Tbetagamma was dissociated from Talpha. Ubiquitylation of Tbetagamma on Tgamma was selectively catalyzed by human ubiquitin-conjugating enzymes UbcH5 and UbcH7 and was coincident with degradation of the entire Tbetagamma subunit complex in vitro by a mechanism requiring ATP and the proteasome. We also show that Tbetagamma association with phosducin, a photoreceptor-specific protein of unknown physiological function, blocks Tbetagamma ubiquitylation and subsequent degradation. Phosphorylation of phosducin by Ca(2+)/calmodulin-dependent protein kinase II, which inhibits phosducin-Tbetagamma complex formation, completely restored Tbetagamma ubiquitylation and degradation. We conclude that Tbetagamma is a substrate of the ubiquitin-proteasome pathway and suggest that phosducin serves to protect Tbetagamma following the light-dependent dissociation of Talphabetagamma.     

The pleckstrin homology domain of phospholipase C-beta(2) links the binding of gbetagamma to activation of the catalytic core

Pleckstrin homology (PH) domains are membrane tethering devices found in many signal transducing proteins. These domains also couple to the betagamma subunits of GTP binding proteins (G proteins), but whether this association transmits allosteric information to the catalytic core is unclear. To address this question, we constructed protein chimeras in which the PH domain of phospholipase C-beta(2) (PLC-beta(2)), which is regulated by Gbetagamma, replaces the PH domain of PLC-delta(1) which binds to, but is not regulated by, Gbetagamma. We found that attachment of the PH domain of PLC-beta(2) onto PLC-delta(1) not only causes the membrane-binding properties of PLC-delta(1) to become similar to those of PLC-beta(2), but also results in a Gbetagamma-regulated enzyme. Thus, PH domains are more than simple tethering devices and mediate regulatory signals to the host protein.     

A small region in phosducin inhibits G-protein betagamma-subunit function.

G-protein betagamma-subunits (G(betagamma)) are active transmembrane signalling components. Their function recently has been observed to be regulated by the cytosolic protein phosducin. We show here that a small fragment (amino acids 215-232) contained in the C-terminus of phosducin is sufficient for high-affinity interactions with G(betagamma). Corresponding peptides not only disrupt G(betagamma)-G(alpha) interactions, as defined by G(betagamma)-stimulated GTPase activity of alpha(o), but also other G(betagamma)-mediated functions. The NMR structure of a peptide encompassing this region shows a loop exposing the side chains of Glu223 and Tyr224, and peptides with a substitution of either of these amino acids show a complete loss of activity towards G(o). Mutation of this Tyr224 to Ala in full-length phosducin reduced the functional activity of phosducin to that of phosducin's isolated N-terminus, indicating the importance of this residue within the short, structurally defined C-terminal segment. This small peptide derived from phosducin, may represent a model of a G(betagamma) inhibitor, and illustrates the potential of small compounds to affect G(betagamma) functions.     

Fluorescence analysis of receptor-G protein interactions in cell membranes

The dynamics of G protein heterotrimer complex formation and disassembly in response to nucleotide binding and receptor activation govern the rate of responses to external stimuli. We use a novel flow cytometry approach to study the effects of lipid modification, isoform specificity, lipid environment, and receptor stimulation on the affinity and kinetics of G protein subunit binding. Fluorescein-labeled myristoylated Galpha(i1) (F-alpha(i1)) was used as the ligand bound to Gbetagamma in competition binding studies with differently modified Galpha subunit isoforms. In detergent solutions, the binding affinity of Galpha(i) to betagamma was 2 orders of magnitude higher than for Galpha(o) and Galpha(s) (IC50 of 0.2 nM vs 17 and 27 nM, respectively), while in reconstituted bovine brain lipid vesicles, binding was slightly weaker. The effects of receptor on the G protein complex were assessed in alpha(2A)AR receptor expressing CHO cell membranes into which purified betagamma subunits and F-alpha(i1) were reconstituted. These cell membrane studies led to the following observations: (1) binding of alpha subunit to the betagamma was not enhanced by receptor in the presence or absence of agonist, indicating that betagamma contributed essentially all of the binding energy for alpha(i1) interaction with the membrane; (2) activation of the receptor facilitated GTPgammaS-stimulated detachment of F-alpha(i1) from betagamma and the membrane. Thus flow cytometry permits quantiatitive and real-time assessments of protein-protein interactions in complex membrane environments.     

