Diversity of G proteins in signal transduction

A 68-kD GTP-binding protein associated with the T cell receptor complex

The identity of the guanine nucleotide-binding protein (G protein) involved in T cell activation pathways remains unclear. We identified a 68-kD GTP-binding protein associated with the T cell receptor (TCR)/CD3 complex using immunoprecipitation and GTP-affinity labeling techniques. Proteins coimmunoprecipitated with the TCR/CD3 complex in digitonin lysate of a human leukemic T cell line, MOLT 16, were incubated with alpha-[32P]GTP and irradiated with ultraviolet rays to covalently link the labeled GTP to GTP-binding proteins. They were then analyzed by electrophoresis. The 68-kD protein exhibited nucleotide specificity for GTP-binding and was insensitive to cholera and pertussis toxins. The 68-kD GTP-binding protein could be coimmunoprecipitated with the TCR/CD3 complex but not with other surface molecules such as major histocompatibility complex class I and lymphocyte function associated-1, which do not cause rapid Ca2+ mobilization. These suggest that the 68-kD GTP-binding protein is specifically associated with the TCR/CD3 complex.

Attenuation of GTPase activity of recombinant G(o) alpha by peptides representing sequence permutations of mastoparan

There is convincing evidence that the cytoplasmic domains of multispanning receptors interact with guanine nucleotide-binding proteins (G proteins). What are the rules governing these interactions? In an attempt to answer this question, we focused our attention on mastoparan, an amphiphilic tetradecapeptide from wasp venom, and on nine of its variants, produced by sequence permutation, which have altered amphiphilicity or no amphiphilicity at all. Mastoparan enhances the GTPase activity of recombinant G(o) alpha 5-fold in phospholipid vesicles. Like mastoparan, four of the synthetic variants can form amphiphilic alpha-helices and two of them indeed stimulate the GTPase activity of the G protein, whereas the other two have no effect. This confirms that the activation of certain G proteins by a number of peptides is mainly due to their cationic amphiphilicity. However, this structural feature is clearly not sufficient. The relative orientation of the positively charged residues as well as that of the hydrophobic side chains appear to be of fundamental importance. The other five peptides are not amphiphilic and do not enhance the rate of GTP hydrolysis. Surprisingly, three of them almost completely inhibit the G protein's intrinsic GTPase activity. This finding is of interest because of the possible role differential regulation of G protein activity can play in cellular functions.

Pertussis toxin-catalyzed ADP-ribosylation of G(o) alpha with mutations at the carboxyl terminus

The guanine nucleotide-binding protein G(o alpha) has been implicated in the regulation of Ca2+ channels in neural tissues. Covalent modification of G(o alpha) by pertussis toxin-catalyzed ADP-ribosylation of a cysteine (position 351) four amino acids from the carboxyl terminus decouples G(o alpha) from receptor. To define the structural requirements for ADP-ribosylation, preparations of recombinant G(o alpha) with mutations within the five amino acids at the carboxyl terminus were evaluated for their ability to serve as pertussis toxin substrates. As expected, the mutant in which cysteine 351 was replaced by glycine (C351G) was not a toxin substrate. Other inactive mutants were G352D and L353 delta/Y354 delta. Mutations that had no significant effect on toxin-catalyzed ADP-ribosylation included G350D, G350R, Y354 delta, and L353V/Y354 delta. Less active mutants were L353G/Y354 delta, L353A/Y354 delta, and L353G. ADP-ribosylation of the active mutants, like that of wild-type G(o alpha), was enhanced by the beta gamma subunits of bovine transducin. It appears that three of the four terminal amino acids critically influence pertussis toxin-catalyzed ADP-ribosylation of G(o alpha).

Characterization of a G-protein from the mandibular organ of the lobster Homarus americanus (Nephropidae, Decapoda)

1. GTP-binding activity was found in both calf brain and male lobster mandibular organ (MO). There was approximately two to three times as much binding in the calf brain. 2. The GTP-binding activity could be extracted from the calf brain with sodium cholate, but not from the MOs. 3. Using ADP-ribosylation catalyzed by pertussis toxin, GTP-binding was shown to be the result of the presence of G-protein. In the lobster MO the G-protein alpha subunit has a molecular weight of about 42 kDa and may be of the Go or Gi varieties.

