Subunit Of Transducin Research Articles

Photoreceptor dysplasia (pd) in miniature schnauzer dogs: evaluation of candidate genes by molecular genetic analysis.

Photoreceptor dysplasia (pd) is one of a group of at least six distinct autosomal and one X-linked retinal disorders identified in dogs which are collectively known as progressive retinal atrophy (PRA). It is an early onset retinal disease identified in miniature schnauzer dogs, and pedigree analysis and breeding studies have established autosomal recessive inheritance of the disease. Using a gene-based approach, a number of retina-expressed genes, including some members of the phototransduction pathway, have been causally implicated in retinal diseases of humans and other animals. Here we examined seven such potential candidate genes (opsin, RDS/peripherin, ROM1, rod cGMP-gated cation channel alpha-subunit, and three subunits of transducin) for their causal association with the pd locus by testing segregation of intragenic markers with the disease locus, or, in the absence of informative polymorphisms, sequencing of the coding regions of the genes. Based on these results, we have conclusively excluded four photoreceptor-specific genes as candidates for pd by linkage analysis. For three other photoreceptor-specific genes, we did not find any mutation in the coding sequences of the genes and have excluded them provisionally. Formal exclusion would require investigation of the levels of expression of the candidate genes in pd-affected dogs relative to age-matched controls. At present we are building suitable informative pedigrees for the disease locus with a sufficient number of meiosis to be useful for genomewide screening. This should identify markers linked to the disease locus and eventually permit progress toward the identification of the photoreceptor dysplasia gene and the disease-causing mutation.

Rod and cone function in the Nougaret form of stationary night blindness.

Recently, a mutation (Gly38Asp) was identified in the alpha subunit of rod transducin in members of the Nougaret pedigree affected with dominantly inherited stationary night blindness. To evaluate retinal function in patients with the Gly38Asp gene defect. Ocular examinations, including specialized measures of rod and cone function. A clinical research facility in Boston, Mass. A father (aged 48 years) and son (aged 25 years) with the Gly38Asp mutation. Psychophysical thresholds to white and narrowband lights and full-field electroretinographic (ERG) responses. Both patients showed dark-adapted thresholds to white light that were elevated approximately 2 log-units across the retina. Spectral sensitivity testing revealed thresholds that seemed to be governed mostly by rods. Although both patients' dark-adapted ERG responses to a dim blue flash were nondetectable, their dark-adapted ERGs to a white flash showed an a-wave with cone and rod components and a b-wave amplitude larger than what could have been generated by cone function alone. Rod ERGs to bright blue flashes had subnormal, but detectable, amplitudes that seemed to result from a profound reduction in sensitivity. The patients also showed loss of a cone subcomponent in the dark-adapted response to a red flash. The abnormal dark-adapted ERG responses of the patients could be simulated in the ERG responses of normal subjects tested with blue, white, and red flashes presented in the presence of a mesopic background. Although the Nougaret form of stationary night blindness has been cited as a prototype of absent rod function with normal cone function, our findings, based on the genealogically and genotypically documented descendants of Jean Nougaret, show that rod function is present, although subnormal, and that there is slight impairment of cone function. The data also suggest that these abnormalities can be simulated by light-adapting the normal retina, compatible with the proposal that the rod transducin encoded by the mutant gene is constitutively active and that the night blindness results from partial desensitization of rods caused by the constitutive activity.

Role of G protein betagamma subunits in muscarinic receptor-induced stimulation and inhibition of adenylyl cyclase activity in rat olfactory bulb.