Molecular determinants for G protein betagamma modulation of ionotropic glycine receptors

The ligand-gated ion channel superfamily plays a critical role in neuronal excitability. The functions of glycine receptor (GlyR) and nicotinic acetylcholine receptor are modulated by G protein betagamma subunits. The molecular determinants for this functional modulation, however, are still unknown. Studying mutant receptors, we identified two basic amino acid motifs within the large intracellular loop of the GlyR alpha(1) subunit that are critical for binding and functional modulation by Gbetagamma. Mutations within these sequences demonstrated that all of the residues detected are important for Gbetagamma modulation, although both motifs are necessary for full binding. Molecular modeling predicts that these sites are alpha-helixes near transmembrane domains 3 and 4, near to the lipid bilayer and highly electropositive. Our results demonstrate for the first time the sites for G protein betagamma subunit modulation on GlyRs and provide a new framework regarding the ligand-gated ion channel superfamily regulation by intracellular signaling.     

Role of the G protein gamma subunit in beta gamma complex modulation of phospholipase Cbeta function

The G protein betagamma complex regulates a wide range of effectors, including the phospholipase C isozymes (PLCbetas). Different domains on the beta subunit are known to contact phospholipase Cbeta and affect its regulation. In contrast, the role of the gamma subunit in Gbetagamma modulation of PLCbeta function is not known. Results here show that the gamma subunit C-terminal domain is involved in mediating Gbetagamma interactions with phospholipase Cbeta. Mutations were introduced to alter the position of the post-translational prenyl modification at the C terminus of the gamma subunit with reference to the beta subunit. These mutants were appropriately post-translationally modified with the geranylgeranyl moiety. A deletion that shortened the C-terminal domain, insertions that extended this domain, and a point mutation, F59A, that disrupted the interaction of this domain with the beta subunit were all affected in their ability to activate PLCbeta to varying degrees. All mutants, however, interacted equally effectively with the G(o)alpha subunit. The results indicate that the G protein gamma subunit plays a direct role in the modulation of effector function by the betagamma complex.     

G protein modulation of N-type calcium channels is facilitated by physical interactions between syntaxin 1A and Gbetagamma

The direct modulation of N-type calcium channels by G protein betagamma subunits is considered a key factor in the regulation of neurotransmission. Some of the molecular determinants that govern the binding interaction of N-type channels and Gbetagamma have recently been identified (see, i.e., Zamponi, G. W., Bourinet, E., Nelson, D., Nargeot, J., and Snutch, T. P. (1997) Nature 385, 442-446); however, little is known about cellular mechanisms that modulate this interaction. Here we report that a protein of the presynaptic vesicle release complex, syntaxin 1A, mediates a crucial role in the tonic inhibition of N-type channels by Gbetagamma. When syntaxin 1A was coexpressed with (N-type) alpha(1B) + alpha(2)-delta + beta(1b) channels in tsA-201 cells, the channels underwent a 18 mV negative shift in half-inactivation potential, as well as a pronounced tonic G protein inhibition as assessed by its reversal by strong membrane depolarizations. This tonic inhibition was dramatically attenuated following incubation with botulinum toxin C, indicating that syntaxin 1A expression was indeed responsible for the enhanced G protein modulation. However, when G protein betagamma subunits were concomitantly coexpressed, the toxin became ineffective in removing G protein inhibition, suggesting that syntaxin 1A optimizes, rather than being required for G protein modulation of N-type channels. We also demonstrate that Gbetagamma physically binds to syntaxin 1A, and that syntaxin 1A can simultaneously interact with Gbetagamma and the synprint motif of the N-type channel II-III linker. Taken together, our experiments suggest a mechanism by which syntaxin 1A mediates a colocalization of G protein betagamma subunits and N-type calcium channels, thus resulting in more effective G protein coupling to, and regulation of, the channel. Thus, the interactions between syntaxin, G proteins, and N-type calcium channels are part of the structural specialization of the presynaptic terminal.     

Phosducin-like protein acts as a molecular chaperone for G protein betagamma dimer assembly

Phosducin-like protein (PhLP) is a widely expressed binding partner of the G protein betagamma subunit dimer (Gbetagamma). However, its physiological role is poorly understood. To investigate PhLP function, its cellular expression was blocked using RNA interference, resulting in inhibition of Gbetagamma expression and G protein signaling. This inhibition was caused by an inability of nascent Gbetagamma to form dimers. Phosphorylation of PhLP at serines 18-20 by protein kinase CK2 was required for Gbetagamma formation, while a high-affinity interaction of PhLP with the cytosolic chaperonin complex appeared unnecessary. PhLP bound nascent Gbeta in the absence of Ggamma, and S18-20 phosphorylation was required for Ggamma to associate with the PhLP-Gbeta complex. Once Ggamma bound, PhLP was released. These results suggest a mechanism for Gbetagamma assembly in which PhLP stabilizes the nascent Gbeta polypeptide until Ggamma can associate, resulting in membrane binding of Gbetagamma and release of PhLP to catalyze another round of assembly.     