Different beta-subunits determine G-protein interaction with transmembrane receptors

Regulatory GTP-binding proteins (G proteins) are membrane-attached heterotrimers (alpha, beta, gamma) that mediate cellular responses to a wide variety of extracellular stimuli. They undergo a cycle of guanine-nucleotide exchange and GTP hydrolysis, during which they dissociate into alpha-subunit and beta gamma complex. The roles of G-protein alpha-subunits in these processes and for the specificity of signal transduction are largely established; the beta- and gamma-subunits are essential for receptor-induced G-protein activation and seem to be less diverse and less specific. Although the complementary DNAs for several beta-subunits have been cloned, isolated subunits have only been studied as beta gamma complexes. Functional differences have been ascribed to the gamma-subunit on the basis of extensive sequence similarity among beta-subunits and apparent heterogeneity in gamma-subunit sequences. Beta gamma complexes can interact directly or indirectly with different effectors. They seem to be interchangeable in their interaction with pertussis toxin-sensitive alpha-subunits, so we tested this by microinjecting antisense oligonucleotides into nuclei of a rat pituitary cell line to suppress the synthesis of individual beta-subunits selectively. Here we show that two out of four subtypes of beta-subunits tested (beta 1 and beta 3) are selectively involved in the signal transduction cascades from muscarinic M4 (ref. 4) and somatostatin receptors, respectively, to voltage-dependent Ca2+ channels.

The WD-40 repeat

An amino acid sequence motif, called the WD-40 repeat, has been found as a repeat in a large variety of proteins that do not share any obvious functional properties. At present, the function of the repeated motif is not known for any of these proteins. Interestingly, recent experiments in yeast indicate that several proteins containing the WD-40 repeat are genetically associated with members of the TPR-family, a protein family that is characterized by the presence of another repeated motif of unknown function: the tetratricopeptide repeat. It is conceivable that proteins containing the WD-40 repeat interact physically with members of the TPR-family via their respective repeated motifs.

Heterogeneity of three electrophoretically distinct Go alpha-subunits in mammalian brain

So far three splice variants of the alpha o-gene coding for two alpha o proteins have been identified by molecular cloning, and the corresponding proteins purified. In the present study subtype-specific peptide antibodies revealed the existence of an electrophoretically distinct third form of alpha o in mammalian brain membranes which migrates more slowly on SDS-PAGE and shows a more acidic pI value than the other alpha o-subunits. Each of the three alpha o-subunits is detected as two isoforms when enriched from brain membranes. Rodent alpha o-subunits differ from non-rodent species in their electrophoretic mobilities. The results suggest that (i) there may exist a novel alpha o-subunit which reacts with an alpha o1-subunit-specific antibody, (ii) each alpha o-subunit may exist in more than one co- or posttranslationally modified isoform in brain membranes, and (iii) differences between alpha o-subunits from different species exist which are detectable by gel electrophoretic methods.

Development of MEKA (phosducin), G beta, G gamma and S-antigen in the rat pineal gland and retina

Pinealocytes and retinal photoreceptor cells contain an unusual cytoplasmic complex composed of the G beta gamma dimer of GTP-binding regulatory proteins (G-proteins) tightly bound to an acidic 33 kDa phosphoprotein termed MEKA or phosducin; MEKA is a substrate of cyclic AMP-dependent protein kinase. This study characterized the developmental appearance of these and two related proteins, G gamma and S-antigen, in pineal and retinal tissue. MEKA was absent in the pineal gland prior to birth, at a time when it was possible to detect G beta in pineal cytoplasm, indicating that the appearance of G beta in the cytoplasm precedes that of MEKA and does not appear to require the presence of MEKA. The absence of MEKA at this time indicates that the cyclic AMP stimulation of pineal serotonin N-acetyltransferase activity is not mediated by MEKA, which has been considered as a possible role of MEKA. After postnatal day 7, pineal MEKA and cytoplasmic G beta increased in a parallel manner, with peak values occurring at about postnatal day 21. Thereafter, both proteins in the pineal gland decreased in a parallel fashion to 10 and 35% of their peak values, respectively; in contrast, the cytoplasmic protein S-antigen and membrane associated G beta remained at maximal levels after this time. Whereas both MEKA and G beta decreased late in development in the pineal gland, these proteins either increased or remained constant in the retina. These tissue-specific patterns were found to differ from those of another cytosolic protein found exclusively in the pineal gland and retina, S-antigen, which remained constant after day 21 in the pineal gland but decreased in the retina late in life.

Involvement of pertussis toxin sensitive G-proteins in conditioned fear-potentiated startle: possible involvement of the amygdala

The present study evaluated the effects of intraventricular or intracerebral administration of pertussis toxin on fear-potentiated startle (a measure of conditioned fear) and shock sensitization (a measure of unconditioned fear). In Experiment 1 all animals were unilaterally implanted with cannulae into the lateral ventricle 1 week prior to 2 days of fear conditioning (ten light-shock pairings on each of 2 days). Five days later, animals were infused with either 1 microgram pertussis toxin or saline and tested for fear-potentiated startle 24 h after infusion and tested for shock sensitization 26 or 50 h after infusion. Pertussis toxin blocked the ability of a light conditioned stimulus to facilitate startle but did not alter the ability of acute footshock to increase startle amplitude in the same animals. In Experiment 2 bilateral infusion of 1 microgram pertussis toxin into the basolateral nuclei of the amygdala, but not the interpositus nuclei of the cerebellum, also blocked fear-potentiated startle when animals were tested 6 h after infusion. These findings suggest a role for pertussis toxin sensitive G-proteins, perhaps within the amygdala, in the expression of conditioned but not unconditioned fear.