In the olfactory bulb, muscarinic receptors exert a bimodal control on cyclic AMP, enhancing basal and Gs-stimulated adenylyl cyclase activities and inhibiting the Ca2+/calmodulin- and forskolin-stimulated enzyme activities. In the present study, we investigated the involvement of G protein betagamma subunits by examining whether the muscarinic responses were reproduced by the addition of betagamma subunits of transducin (betagamma(t)) and blocked by putative betagamma scavengers. Membrane incubation with betagamma(t) caused a stimulation of basal adenylyl cyclase activity that was not additive with that produced by carbachol. Like carbachol, betagamma(t) potentiated the enzyme stimulations elicited by vasoactive intestinal peptide and corticotropin-releasing hormone. RT-PCR analysis revealed the expression of mRNAs encoding both type II and type IV adenylyl cyclase, two isoforms stimulated by betagamma synergistically with activated Gs. In addition, betagamma(t) inhibited the Ca2+/calmodulin- and forskolin-stimulated enzyme activities, and this effect was not additive with that elicited by carbachol. Membrane incubation with either one of two betagamma scavengers, the GDP-bound form of the alpha subunit of transducin and the QEHA fragment of type II adenylyl cyclase, reduced both the stimulatory and inhibitory effects of carbachol. These data provide evidence that in rat olfactory bulb the dual regulation of cyclic AMP by muscarinic receptors is mediated by betagamma subunits likely acting on distinct isoforms of adenylyl cyclase.

Phosphorylation of the gamma subunit of the retinal photoreceptor cGMP phosphodiesterase by the cAMP-dependent protein kinase and its effect on the gamma subunit interaction with other proteins.

Cyclic GMP phosphodiesterase, a key enzyme in phototransduction, is composed of P alpha beta and two P gamma subunits. Interaction of P gamma with P alpha beta or with the alpha subunit (T alpha) of transducin is crucial for the regulation of cGMP phosphodiesterase in retinal photoreceptors. Here we have investigated phosphorylation of P gamma by cAMP-dependent protein kinase and its functional effect on the P gamma interaction with P alpha beta or T alpha in vitro. P gamma, but not P gamma complexed with T alpha (both GTP and GDP forms), is phosphorylated. Measurement of 32P radioactivity in phosphorylated P gamma, analysis of phosphorylated P gamma by laser mass spectrometry, identification of phosphoamino acid, and phosphorylation of mutant forms of P gamma indicate that only threonine 35 in P gamma is phosphorylated. Phosphorylation of P gamma mutants also reveals that the C and N terminals of P gamma which are required for the regulation of P alpha beta functions are not involved in the P gamma phosphorylation but that arginine 33, which is ADP-ribosylated by an endogenous ADP-ribosyltransferase, is required for the phosphorylation. Phosphorylated P gamma has a higher inhibitory activity for trypsin-activated cGMP phosphodiesterase than nonphosphorylated P gamma, indicating that the P gamma-P alpha beta interaction is affected by P gamma phosphorylation. Nonphosphorylated P gamma inhibits both the GTPase activity of T alpha and the binding of a hydrolysis-resistant GTP analogue to T alpha, while P gamma phosphorylation reduces these inhibitory activities. These observations suggest that a P gamma domain containing threonine 35 is involved in the P gamma-T alpha interaction, and P gamma phosphorylation regulates the P gamma-T alpha interaction. Our observation suggests that P gamma phosphorylation by cAMP-dependent protein kinase may function for the regulation of phototransduction in vertebrate rod photoreceptors.

Piscine (Sparus aurata) α subunit of the G-protein transducin is homologous to mammalian cone and rod transducin

A novel cDNA encoding α subunit of the GTP-binding protein, transducin, has been cloned from a marine fish, Sparus aurata. The cDNA contains an open reading frame of 1050 nt (encoding 350 amino acid residues). A high degree of identity was found with known mammalian transducin proteins of cones (Gt2α) or rods (Gt1α): human Gt2α (80.2%), bovine Gt2α (79.3%), mouse Gt1α (78.2%), mouse Gt2α (78%) and bovine Gt1α (77.9%). Northern blot analysis of different tissues revealed a transcript of about 2.5 kb, which is expressed only in the fish eye and not in other tissues from adult fish, supporting its identification as transducin. Ontogeny of transducin mRNA expression during early development of Sparus aurata, determined by Northern blot analysis, showed very low levels in larvae 3 days after hatching but not earlier. Levels increased 3- and 6-fold on days 4 and 6 (respectively) compared with those on day 3 and remained essentially unchanged thereafter, until day 21 after hatching (the last day studied). Our results suggest that in fish only one α subunit of transducin is found, which shows similar identity with cone and rod α subunits of mammals.

