The stimulatory G protein of adenylyl cyclase, Gs, also stimulates dihydropyridine-sensitive Ca2+ channels. Evidence for direct regulation independent of phosphorylation by cAMP-dependent protein kinase or stimulation by a dihydropyridine agonist

We demonstrated recently that purified preparations of Gs, the stimulatory G protein of adenylyl cyclase, can stabilize Ca2+ channels in inside-out cardiac ventricle membrane patches stimulated prior to excision by the beta-adrenergic agonist isoprenaline or by the dihydropyridine agonist Bay K 8644 and that such preparations of Gs can restore activity to spontaneously inactivated cardiac Ca2+ channels incorporated into planar lipid bilayers (Yatani, A., Codina, J., Reeves, J.P., Birnbaumer, L., and Brown, A.M. (1987) Science 238, 1288-1292). To test whether these effects represented true stimulation and to further identify the G protein responsible, we incorporated skeletal muscle T-tubule membranes into lipid bilayers and studied the response of their Ca2+ channels to G proteins, specifically Gs, and manipulations known to be specific for Gs. In contrast to cardiac channels, incorporated T-tubule Ca2+ channels exhibit stable average activities over prolonged periods of time (up to 20 min at room temperature), allowing assessment of possible effects of G proteins under steady-state assay conditions. We report that exogenously added human erythrocyte GTP gamma S (guanosine 5'-O-(3-thiotriphosphate]-activated Gs (Gs) or its resolved GTP gamma S-activated alpha subunit (alpha s) stimulate T-tubule Ca2+ channels by factors of 2-3 in the presence of Bay K 8644, and of 10-20 in the absence of Bay K 8644 and that they do so in a manner that is independent of concurrent or previous phosphorylation by cAMP-dependent protein kinase. Activation of purified Gs by cholera toxin increases both its adenylyl cyclase stimulatory and its Ca2+ channel stimulatory effects. Ca2+ channels previously stimulated by the combined actions of Bay K 8644 and cAMP-dependent protein kinase still respond to Gs. We conclude that the responses seen are due to Gs rather than a contaminant, that the effect on Ca2+ channel activity is that of a true stimulation, akin to that on adenylyl cyclase, and show that a given G protein may regulate more than one effector system.     

Mechanism of fluoride activation of G protein-gated muscarinic atrial K+ channels.

Aluminum fluoride (AlF4-) activates the heterotrimeric G protein Gs (stimulatory G protein of adenylylcyclase) (Sternweis, P. C., and Gilman, A. G. (1982) Proc. Natl. Acad. Sci. U. S. A. 79, 4888-4891) and GT (transducin), and for GT, Bigay et al. (Bigay, J., Deterre, P., Pfister, C., and Chabre, M. (1985) FEBS Lett. 191, 181-185) have made the intriguing proposal that AlF4- acts by mimicking the gamma-phosphate of GTP. The endogenous G protein (probably G alpha i-2 or G alpha i-3 (Yatani, A., Mattera, R., Codina, J., Graf, R., Okabe, K., Padrell, E., Iyengar, R., Brown, A. M., and Birnbaumer, L. (1988) Nature 336, 680-682) that stimulates the muscarinic atrial K+ (K+[ACh]) channel is also thought to be activated by AlF4- (Kurachi, Y., Nakajima, T., and Ito, H. (1987) Circulation 76, 105P). To investigate the AlF4- mechanism, we applied potassium fluoride (KF) to the cytoplasmic face of inside-out membrane patches excised from guinea pig atria. We found that KF activated single K+[ACh] channel currents in both a concentration- and a Mg(2+)-dependent manner. Activation persisted following removal of KF, but unlike activation by guanosine 5'-(3-thiotriphosphate) (GTP gamma S), was fully reversed by removal of Mg2+. Evidence for Al3+ involvement was that the Al3+ chelator deferoxamine (500 microM) inhibited KF activation and that at low concentrations of KF (less than 1 mM), micromolar AlCl3 concentrations potentiated KF stimulation. The rate of activation produced by KF was far slower than the rate produced by GTP or GTP gamma S, and unlike these guanine nucleotides, the rate was unchanged in the presence of agonist. To test the gamma-phosphate-mimicking hypothesis, we evaluated the requirement for GDP; and to accomplish this, it was necessary to establish a condition that ensured exchange of guanine nucleotides. This condition was satisfied by using the muscarinic agonist carbachol because both the rate and the extent of activation of the K+[ACh] channels produced by GTP were much faster in carbachol, and both were greatly slowed when GDP was added along with GTP. By contrast, the effects of KF were unchanged by carbachol in the presence or absence of GDP. Further evidence that GDP is not essential for activation by AlF4- was provided by the observation that during carbachol activation and following extensive washing with GMP, guanosine 5'-O-(2-thiodiphosphate) at blocking concentrations had no effect on activation produced by KF.(ABSTRACT TRUNCATED AT 400 WORDS)     