Molecular cloning of a G-protein alpha i subunit from the lobster olfactory organ

A G-protein alpha subunit was cloned from a lobster olfactory organ cDNA library and sequenced. The clone encodes an alpha i subunit based on the 80% identity its predicted amino acid sequence shares with mammalian alpha i subunits. On Northern blots of polyadenylated RNA, the clone hybridized to a 5 kb species from several tissues.

Interaction between G-protein beta and gamma subunit types is selective

Signal-transducing guanine nucleotide-binding proteins (G proteins) are made up of three subunits, alpha, beta, and gamma. Each of these subunits comprises a family of proteins. The rules for association between members of one family with members of another to form a multimer are not known; it is not clear whether associations are specific or nonspecific. Other than transducin (Gt), the G protein in rod photoreceptors, most purified G proteins contain more than one subtype of beta or gamma subunits. The Gt alpha subunit is associated only with beta 1 and gamma 1. It is not known whether this specificity is due to the differential expression of these subunit types in a cell type or due to intrinsically different affinities between different beta and gamma subunit types. We have used a transfected cell assay system to examine the association of the beta 1, beta 2, and beta 3 proteins with the gamma 1 and gamma 2 proteins. Results show that gamma 1 does not associate with beta 2 and that beta 3 does not associate with gamma 1 or gamma 2. Differences in affinities between types of G protein subunits will impose restrictions on the formation of certain heterotrimers and determine which G protein will be active in a cell. A chimeric molecule of beta 1 and beta 2 was used to broadly map the regions on these subunits that determine specificity of association.

Mutational activation of RAS and GSP oncogenes in differentiated thyroid cancer and their biological implications

Activating mutations of ras-genes (Kirsten-ras, Harvey-ras, N-ras) and genes encoding for the alpha subunit of G-proteins (Gs, Gi2, Gi3, Go, Gz) were assessed in 32 differentiated thyroid cancer (DTC) tissues from German (n = 22) and American (n = 10) patients. Gs-protein (GSP) and/or ras mutations were found in 69% of all tissues with a heterogeneous distribution pattern. An increased prevalence could be demonstrated in metastatic (8 of 9 mutation positive) when compared to localized disease (13 of 23 mutation positive) (p less than 0.001) and in patients greater than 50 years of age (16 of 18 mutation positive), when compared to younger patients (6 of 14 mutation positive) (p less than 0.001). No activating mutations were found on H-ras and K-ras genes nor on genes encoding for the alpha subunits of Gi2, Gi3, Go, and Gz. Differentiated thyroid cancer tissue from German patients revealed a higher prevalence for GSP mutations (73%) than did DTC from American patients (20%) (p less than 0.001). We demonstrated a high frequency of ras and GSP mutations in DTC and suggest that these mutations may contribute to our basic understanding of this disease and might initiate a new search for more rational and individualized therapeutic approaches in patients with DTC.

Heterotrimeric G proteins in synaptoneurosome membranes are crosslinked by p-phenylenedimaleimide, yielding structures comparable in size to crosslinked tubulin and F-actin

We have treated rat brain synaptoneurosomes with the crosslinking agent N,N'-1,4-phenylenedimaleimide under conditions that cause extensive crosslinking of tubulin, F-actin, and the alpha and beta subunits of three major types of heterotrimeric GTP-binding regulatory proteins (G(o), Gs, Gi) present in brain membranes. The major crosslinked products are coeluted from Bio-Gel sizing columns as very large structures that do not penetrate stacking gels during SDS/PAGE. The alpha subunits but not the beta subunits of Gs, G(o) and Gi also yield crosslinked products of intermediate sizes. None of the products are as small as the heterotrimeric G proteins extracted from brain by cholate or Lubrol. However, the large and intermediate crosslinked structures are strikingly similar to the large, polydisperse structures of the alpha subunits of Gs, Gi, and G(o) extracted from synaptoneurosomes by the detergent octyl glucoside, which have sedimentation properties of multimeric proteins. Several ways in which multimeric forms of G proteins can explain the dynamic and pleiotropic actions of hormones and GTP on signal-transducing systems are discussed.

Gustducin is a taste-cell-specific G protein closely related to the transducins

A novel G protein alpha-subunit (alpha-gustducin) has been identified and cloned from taste tissue. alpha-Gustducin messenger RNA is expressed in taste buds of all taste papillae (circumvallate, foliate and fungiform); it is not expressed in non-sensory portions of the tongue, nor is it expressed in the other tissues examined. alpha-Gustducin most closely resembles the transducins (the rod and cone photoreceptor G proteins), suggesting that gustducin's role in taste transduction is analogous to that of transducin in light transduction.