Communication between Switch II and Switch III of the Transducin α Subunit Is Essential for Target Activation

Comparisons of the tertiary structures of the GDP-bound and guanosine 5'-O-(thiotriphosphate) (GTPgammaS)-bound forms of the alpha subunit of transducin (alphaT) indicate that there are three regions that undergo changes in conformation upon alphaT activation. Two of these regions, Switch I and Switch II, were originally identified in Ras, while Switch III appears to be unique to trimeric GTP-binding proteins (G proteins). We find that replacement of the Switch III region (aspartic acid 227 through asparagine 237) with a single alanine residue yields an alphaT subunit that fully binds and hydrolyzes GTP but no longer stimulates the activity of the cyclic GMP phosphodiesterase (PDE), the physiological target for transducin. We also show that changing glutamic acid 232 of alphaT to a leucine (E232L) had no effect on rhodopsin-stimulated GTP-GDP exchange nor on the GTP hydrolytic activity of alphaT. However, the GTPgammaS-bound form of the alphaTE232L mutant was unable to stimulate the activity of the cyclic GMP PDE. The lack of stimulation was not due to an inability of the alphaTE232L mutant to bind to the target. Taken together, these results indicate that glutamic acid 232 mediates a conformational coupling between Switch II and Switch III, which is essential for converting GTP-dependent G protein-target interactions into a stimulation of target/effector activity.

The Rat D4 Dopamine Receptor Couples to Cone Transducin (Gαt2) to Inhibit Forskolin-stimulated cAMP Accumulation

Based on its expression pattern and pharmacology, the D4 dopamine receptor may play a role in schizophrenia. Thus it is of interest to know what signaling pathways are utilized by this receptor. Previously, we showed that activation of D4 receptors in a mouse mesencephalic neuronal cell line (MN9D) inhibited forskolin-stimulated cAMP accumulation in a pertussis toxin-sensitive (Ptx-sensitive) fashion. Of the known Ptx-sensitive G-protein alpha subunits, MN9D-expressed Galphai2, GalphaoA, and GalphaoB; however, none of these coupled to the D4 receptor. Using a low stringency polymerase chain reaction cloning method, we found an additional Ptx-sensitive G-protein cone transducin (Galphat2) expressed in the MN9D cells. We also found that Galphat2 mRNA is highly expressed in rat mesencephalic tissue. To test the hypothesis that the D4 receptor couples to Galphat2, we cotransfected MN9D cells with the D4 receptor and a mutagenized Ptx-resistant Galphat2 subunit (mGalphat2). Application of the dopaminergic agonist quinpirole to cotransfected cells inhibited forskolin-stimulated cAMP accumulation in the presence or absence of Ptx. To our knowledge, this is the first report demonstrating that the D4 dopamine receptor functionally couples to a specific G-protein and that a non-opsin-like receptor can couple with a transducin subunit.

Residues within the polycationic region of cGMP phosphodiesterase gamma subunit crucial for the interaction with transducin alpha subunit. Identification by endogenous ADP-ribosylation and site-directed mutagenesis.

Interaction between the gamma subunit (Pgamma) of cGMP phosphodiesterase and the alpha subunit (Talpha) of transducin is a key step for the regulation of cGMP phosphodiesterase in retinal rod outer segments. Here we have utilized a combination of specific modification by an endogenous enzyme and site-directed mutagenesis of the Pgamma polycationic region to identify residues required for the interaction with Talpha. Pgamma, free or complexed with the alphabeta subunit (Palphabeta) of cGMP phosphodiesterase, was specifically radiolabeled by prewashed rod membranes in the presence of [adenylate-32P]NAD. Identification of ADP-ribose in the radiolabeled Pgamma and radiolabeling of arginine-replaced mutant forms of Pgamma indicate that both arginine 33 and arginine 36 are similarly ADP-ribosylated by endogenous ADP-ribosyltransferase, but only one arginine is modified at a time. Pgamma complexed with Talpha (both GTP- and GDP-bound forms) was not ADP-ribosylated; however, agmatine, which cannot interact with Talpha, was ADP-ribosylated in the presence of Talpha, suggesting that a Pgamma domain containing these arginines is masked by Talpha. A Pgamma mutant (R33,36K), as well as wild type Pgamma, inhibited both GTP hydrolysis of Talpha and GTP binding to Talpha. Moreover, GTP-bound Talpha activated Palphabeta that had been inhibited by R33,36K. However, another Pgamma mutant (R33,36L) could not inhibit these Talpha functions. In addition, GTP-bound Talpha could not activate Palphabeta inhibited by R33,36L. These results indicate that a Pgamma domain containing these arginines is required for its interaction with Talpha, but not with Palphabeta, and that positive charges in these arginines are crucial for the interaction.