Reassembly of phospholipase C-beta2 from separated domains: analysis of basal and G protein-stimulated activities

Phosphatidylinositol-specific phospholipase C-betas (PLC-betas) are the only PLC isoforms that are regulated by G protein subunits. To further understand the regulation of PLC-beta(2) by G proteins and the functional roles of PLC-beta(2) structural domains, we tested whether the separately expressed amino and carboxyl halves of PLC-beta(2) could associate to form catalytically active enzymes as two polypeptides, and we explored how the complexes thus formed would be regulated by G protein betagamma subunits (Gbetagamma). We expressed cDNA constructs encoding PLC-beta(2) fragments of different lengths in COS-7 cells and demonstrated by coimmunoprecipitation that the coexpressed fragments could assemble and functionally reconstitute an active PLC-beta(2). The pleckstrin homology domain of PLC-beta(2) was required for its targeting to the membrane and for substrate hydrolysis. Reconstituted enzymes that contained the linker region that joins the two catalytic domains were as active or more active than the wild-type PLC-beta(2). When the linker region was removed, basal PLC-beta(2) enzymatic activity was increased further, suggesting that the linker region exerts an inhibitory effect on basal PLC-beta(2) activity. The reconstituted enzymes, like wild-type PLC-beta(2), were activated by Gbetagamma; when the C-terminal region was present in these constructs, they were also activated by Galpha(q). Gbetagamma and Galpha(q) activated these PLC-beta(2) constructs equally in the presence or absence of the linker region. We conclude that the linker region is an inhibitory element in PLC-beta(2) and that Gbetagamma and Galpha(q) do not stimulate PLC-beta(2) through easing the inhibition of enzymatic activity by the linker region.     

Mapping of calmodulin and Gbetagamma binding domains within the C-terminal region of the metabotropic glutamate receptor 7A

Ca(2+)/calmodulin (Ca(2+)/CaM) and the betagamma subunits of heterotrimeric G-proteins (Gbetagamma) have recently been shown to interact in a mutually exclusive fashion with the intracellular C terminus of the presynaptic metabotropic glutamate receptor 7 (mGluR 7). Here, we further characterized the core CaM and Gbetagamma binding sequences. In contrast to a previous report, we find that the CaM binding motif localized in the N-terminal region of the cytoplasmic tail domain of mGluR 7 is conserved in the related group III mGluRs 4A and 8 and allows these receptors to also bind Ca(2+)/CaM. Mutational analysis of the Ca(2+)/CaM binding motif is consistent with group III receptors containing a conventional CaM binding site formed by an amphipathic alpha-helix. Substitutions adjacent to the core CaM target sequence selectively prevent Gbetagamma binding, suggesting that the CaM-dependent regulation of signal transduction involves determinants that overlap with but are different from those mediating Gbetagamma recruitment. In addition, we present evidence that Gbetagamma uses distinct nonoverlapping interfaces for interaction with the mGluR 7 C-terminal tail and the effector enzyme adenylyl cyclase II, respectively. Although Gbetagamma-mediated signaling is abolished in receptors lacking the core CaM binding sequence, alpha subunit activation, as assayed by agonist-dependent GTPgammaS binding, was not affected. This suggests that Ca(2+)/CaM may alter the mode of group III mGluR signaling from mono- (alpha) to bidirectional (alpha and betagamma) activation of downstream effector cascades.     

Gbetagamma inhibits Galpha GTPase-activating proteins by inhibition of Galpha-GTP binding during stimulation by receptor