Baculovirus expression of mammalian G protein alpha subunits

Complementary DNAs encoding three subtypes of the alpha subunit (alpha i-1, alpha o and alpha s) of rat guanyl nucleotide regulatory proteins were used to construct recombinant baculoviruses which direct high-level expression of the corresponding proteins in cultured Sf9 insect cells. The expressed proteins were recognized by polyclonal antisera specific for the different alpha chains, and co-migrated with the native proteins from rat brain membranes in immunoblotting analyses. Soluble and particulate forms of all three immunoreactive alpha chains were observed following ultracentrifugation of cell lysates. Biosynthetic radiolabelling of infected cells with [35S]methionine or [3H]myristate showed that both soluble and particulate forms of alpha i-1 and alpha o were myristoylated; in contrast, alpha s did not incorporate myristate. The soluble fractions from cells expressing alpha chains showed high levels of GTP-binding activity over that observed in uninfected cells, or in cells infected with wild-type virus. The peak expression levels observed at 72 h post-infection were highest for alpha o at ca. 400 pmol of GTP-gamma-35S/mg protein, or roughly 2% of the total soluble protein. The results of this work show that the baculovirus system can be employed for high-level production of mammalian G protein alpha chains which retain GTP-binding activity and are appropriately modified by myristoylation.

Characterization of the human rod transducin alpha-subunit gene

The human rod transducin alpha subunit (Tr alpha) gene has been cloned. A cDNA clone, HG14, contained a 1.1 kb insertion when compared with the human Tr alpha cDNA published by Van Dop et al. (1). Based on two overlapping clones isolated from a human genomic library, the human Tr alpha gene is 4.9 kb in length and consists of nine exons interrupted by eight introns. Northern blots of human retina total RNA showed that the gene is transcribed by rod photoreceptors into two species of mRNA, 1.3 kb and 2.4 kb in size. Apparently, this is the result of alternative splicing. Two putative transcription initiation sites were determined by primer extension and S1 nuclease protection assays. The putative promoter regions of the human and mouse Tr alpha genes have an identity of 78.1%. As found in the mouse gene (2), no TATA consensus sequence is present in the human gene.

GTP-binding proteins and post-receptor components in hypertension

Alterations in neurohormonal response are a widely-observed feature in various forms of hypertension. Such responses depend not only on levels of hormones/neurotransmitters, but also on receptors and post-receptor components. With respect to G protein-coupled receptors, such as those for catecholamines, angiotensin II, and bradykinin, it is possible that G-proteins or G protein-coupled effector molecules are altered in hypertension. In this article, several classes of G alpha proteins and effectors which link to these proteins are briefly discussed. Evidence is presented in support of the concept that signal amplification in G protein-coupled receptor systems occurs at the level of receptor activation of the G proteins. Limited data are as yet available that directly assess whether changes in the amount or properties of particular G alpha proteins or G-protein-linked effectors, are altered in hypertension. The availability of antibody, cDNA and other genetic probes should prove highly useful in testing the hypothesis that such alterations are important for the pathogenesis and maintenance of the hypertensive state.

Neuromodulation

The ability of the nervous system to respond to the environment and to learn depends upon the tuning of neuronal electrical activity, loosely called neuromodulation. The substrates for electrical activity and, therefore, neuromodulation are ion channels which may be either synaptic or extrasynaptic. Neuromodulation is dynamic and most frequently involves neurotransmitters and hormones acting via G-protein-coupled pathways.

Relationships between the degree of cross-linking of surface immunoglobulin and the associated inositol 1,4,5-trisphosphate and Ca2+ signals in human B cells

Cross-linking of surface immunoglobulin (Ig) receptors on human B cells leads to the activation of a tyrosine kinase. The activated tyrosine kinase subsequently phosphorylates a number of substrates, including phospholipase C-gamma. This enzyme breaks down phosphoinositol bisphosphate to form two intracellular messengers, diacylglycerol and inositol 1,4,5-trisphosphate, leading to the activation of protein kinase C and the release of intracellular Ca2+ respectively. We have used h.p.l.c. and flow cytometry to measure accurately the inositol phosphate turnover and Ca2+ release in anti-Ig-stimulated human B cells. In particular, we have examined the effect of dose of the cross-linking antibody on the two responses. The identity of putative messenger inositol phosphates has been verified by structural analysis, and the amounts of both inositol phosphates and Ca2+ present have been quantified. In the Ramos Burkitt lymphoma, which is very sensitive to stimulus through its Ig receptors, both inositol phosphate production and Ca2+ release were found to be related to the dose of anti-Ig antibody applied. This suggests that phospholipase C-mediated signal transduction in human B cells converts the degree of cross-linking of the immunoglobulin receptor quantitatively into intracellular signals.