On the Mechanism of the Inhibition of Transducin Function by Farnesylcysteine Analogs

The gamma subunits of heterotrimeric G proteins are isoprenylated/methylated on their carboxy termini. The photoreceptor G protein, transducin, is farnesylated/methylated at this position. Since the isoprenyl group is required for G protein function, it is of great interest to determine the mechanism by which the farnesyl group of Tgamma interacts with the other transducin subunits and/or the activated photoreceptor, rhodopsin. Farnesylcysteine derivatives (N-acetyl-S-farnesyl-L-cysteine and farnesylated peptides) have been previously shown to have effects on transducin activity at high concentrations. Here, an extensive survey is done of farnesylcysteine analogs and other lipid molecules, which are tested for their ability to inhibit GTP/GDP exchange in transducin catalyzed by photolyzed rhodopsin. These studies are carried out to determine the nature of the inhibition process. While it does not appear that these molecules exhibit the specificity which would characterize a ligand-receptor type mechanism, the results suggest that these compounds are not acting in a nonspecific detergent-like manner either. The most likely mode of action of famesylcysteine analogs is that they interfere with the lipid-lipid based association of Talpha and Tbetagamma through the lipid modifications present on each subunit.

A Novel Form of the G Protein β Subunit Gβ5 Is Specifically Expressed in the Vertebrate Retina

The G protein beta subunit, Gbeta5, is predominantly expressed in the central nervous system. In rodent brain, Gbeta5 is expressed as a protein with an apparent molecular mass of 39,000 daltons (39 kDa). We have identified an additional Gbeta5 immunoreactive protein of apparent size 44 kDa in the vertebrate retina. Molecular cloning and sequencing of polymerase chain reaction products revealed that the cDNA encoding the larger species of Gbeta5 (Gbeta5L) was identical to the shorter form with the addition of 126 base pairs of 5' DNA sequence potentially encoding an in-frame 42-amino acid extension. Sequencing of mouse Gbeta5 genomic clones demonstrated that the 126-base pair of retinal-specific coding material is derived from a hitherto undetected 5' exon. During sucrose density gradient fractionation of bovine retinas, the 44-kDa Gbeta5L protein co-purified with rod outer segment membranes. Incubation of rod outer segment membranes with the nonhydrolyzable guanine nucleotide, GTPgammaS (guanosine 5'-3-O-(thio)triphosphate), which released the Gbeta subunit of transducin (Gbeta1), failed to remove Gbeta5L. The 39-kDa Gbeta5 protein displayed differential association with retinal and brain membranes. In the retina, Gbeta5 was present as a soluble protein and was undetectable in the membrane fraction, whereas in the brain approximately 70% of Gbeta5 was associated with cellular membranes. In transient COS-7 cell expression experiments, Gbeta5L formed functional Gbetagamma dimers and Galphabetagamma heterotrimers, and activated phosphoinositide-specific phospholipase Cbeta2 in a manner indistinguishable from the 39-kDa Gbeta5 protein. The cloning of the retinal-specific Gbeta5L cDNA suggests the existence of potentially novel G protein-mediated signaling cascades in photoreception.

G-protein alpha subunit Gi(alpha)2 mediates erythropoietin signal transduction in human erythroid precursors.