Gbetagamma subunits modulate several distinct molecular events involved with G protein signaling. In addition to regulating several effector proteins, Gbetagamma subunits help anchor Galpha subunits to the plasma membrane, promote interaction of Galpha with receptors, stabilize the binding of GDP to Galpha to suppress spurious activation, and provide membrane contact points for G protein-coupled receptor kinases. Gbetagamma subunits have also been shown to inhibit the activities of GTPase-activating proteins (GAPs), both phospholipase C (PLC)-betas and RGS proteins, when assayed in solution under single turnover conditions. We show here that Gbetagamma subunits inhibit G protein GAP activity during receptor-stimulated, steady-state GTPase turnover. GDP/GTP exchange catalyzed by receptor requires Gbetagamma in amounts approximately equimolar to Galpha, but GAP inhibition was observed with superstoichiometric Gbetagamma. The potency of inhibition varied with the GAP and the Galpha subunit, but half-maximal inhibition of the GAP activity of PLC-beta1 was observed with 5-10 nM Gbetagamma, which is at or below the concentrations of Gbetagamma needed for regulation of physiologically relevant effector proteins. The kinetics of GAP inhibition of both receptor-stimulated GTPase activity and single turnover, solution-based GAP assays suggested a competitive mechanism in which Gbetagamma competes with GAPs for binding to the activated, GTP-bound Galpha subunit. An N-terminal truncation mutant of PLC-beta1 that cannot be directly regulated by Gbetagamma remained sensitive to inhibition of its GAP activity, suggesting that the Gbetagamma binding site relevant for GAP inhibition is on the Galpha subunit rather than on the GAP. Using fluorescence resonance energy transfer between cyan or yellow fluorescent protein-labeled G protein subunits and Alexa532-labeled RGS4, we found that Gbetagamma directly competes with RGS4 for high-affinity binding to Galpha(i)-GDP-AlF4.     

Regulation of Xenopus oocyte meiosis arrest by G protein betagamma subunits

BACKGROUND: Progesterone induces the resumption of meiosis (maturation) in Xenopus oocytes through a nongenomic mechanism involving inhibition of an oocyte adenylyl cyclase and reduction of intracellular cAMP. However, progesterone action in Xenopus oocytes is not blocked by pertussis toxin, and this finding indicates that the inhibition of the oocyte adenylyl cyclase is not mediated by the alpha subunits of classical G(i)-type G proteins. RESULTS: To investigate the possibility that G protein betagamma subunits, rather than alpha subunits, play a key role in regulating oocyte maturation, we have employed two structurally distinct G protein betagamma scavengers (G(t)alpha and betaARK-C(CAAX)) to sequester free Gbetagamma dimers. We demonstrated that the injection of mRNA encoding either of these Gbetagamma scavengers induced oocyte maturation. The Gbetagamma scavengers bound an endogenous, membrane-associated Gbeta subunit, indistinguishable from Xenopus Gbeta1 derived from mRNA injection. The injection of Xenopus Gbeta1 mRNA, together with bovine Ggamma2 mRNA, elevated oocyte cAMP levels and inhibited progesterone-induced oocyte maturation. CONCLUSION: An endogenous G protein betagamma dimer, likely including Xenopus Gbeta1, is responsible for maintaining oocyte meiosis arrest. Resumption of meiosis is induced by Gbetagamma scavengers in vitro or, naturally, by progesterone via a mechanism that suppresses the release of Gbetagamma.     

Identification of possible phosducins in the ciliate Blepharisma japonicum

Examination of ciliate Blepharisma japonicum whole cell lysates with an antibody against phosphoserine and in vivo labeling of cells with radioactive phosphate revealed that the photophobic response in the ciliate is accompanied by a rapid dephosphorylation of a 28 kDa protein and an enhanced phosphorylation of a 46 kDa protein. Analysis with antibodies raised against rat phosducin or human phosducin-like proteins, identified one major protein of a molecular weight of 28 kDa, and two protein bands of 40 kDa and 93 kDa. While the identified ciliate phosducin is phosphorylated in a light-dependent manner, both phosducin-like proteins exhibit no detectable dependence of phosphorylation upon illumination. An immunoprecipitation assay also showed that the ciliate phosducin is indeed phosphorylated on a serine residue and exists in a phosphorylated form in darkness and that its dephosphorylation occurs in light. Immunocytochemical experiments showed that protozoan phosducin and phosducin-like proteins are localized almost uniformly within the cytoplasm of cells adapted to darkness. Cell exposure to light caused a pronounced displacement of the cell phosducin to the vicinity of the plasma membrane; however, no translocation of phosducin-like proteins was observed upon cell illumination. The obtained results are the first demonstration of the presence and morphological localization of a possible phosducin and phosducin-like proteins in ciliate protists. Phosducin and phosducin-like proteins were found to bind and sequester the betagamma-subunits of G-proteins with implications for regulation of G-protein-mediated signaling pathways in various eukaryotic cells. The findings presented in this study suggest that the identified phosphoproteins in photosensitive Blepharisma japonicum may also participate in the regulation of the efficiency of sensory transduction, resulting in the motile photophobic response in this cell.