Gi3 does not contribute to the inhibition of adenylate cyclase when stimulation of an alpha 2-adrenergic receptor causes activation of both Gi2 and Gi3

Agonist occupancy of the alpha 2-C10 adrenergic receptor in a stable clone (1C) of Rat 1 fibroblasts produced by transfection of cells with genomic DNA encoding this receptor causes the activation of both of the pertussis-toxin-sensitive G-proteins Gi2 and Gi3 [Milligan, Carr, Gould, Mullaney & Lavan (1991) J. Biol. Chem. 266, 6447-6455]. An IgG fraction from an antiserum (I3B) which identifies the C-terminal decapeptide of Gi3 alpha only was able to inhibit partially receptor stimulation of high-affinity GTPase activity. An equivalent fraction from an antiserum (AS7) able to identify the C-terminal decapeptide of Gi1 alpha + Gi2 alpha, but not Gi3 alpha, was also able to inhibit partially receptor stimulation of GTPase activity, and the effects of the two antisera were additive. By contrast, agonist-mediated inhibition of forskolin-amplified adenylate cyclase activity was abolished completely by the IgG fraction of antiserum AS7, but was not decreased by treatment with antiserum 13B. Based on the proportion of agonist-stimulated high-affinity GTPase which was prevented by each antiserum and on the measured membrane levels of Gi2 and Gi3, calculations indicated that essentially all of the cellular Gi3, but only 15% of the available Gi2, can be activated by the alpha 2-C10 adrenergic receptor in these cells. These results demonstrate that, although Gi3 is activated by alpha 2-adrenergic agonists in membranes of clone 1C cells, it does not contribute to the transduction of receptor-mediated inhibition of adenylate cyclase.

Biosynthesis of paf-acether in cultured-mouse mast cells: the role of calcium and G proteins

We examined the potential role of a guanine nucleotide-binding protein in the biosynthesis of paf-acether (paf) and the release of beta-hexosaminidase during antigenic stimulation of cultured mouse bone marrow-derived mast cells. Unlike pertussis toxin, cholera toxin treatment enhanced the antigen-stimulated production of paf and calcium mobilisation without affecting acetyltransferase activation and cell degranulation. The level of intracellular cAMP doubled in cholera toxin-treated cells. Our data suggest that a cholera toxin-sensitive guanine nucleotide-binding protein is involved in the IgE receptor-mediated signal transduction leading to paf production most probably at the level of Ca2+ influx.

Evolution of the mammalian G protein alpha subunit multigene family

Heterotrimeric guanine nucleotide binding proteins (G proteins) transduce extracellular signals received by transmembrane receptors to effector proteins. The multigene family of G protein alpha subunits, which interact with receptors and effectors, exhibit a high level of sequence diversity. In mammals, 15 G alpha subunit genes can be grouped by sequence and functional similarities into four classes. We have determined the murine chromosomal locations of all 15 G alpha subunit genes using an interspecific backcross derived from crosses of C57BL/6J and Mus spretus mice. These data, in combination with mapping studies in humans, have provided insight into the events responsible for generating the genetic diversity found in the mammalian alpha subunit genes and a framework for elucidating the role of the G alpha subunits in disease.

Characterization of GTP-binding proteins in Golgi-associated membrane vesicles from rat adipocytes

We have previously reported that guanine nucleotides inhibit glucose transport activity reconstituted from adipocyte membrane fractions. In order to further investigate the hypothetical involvement of guanine-nucleotide-binding proteins (GTP-binding proteins) in the regulation of insulin-sensitive glucose transport activity, we studied their subcellular distribution in adipocytes treated or not with insulin. Adipocytes were homogenized and fractionated to yield plasma membranes (PM) and a Golgi-enriched fraction of intracellular membranes (low-density microsomes, LDM). In these membrane fractions, total guanosine 5'-[gamma-[35S]thio]triphosphate ([35S]GTP[S]) binding, alpha- and beta-subunits of heterotrimeric G-proteins, proto-oncogenes Ha-ras and K-ras, and 23-28 kDa GTP-binding proteins were assayed. The levels of alpha s and alpha i (the alpha-subunits of Gs and Gi) were approx. 8-fold lower in LDM than in PM; beta-subunits, Ha-ras and K-ras were not detectable in LDM. Total GTP[S]-binding sites and 23-28 kDa GTP-binding proteins were present in LDM in approximately the same concentrations as in PM. Insulin gave rise to the characteristic translocation of glucose transporters, but failed to alter the subcellular distribution of any of the GTP-binding proteins. Fractionation of the LDM on a discontinuous sucrose gradient revealed that alpha s and alpha i, as detected with antiserum against a common peptide sequence (alpha common), and the bulk of the 23-28 kDa G-proteins sedimented at different sucrose densities. None of the GTP-binding proteins co-sedimented with glucose transporters. Furthermore, the inhibitory effect of GTP[S] on the reconstituted transport activity was lost in the peak fractions of glucose transporters partially purified on the sucrose gradient. These data indicate that LDM from adipocytes contain several GTP-binding proteins in discrete vesicle populations. However, the intracellular GTP-binding proteins are not tightly associated with the vesicles containing the glucose transporter.