Erythropoietin induces a dose-dependent increase in cytosolic calcium in human erythroblasts that is mediated by a voltage-independent Ca2+ channel. Inhibition of this response to erythropoietin by pertussis toxin suggests involvement of guanine nucleotide-binding regulatory proteins (G-proteins). The role of G-proteins in regulation of the erythropoietin-modulated Ca2+ channel was delineated here by microinjection of G-protein modulators or subunits into human erythroid precursors. This is the first report on the use of microinjection to study erythropoietin signal transduction in normal precursor cells. Fura-2 loaded day-10 burst-forming units-erythroid-derived erythroblasts were used for microinjection and free intracellular calcium concentration ([Ca(i)]) was measured with digital video imaging. BCECF (1,2',7'-bis(2-carboxyethyl)-5-(and -6-)-carboxyfluorescein) was included in microinjectate, and an increase in BCECF fluorescence was evidence of successful microinjection. Cells were microinjected with nonhydrolyzable analogues of GTP, GTPgammaS or GDPbetaS, which maintain the alpha subunit in an activated or inactivated state, respectively. [Ca(i)] increased significantly in a dose-dependent manner after microinjection of GTPgammaS. However, injection of GDPbetaS blocked the erythropoietin-induced calcium increase, providing direct evidence that activation of a G-protein is required. To delineate which G-protein subunits are involved, alpha or betagamma transducin subunits were purified and microinjected as a sink for betagamma or alpha subunits in the erythroblast, respectively. Transducin betagamma, but not alpha, subunits eliminated the calcium response to erythropoietin, demonstrating the primary role of the alpha subunit. Microinjected antibodies to Gi(alpha)2, but not Gi(alpha)1 or Gi(alpha)3, blocked the erythropoietin-stimulated [Ca(i)] rise, identifying Gi(alpha)2 as the subunit involved. This was confirmed by the ability of microinjected recombinant myristoylated Gi(alpha)2, but not Gi(alpha)1 or Gi(alpha)3 subunits, to reconstitute the response of pertussis toxin-treated erythroblasts to erythropoietin. These data directly demonstrate a physiologic function of G-proteins in hematopoietic cells and show that Gi(alpha)2 is required in erythropoietin modulation of [Ca(i)] via influx through calcium channels.

Interaction Sites of the COOH-terminal Region of the γ Subunit of cGMP Phosphodiesterase with the GTP-bound α Subunit of Transducin

In photoreceptor cells, visual transduction occurs through photoexcitation of rhodopsin, GTP activation of the alpha subunit of transducin, and interaction between GTP-bound transducin alpha subunit and the inhibitory gamma subunit of phosphodiesterase. The gamma subunit of phosphodiesterase, in turn, accelerates the hydrolysis of GTP on the alpha subunit of transducin. Within the COOH-terminal residues (46-87) of the phosphodiesterase gamma subunit, Trp-70 has been implicated in phosphodiesterase activation, transducin alpha subunit-phosphodiesterase gamma subunit interaction, and the GTP hydrolysis accelerating activity. We have derivatized the phosphodiesterase gamma subunit with a reversible photoactivatable reagent, [125I]N-[(3-iodo-4-azidophenylpropionamido-S-(2-thiopyridyl) ]cysteine ([125I]ACTP), at cysteine (Cys-68). A light-dependent, cross-linked complex of guanosine 5'-(gamma-thio)triphosphate-bound transducin alpha subunit and ACTPderivatized phosphodiesterase gamma subunit formed after photolysis of a 1:1 stoichiometic complex of the two proteins. The specificity of complex formation between the transducin alpha subunit and the phosphodiesterase gamma subunit was demonstrated by specific protection by the C68A mutant of the phosphodiesterase gamma subunit. The cross-linked complex was treated with beta-mercaptoethanol to transfer the 125I photomoiety from the phosphodiesterase gamma subunit to the transducin alpha subunit. Combined techniques involving electrophoresis, chemical and enzymatic cleavage, and chemical and radiosequencing were used to identify photoinsertion sites on the alpha3 and alpha4/beta6 regions of the transducin alpha subunit. Three photo-labeled residues, His-244 (alpha3 helix), Met-308, and Arg-310 (alpha4/beta6 interface), were specifically identified as photoinsertion sites. Utilizing the crystal structure coordinates of the GTP-bound transducin alpha subunit and molecular modeling, we conclude that Cys-68 of the phosphodiesterase gamma subunit is located at a position between the exposed face of the alpha3 and alpha4 helices of the transducin alpha subunit. We propose that the phosphodiesterase gamma subunit interacts with GTP-bound transducin alpha subunit at multiple sites in which the cysteine 68 to tryptophan 70 sequence of the phosphodiesterase gamma subunit, which is critical for GTP hydrolysis accelerating activity, interacts in the alpha3/alpha4/beta6 region of GTP-bound transducin alpha subunit.