Cellular distribution and biochemical characterization of G proteins in skeletal muscle: comparative location with voltage-dependent calcium channels.

GTP binding proteins have been proposed to play a role in excitation--contraction coupling. In a precedent study [Toutant et al., (1988), Biochem. J., 405-409], we determined that Bordetella pertussis toxin is able to catalyse ADP-ribosylation of two substrates in the detergent soluble fraction of total muscle extracts. Purified fractions of transverse tubule membranes (T-tubule membranes), a key element of the excitation--contraction coupling, were shown to exhibit a major ADP-ribosylated substrate at 40 kd and an immunoreactivity with antisera raised against purified bovine brain Go alpha or G beta. In the present study, we have investigated the cellular distribution of G protein subunits in comparison with that of the voltage-dependent Ca2+ channels by immunofluorescence on transverse and longitudinal sections of fast and slow muscles. With affinity-purified antibodies against G beta subunits, a fluorescent labelling underlined the myofibrils and sarcolemma, whereas a strong immunoreaction in a dotted pattern evoked the presence of the subunit in repetitive triadic structures. With anti-Go alpha antibodies, the immunofluorescence was more clearly focussed on a dotted pattern and the co-location with the voltage-dependent Ca2+ channel immunoreactivity indicates that both proteins were located in very close subcellular structures. Immunoblot analysis and PTX ADP-ribosylation of the purified light sarcoplasmic reticulum (LSR), heavy sarcoplasmic reticulum (HSR) and T-tubule subcellular fractions indicate the discrete presence of G proteins in LSR, an unambiguous labelling of the HSR fraction, while T-tubule membranes clearly appear very rich in a Go-like protein, confirming the observed preferential immunocytochemical distribution of G protein subunits.(ABSTRACT TRUNCATED AT 250 WORDS)     

The inhibitory guanine nucleotide-binding protein (Ni) purified from bovine brain is a high affinity GTPase

Using modifications of the methods of Bokoch et al. (Bokoch, G.M., Katada, T., Northup, J. K., Ui, M., and Gilman, A. G. (1984) J. Biol. Chem. 259, 3560-3567) and Codina et al. (Codina, J., Hildebrandt, J. D., Sekura, R. D., Birnbaumer, M., Bryan, J., Manclark, C. R., Iyengar, R., and Birnbaumer, L. (1984) J. Biol. Chem. 259, 5871-5886), we have purified a pertussis toxin substrate with the expected characteristics of the inhibitory guanine nucleotide-binding protein (Ni) essentially to homogeneity. The purified protein consists of 3 subunits of Mr 40,000, 35,000, and less than 10,000. The Mr 40,000 band is found, upon close examination, to consist of a poorly resolved doublet. Starting with the membranes from 1,320 g of bovine forebrain we purified the protein some 100-fold with approximately 20% yield to obtain 13 mg of a greater than 95% pure protein. Chromatography on octyl-Sepharose provided efficient separation of Ni from Ns (the stimulatory guanine nucleotide-binding protein). Analytical ultracentrifugation indicates an Mr of 82,000 and a sedimentation coefficient S20,w of 5.1. The protein is able to restore opiate-mediated inhibition of adenylate cyclase to membranes prepared from NG 108-15 cells which had been treated with pertussis toxin. Bovine brain Ni has the enzymatic properties of a low Km GTPase with a turnover number of 0.3 and affinities for nucleotides in the order GppNHp greater than or equal to GTP greater than or equal to GDP much greater than ATP, CTP, UTP, and GMP. Na+ specifically stimulates the GTPase and low concentrations of Mg2+ (less than 50 microM) are inhibitory. Some Mg2+ is apparently necessary because EDTA, but not EGTA, abolishes the GTPase activity.     