Guanyl nucleotides modulate binding to steroid receptors in neuronal membranes

The recently characterized corticosteroid receptor on amphibian neuronal membranes appears to mediate rapid, stress-induced changes in male reproductive behaviors. Because the transduction mechanisms associated with this receptor are unknown, we performed radioligand binding studies to determine whether this steroid receptor is negatively modulated by guanyl nucleotides. The binding of [3H]corticosterone to neuronal membranes was inhibited by nonhydrolyzable guanyl nucleotides in both equilibrium saturation binding and titration studies. The addition of guanyl nucleotide plus unlabeled corticosterone induced a rapid phase of [3H]corticosterone dissociation from membranes that was not induced by addition of unlabeled ligand alone. Furthermore, the equilibrium binding of [3H]corticosterone and the sensitivity of the receptor to modulation by guanyl nucleotides were both enhanced by Mg2+. These results are consistent with the formation of a ternary complex of steroid, receptor, and guanine nucleotide-binding protein that is subject to regulation by guanyl nucleotides. Therefore, rapid signal transduction through corticosteroid receptors on neuronal membranes appears to be mediated by guanine nucleotide-binding proteins.

Role of G proteins in mouse egg activation: stimulatory effects of acetylcholine on the ZP2 to ZP2f conversion and pronuclear formation in eggs expressing a functional m1 muscarinic receptor

Sperm-mediated egg activation may be analogous to ligand-mediated signal transduction through G protein-coupled receptors. We investigated this possibility in the mouse egg by microinjecting mouse oocytes with an m1 muscarinic receptor mRNA. Following oocyte maturation in vitro, the metaphase II-arrested eggs were treated with acetylcholine and its effect was examined on zona pellucida modifications and pronuclear formation, which are end points of early and late egg activation, respectively. Treatment of these eggs with acetylcholine reveals that both the ZP2 to ZP2f conversion and pronuclear formation occur. Atropine and microinjected GDP beta S block the acetylcholine-induced ZP2 conversion, suggesting that the acetylcholine effects are mediated via a functional G protein-coupled m1 receptor. The acetylcholine-induced ZP2 conversion, however, is not inhibited by pertussis toxin under conditions in which greater than 90% of the endogenous Gi is inactivated by ADP ribosylation. The presence of a pertussis toxin-insensitive G protein, Gq, is detected by immunoblotting; this G protein could be a candidate to mediate the pertussis toxin-insensitive effects of acetylcholine. Results of these experiments are consistent with the hypothesis that receptor-mediated G protein activation may play a role in egg activation.

Characterization of the cDNA and genomic sequence of a G protein gamma subunit (gamma 5)

A cDNA from human placenta and liver tissues that contained both sequence for the lysosomal glycosidase di-N-acetylchitobiase and sequence homologous to the gamma subunit of GTP-binding proteins was previously isolated. Here we have shown that the gamma-subunit-homologous portion of this unusual cDNA is derived from a member of the gamma-subunit multigene family. The partial human gamma-subunit sequence was used to isolate the corresponding full-length cDNA clones from bovine and rat livers. The two cDNAs encode identical 68-amino-acid proteins (7.3 kDa) homologous to previously cloned G protein gamma subunits. The bovine gene sequence encoding this new gamma-subunit isoform (gamma 5) was determined and found to have an intron-exon structure consistent with the original human chitobiase-gamma 5-subunit hybrid mRNA being a product of alternative splicing. Genomic cloning also resulted in the isolation of a human gamma 5 pseudogene.

Gz-mediated hormonal inhibition of cyclic AMP accumulation

Hormones inhibit synthesis of adenosine 3',5'-monophosphate (cAMP) in most cells via receptors coupled to pertussis toxin (PTX)-sensitive guanine nucleotide-binding (G) proteins. Mutationally activated alpha subunits of Gi2 (alpha i2) constitutively inhibit cAMP accumulation when transfected into cells. Cells have now been transfected with mutant alpha subunits of four other G proteins--Gz, a PTX-insensitive G protein of unknown function, and Gi1, Gi3, and G(o), which are PTX-sensitive. Mutant alpha z, alpha i1, and alpha i3 inhibited cAMP accumulation but alpha o did not. Moreover, expression of wild-type alpha z produced cells in which PTX did not block hormonal inhibition of cAMP accumulation. Thus, Gz can trigger an effector pathway in response to hormone receptors that ordinarily interact with PTX-sensitive Gi proteins.