G-protein βγ Subunits Mediate Specific Phosphorylation of the Protein-tyrosine Phosphatase SH-PTP1 Induced by Lysophosphatidic Acid

SH-PTP1 is a protein-tyrosine phosphatase preferentially expressed in hematopoietic cells and bearing two SH2 (src homology-2) domains. In the human megakaryocytic cell line Dami, lysophosphatidic acid (LPA) promoted a rapid increase in SH-PTP1 phosphorylation on both serine and tyrosine residues. Only tyrosine phosphorylation was significantly inhibited by pertussis toxin and by the protein kinase C inhibitor GF109203X. Moreover, SH-PTP1 was phosphorylated upon challenge with other agonists acting via G-protein-coupled receptors such as alpha-thrombin, epinephrine, and ADP, whereas the closely related protein-tyrosine phosphatase SH-PTP2 failed to share such a regulation in Dami cells. We developed an in vitro assay that reproduced LPA-dependent phosphorylation of SH-PTP1 in a cell-free system. The fusion protein glutathione S-transferase-beta-adrenergic receptor kinase 1-(495-689) or the transducin subunit Galphat-GDP, which act as specific antagonists of Gbetagamma, inhibited SH-PTP1 phosphorylation. Moreover, purified transducin Gbetagamma subunits mimicked the effect of LPA. Finally, stable expression of beta-adrenergic receptor kinase 1-(495-689) in Dami cells resulted in the inhibition of SH-PTP1 as a specific target of protein kinases linked to G-protein-coupled receptors via Gbetagamma subunits.

Missense mutation in the gene encoding the alpha subunit of rod transducin in the Nougaret form of congenital stationary night blindness.

Patients with congenital stationary night blindness enjoy normal daytime vision, which is mediated by cone photoreceptors, but are blind when ambient light is so dim that a normal individual would utilize only rod photoreceptors to see without colour discrimination. The disease is genetically heterogeneous. One form of dominantly inherited congenital night blindness is eponymously named "Nougaret' because pedigree analysis reveals that the disease originated in Jean Nougaret (1637-1719), a butcher who lived in Vendémian in southern France. Here we report that his affected descendants carry a missense mutation in the gene encoding the alpha subunit of rod transducin the G-protein that couples rhodopsin to cGMP-phosphodiesterase in the phototransduction cascade. Based on these results, rod transducin joins rhodopsin and the beta subunit of rod cGMP-phosphodiesterase to become the third component of the rod phototransduction cascade where a defect is implicated as a cause of stationary night blindness. Interestingly, the amino acid residue in transducin affected by the Nougaret mutation is in the position homologous to that affected by the oncogenic mutation originally reported in p21ras, a distant relative in the G-protein superfamily.

Uncoupling of GTP Binding from Target Stimulation by a Single Mutation in the Transducin α Subunit

Glutamic acid-203 of the alpha subunit of transducin (alphaT) resides within a domain that undergoes a guanosine triphosphate (GTP)-induced conformational change that is essential for effector recognition. Changing the glutamic acid to an alanine in bovine alpha(T) yielded an alpha subunit (alpha(T)E203A) that was fully dependent on rhodopsin for GTP-guanosine diphosphate (GDP) exchange and showed GTP hydrolytic activity similar to that measured for wild-type alpha(T). However, unlike the wild-type protein, the GDP-bound form of alpha(T)E203A was constitutively active toward the effector of transducin, the cyclic guanosine monophosphate phosphodiesterase. Thus, the alpha(T)E203A mutant represents a short-circuited protein switch that no longer requires GTP for the activation of the effector target phosphodiesterase.