Two gamma-subunits, gamma-I and gamma-II, complex with the same beta-subunits in bovine brain G-proteins (Gi/o)

When a mixture of bovine brain G-proteins (Gi/o) was loaded onto an octyl sepharose column in the presence of AlF4-, alpha-subunits of molecular weights 39 kDa and the 41 kDa were eluted separately, followed by the appearance of two distinct peaks containing beta gamma-subunits (beta gamma-I, beta gamma-II). Both beta gamma-I and beta gamma-II possessed identical beta-subunits but different gamma-subunits. The molecular weights of the two gamma-subunits determined by SDS-polyacrylamide gel electrophoresis both in the presence and absence of urea were 4.5 kDa (gamma-I) and 5.0 kDa (gamma-II). Tests indicated that the two isolated gamma-subunits are intact and have not undergone proteolysis. The amino acid composition of gamma-I appeared to be distinct from that of gamma-II. Therefore, this method is a simple procedure for isolating beta gamma-I and beta gamma-II.

Decrement of muscarinic receptor-stimulated low-KM GTPase in striatum and hippocampus from the aged rat

Previous studies have shown that there is an age-related loss of responsiveness in several different receptor systems (e.g. beta-adrenergic, dopaminergic and muscarinic). Our research, using perifused striatal slices and examining muscarinic agonist enhancement of K(+)-evoked dopamine release, has determined that at least part of the loss of sensitivity in muscarinic receptors (mAChR) may occur early in the post-receptor signal transduction process. The present study was carried out to further characterize and localize this deficit by examining carbachol- and oxotremorine-stimulated low-KM guanosine triphosphatase (GTPase) activity in striatal as well as hippocampal tissue obtained from adult (6 months) and old (24 months) Wistar rats. Receptor stimulated low-KM GTPase catalyzes the conversion of GTP to GDP to end the signal transduction cycle and is an indicator of receptor-G-protein coupling/uncoupling. The results showed that stimulated GTPase activity was significantly reduced in hippocampal and striatal tissue from the old animals. These findings suggest that there may be an age-related coupling/uncoupling deficit between muscarinic receptor and G-proteins, and that this deficit may contribute to the reduced mAChR responsiveness in senescence.

Characterization of the cDNA and genomic sequence of a G protein gamma subunit (gamma 5)

A cDNA from human placenta and liver tissues that contained both sequence for the lysosomal glycosidase di-N-acetylchitobiase and sequence homologous to the gamma subunit of GTP-binding proteins was previously isolated. Here we have shown that the gamma-subunit-homologous portion of this unusual cDNA is derived from a member of the gamma-subunit multigene family. The partial human gamma-subunit sequence was used to isolate the corresponding full-length cDNA clones from bovine and rat livers. The two cDNAs encode identical 68-amino-acid proteins (7.3 kDa) homologous to previously cloned G protein gamma subunits. The bovine gene sequence encoding this new gamma-subunit isoform (gamma 5) was determined and found to have an intron-exon structure consistent with the original human chitobiase-gamma 5-subunit hybrid mRNA being a product of alternative splicing. Genomic cloning also resulted in the isolation of a human gamma 5 pseudogene.

Signal transduction enzymes of vertebrate photoreceptors

A flash of light initiates a cascade of biochemical reactions inside vertebrate photoreceptor cells, culminating in hydrolysis of intracellular cyclic GMP and hyperpolarization of the cell. The cell recovers by shutting down this cascade and resynthesizing cGMP. Many of the reactions responsible for the excitation and recovery phases of the photoresponse have been identified. Here I review some characteristics of the proteins that participate in these reactions.

Inhibition of the ω-conotoxin-sensitive calcium current by distinct G proteins

Leu-enkephalin (Leu-Enk), norepinephrine (NE), somatostatin (SS), and bradykinin (BK) decrease the voltage-dependent calcium current in NG108-15 cells. Here we have investigated whether distinct G proteins, or a G protein common to all of the pathways, mediates this inhibition. We found that pertussis toxin (PTX) reduced all of these transmitter actions, except that of BK. To examine which of the PTX-sensitive pathways is transduced by GoA, we constructed an NG108-15 cell line that stably expresses a mutant, PTX-resistant alpha subunit of GoA. After treatment with PTX, the mutant GoA alpha rescued the Leu-Enk and NE pathways but not the SS pathway. At least three different G proteins can transduce receptor-mediated inhibition of calcium currents in nerve cells. The effects of these G proteins appear to converge on the omega-conotoxin GVIA-sensitive calcium current.

G protein-coupled receptors

The diversity of the G protein-coupled receptor superfamily is now being realised with the molecular cloning of DNA encoding many new receptors and receptor subfamilies. The existing pharmacological definitions of receptor subtypes have been extended dramatically with identification of additional subtypes at the molecular level. Functional analysis of cloned receptors by expression in heterologous cell types has demonstrated that individual receptor subtypes can couple to a variety of different effector systems.