Cyclic AMP-dependent phosphoprotein components I and II interact with beta gamma subunits of transducin in frog rod outer segments.

Components I and II (CI&II) in frog rod outer segments (ROS) are prominent cAMP-dependent protein kinase (PK-A) substrates. Their phosphorylation level is high in the dark, and illumination causes dephosphorylation. In order to understand their physiological role in phototransduction, biochemical characterization of CI&II phosphorylation was performed. Fractionation of phosphorylated ROS proteins showed that CI&II in the soluble fraction were highly phosphorylated by endogenous PK-A, whereas those in the membrane-associated protein fractions were not. The latter proteins could be phosphorylated by purified catalytic subunit of PK-A (PK-Acat) while the former proteins were not, suggesting that membrane-bound CI&II are normally much less phosphorylated. Treatments that dissociate the alpha subunit (alpha t) of transducin (Gt) from beta gamma subunits (beta gamma t) and thus produce excess free subunits of Gt in the soluble fraction caused inhibition of CI&II phosphorylation in the soluble fraction and enhancement of CI&II phosphorylation in the peripheral membrane fractions containing less Gt. Unphosphorylated CI&II tightly associated with the washed ROS membranes could be extracted after phosphorylation by PK-Acat. Phosphorylation also caused elution of beta gamma t from the membrane under the same conditions. Cross-linking by the maleimidobenzoyl-N-hydroxysuccinimide ester of the peripheral membrane fraction produced a distinct phosphorylated 50 kDa product with concurrent disappearance of the beta subunit of transducin (beta t) and phosphorylated CI&II. This phosphorylated cross-linked product was not recognized by a monoclonal anti-alpha t antibody but was recognized by antiserum against beta t, suggesting that the 50 kDa protein is a complex of beta gamma t and CI&II. Amino terminal sequencing of components I and II suggests that they are identical proteins with a unique sequence unrelated to other proteins in protein data bases. Phosphopeptide mapping of phosphorylated CI&II in the soluble fraction yielded two trypsinized phosphopeptides, while that in the peripheral membrane fractions showed only one phosphopeptide. These data suggest that multiple phosphorylation of CI&II alters their cellular localization. We conclude that phosphorylation of CI&II controls their localization in frog ROS and an interaction of CI&II with subunits of Gt regulates their phosphorylation.

A novel regulatory mechanism for trimeric GTP-binding proteins in the membrane and secretory granule fractions of human and rodent β cells

Recently we described roles for heterotrimeric and low-molecular-mass GTP-binding proteins in insulin release from normal rat islets. During these studies, we observed that a protein with an apparent molecular mass (37 kDa) similar to that of the beta subunit of trimeric GTP-binding proteins underwent phosphorylation in each of five classes of insulin-secreting cells. Incubation of the beta cell total membrane fraction or the isolated secretory granule fraction (but not the cytosolic fraction) with [gamma-32P]ATP or [gamma-32P]GTP resulted in the phosphorylation of this protein, which was selectively immunoprecipitated by an anti-serum directed against the common beta subunit of trimeric G-proteins. Disruption of the alpha beta gamma trimer (by pretreatment with either fluoroaluminate or guanosine 5'(-)[gamma-thio]triphosphate) prevented beta subunit phosphorylation. Based on differential sensitivities to pH, heat and the histidine-selective reagent diethyl pyrocarbonate (and reversal of the latter by hydroxylamine), the phosphorylated amino acid was presumptively identified as histidine. Incubation of pure beta subunit alone or in combination with the exogenous purified alpha subunit of transducin did not result in the phosphorylation of the beta subunit, but addition of the islet cell membrane fraction did support this event, suggesting that membrane localization (or a membrane-associated factor) is required for beta subunit phosphorylation. Incubation of phosphorylated beta subunit with G alpha.GDP accelerated the dephosphorylation of the beta subunit, accompanied by the formation of G alpha-GTP. Immunoblotting detected multiple alpha subunits (of Gi, G(o) and Gq) and at least one beta subunit in the secretory granule fraction of normal rat islets and insulinoma cells. These data describe a potential alternative mechanism for the activation of GTP-binding proteins in beta cells which contrasts with the classical receptor-agonist mechanism: G beta undergoes transient phosphorylation at a histidine residue by a GTP-specific protein kinase; this phosphate, in turn, may be transferred via a classical Ping-Pong mechanism to G alpha.GDP (inactive), yielding the active configuration G alpha.GTP in secretory granules (a strategic location to modulate exocytosis).

The differences in the expressions of visual pigments and transducin in photoreceptor cell differentiation.

The distribution and accumulation of visual pigments, i.e., rod pigment, rhodopsin and red sensitive cone pigment, iodopsin, and transducin in the retina of chicken and chicken embryo were investigated immunohistochemically using their specific antibodies. The immunoreactivities of these proteins appeared at the early stage of photoreceptor differentiation (embryonal day 15) and increased in the photoreceptor cells appeared to reach maximum at the end of the embryonal period (embryonal day 20). On the other hand, although the immunoreactivity of beta gamma subunit of transducin (T beta gamma) was detected at embryonal day 15, the expression level of T beta gamma still remained in low level during the embryonal period. These observations suggest that both T beta gamma and visual pigments are expressed during the embryonic period in chicken photoreceptor cells, but their accumulations in the cells are different.

Use of resonance energy transfer to determine the proximity of the guanine nucleotide binding site of transducin relative to a conformationally-sensitive site on the gamma subunit of the cyclic GMP phosphodiesterase.

In this work, we have used resonance energy transfer to determine the relative positions of a reactive cysteine residue on the gamma subunit of the retinal cyclic GMP phosphodiesterase (gamma PDE) and a reactive lysine residue on the alpha subunit of transducin (alpha T). The single cysteine residue on gamma PDE (residue 68) is located at a site that is sensitive to the binding of both the inactive and active forms of alpha T. This is demonstrated by the finding that the addition of an alpha T-GDP complex to a gamma PDE subunit labeled with the environmentally-sensitive probe 2-(4-maleimidoanilino)naphthalene-6-sulfonate (MIANS) results in an enhancement in the MIANS fluorescence. The alpha TGDP-induced fluorescence enhancement is dose-dependent and yields an apparent Kd value of approximately 3 microM. Activation of alpha TGDP by aluminum fluoride, when bound to the MIANS-labeled gamma PDE (M-gamma PDE), then results in a quenching of the MIANS fluorescence. The aluminum fluoride-induced change in M-gamma PDE fluorescence occurs on a time scale identical to that observed for changes in the intrinsic alpha T fluorescence that correspond to activating conformational changes in the alpha T "switch II" region. These results suggest that the induction of the activated state of the alpha T subunit results in a change in conformation close to cysteine 68 in gamma PDE.(ABSTRACT TRUNCATED AT 250 WORDS)

Rod photoreceptor-specific gene expression in human retinoblastoma cells.

Retinoblastoma cells in culture have previously been shown to express cone-specific genes but not their rod counterparts. We have detected the messages for the rod alpha, beta, and gamma subunits of cGMP phosphodiesterase (PDE), the rod alpha subunit of transducin, rod opsin, and the cone alpha' subunit of PDE in RNA of human Y-79 retinoblastoma cells by reverse transcription-PCR. Quantitative analysis of the mRNAs for the rod alpha and cone alpha' PDE subunits revealed that they were expressed at comparable levels; however, the transcript encoding the rod beta PDE subunit was 10 times more abundant in these cells. Northern hybridization analysis of Y-79 cell RNA confirmed the presence of the transcripts for rod and cone PDE catalytic subunits. To test whether the transcriptional machinery required for the expression of rod-specific genes was endogenous in Y-79 retinoblastoma cells, cultures were transfected with a construct containing the promoter region of the rod beta PDE subunit gene attached to the firefly luciferase reporter vector. Significant levels of reporter enzyme activity were observed in the cell lysates. Our results demonstrate that the Y-79 retinoblastoma cell line is a good model system for the study of transcriptional regulation of rod-specific genes.