Molecular cloning of porcine Mx cDNAs: new members of a family of interferon-inducible proteins with homology to GTP-binding proteins

Porcine cells treated with interferon (IFN) or double-stranded RNA synthesize two proteins that exhibit high homology of the amino acid sequence to mouse Mx1 protein involved in selective resistance to influenza virus. A full-length cDNA clone (poMx1) encoding the porcine Mx1 protein was isolated and sequenced. It contained an open reading frame of 663 amino acids. The predicted molecular weight of 75.6 kD is in good agreement with the apparent molecular mass of the two immunoprecipitable proteins of 76 kD and 73 kD determined by SDS polyacrylamide gel electrophoresis. A second cDNA (poMx2) was characterized which was incomplete in the 5' region. A comparison of all known Mx proteins revealed an average homology of 67.5%. The porcine Mx1 polypeptide is most closely related to human MxA (p78), murine Mx2, rat Mx2, and rat Mx3 proteins. The amino-terminal halves of all Mx proteins are highly conserved and possess three consensus elements in proper spacing, characteristic of GTP-binding domains. The Mx family shows in their amino termini striking homology to previously characterized Mx-related proteins playing roles in the intracellular vectorial transport of proteins--the products of the yeast Vps1 locus and the dynamins.

Subunit interactions of GTP-binding proteins

Fluorescence energy transfer [cf. Förster, T. (1948) Ann. Phys. 6, 55-75] was tested for its suitability to study quantitative interactions of subunits of G0 with each other and these subunits or trimeric G0 with the beta 1-adrenoceptor in detergent micelles or after reconstitution into lipid vesicles [according to Feder, D., Im, M.-J., Klein, H. W., Hekman, M., Holzhöfer, A, Dees, C., Levitzki, A., Helmreich, E. J. M. & Pfeuffer, T. (1986) EMBO J. 5, 1509-1514]. For this purpose, alpha 0- and beta gamma-subunits and trimeric G0 purified from bovine brain, the beta gamma-subunits from bovine rod outer segment membranes and the beta 1-adrenoceptor from the turkey erythrocyte were all labelled with either tetramethylrhodamine maleimide or fluorescein isothiocyanate under conditions which leave the labelled proteins functionally intact. In the case of alpha 0- and beta gamma-interactions, specific high-affinity binding interactions (Kd approximately 10 nM) and nonspecific low-affinity binding interactions (Kd approximately 1 microM) could be readily distinguished by comparing fluorescence energy transfer before and after dissociation with 10 microM guanosine 5'-O-[gamma-thio]triphosphate and 10 mM MgCl2 where only low-affinity binding interactions remained. Interactions between alpha 0- and beta gamma-subunits from bovine brain or from bovine retinal transducin did not differ much. The beta gamma-subunits from bovine brain were found to bind with high transfer efficiency and comparable affinities to the hormone-activated and the nonactivated beta 1-receptor reconstituted in lipid vesicles: Kd = 100 +/- 20 and 120 +/- 20 nM, respectively; however, beta gamma-subunits from transducin appeared to bind more weakly to the beta 1-adrenoceptor than beta gamma-subunits from bovine brain. Separated purified homologous alpha 0- and beta gamma-subunits from bovine brain interfered mutually with each other in binding to the beta 1-adrenoceptor presumably because they had a greater affinity for each other than for the receptor. These findings attest to the suitability of fluorescence energy transfer for studying protein-protein interactions of G-proteins and G-protein-linked receptors. Moreover, they supported the previous finding [Kurstjens, N. P., Fröhlich, M., Dees, C., Cantrill, R. C., Hekman, M. & Helmreich, E. J. M. (1991) Eur. J. Biochem. 197, 167-176] that beta gamma-subunits can bind to the nonactivated beta 1-adrenoceptor.

Identification of effector-activating residues of Gs alpha

The heterotrimeric G proteins transduce extracellular signals by interacting with specific intracellular effectors. We have used a scanning mutagenesis approach to identify amino acids of alpha S, the alpha subunit of Gs, that determine the specificity of its interaction with its effector, adenylyl cyclase. In alpha subunit chimeras, residues 236-356 of alpha S comprise the shortest linear stretch that is required for activation of adenylyl cyclase. Within these 121 residues, we identified four clusters of residues in which substitutions prevented effector activation. Mutations in three of these regions did not affect alpha subunit expression or the GTP-induced conformational change. The identified alpha S residues in the NH2-terminal half of the 121-residue region endowed the cognate alpha i2 segment with the ability to activate effector, while those in the COOH-terminal half did not. In a three-dimensional G alpha model, based on the structure of p21ras, the effector-activating residues of alpha S form a surface on the membrane-facing side of the molecule; this surface includes a region that changes conformation upon binding GTP.