Enhanced calcium cycling and contractile function in transgenic hearts expressing constitutively active G alpha o* protein

In contrast to the other heterotrimeric GTP-binding proteins (G proteins) Gs and Gi, the functional role of G o is still poorly defined. To investigate the role of G alpha o in the heart, we generated transgenic mice with cardiac-specific expression of a constitutively active form of G alpha o1* (G alpha o*), the predominant G alpha o isoform in the heart. G alpha o expression was increased 3- to 15-fold in mice from 5 independent lines, all of which had a normal life span and no gross cardiac morphological abnormalities. We demonstrate enhanced contractile function in G alpha o* transgenic mice in vivo, along with increased L-type Ca2+ channel current density, calcium transients, and cell shortening in ventricular G alpha o*-expressing myocytes compared with wild-type controls. These changes were evident at baseline and maintained after isoproterenol stimulation. Expression levels of all major Ca2+ handling proteins were largely unchanged, except for a modest reduction in Na+/Ca2+ exchanger in transgenic ventricles. In contrast, phosphorylation of the ryanodine receptor and phospholamban at known PKA sites was increased 1.6- and 1.9-fold, respectively, in G alpha o* ventricles. Density and affinity of beta-adrenoceptors, cAMP levels, and PKA activity were comparable in G alpha o* and wild-type myocytes, but protein phosphatase 1 activity was reduced upon G alpha o* expression, particularly in the vicinity of the ryanodine receptor. We conclude that G alpha o* exerts a positive effect on Ca2+ cycling and contractile function. Alterations in protein phosphatase 1 activity rather than PKA-mediated phosphorylation might be involved in hyperphosphorylation of key Ca2+ handling proteins in hearts with constitutive G alpha o activation.     

Regulation of calmodulin-sensitive adenylate cyclase by the stimulatory G-protein, Gs

Studies in bovine and rat brain membranes have suggested that calmodulin can potentiate neurotransmitter- and GTP-stimulated adenylate cyclase activities. To examine whether calmodulin and the stimulatory G-protein, Gs, are potentiative at a calmodulin-sensitive adenylate cyclase, Gs was purified from rabbit liver and reconstituted with a partially purified calmodulin-sensitive adenylate cyclase from bovine brain. Activated Gs (G*s) stimulated basal adenylate cyclase activity and enhanced the stimulation by calmodulin. The potentiation of the calmodulin-stimulated adenylate cyclase activity was dose-dependent with respect to G*s concentration. At the highest concentration of G*s tested (3 nM), a 2-fold enhancement of the calmodulin-stimulated adenylate cyclase activity was observed at all concentrations of calmodulin. The synergistic activation of adenylate cyclase by calmodulin and Gs was dependent on the presence of Ca2+ and occurred at physiologically relevant Ca2+ concentrations. The potentiation was not observed when either a nonactivated Gs or a mixture of activated Gi/Go was used. G*s was not able to stimulate or potentiate a calmodulin-stimulated adenylate cyclase purified from membranes pretreated with the nonhydrolyzable GTP analog, guanyl-5'-yl beta,gamma-imidodiphosphate. Photochemical cross-linking of 125I-calmodulin-diazopyruvamide to proteins having an Mr corresponding to the known Mr of adenylate cyclase was not enhanced by G*s. The results demonstrate that the guanyl nucleotide-dependent enhancement of calmodulin-stimulated adenylate cyclase activity is mediated by G*s and suggest that G*s modulates the enzymatic turnover of the calmodulin-stimulated activity.     

Updated Protocols and Comments on the Purification without Use of Activating Ligands of the Coupling Proteins Ns and Ni of the Hormone Sensitive Adenylyl Cyclase

Abstract

N_s and N_i have been purified without using NaF and Mg as stabilizing agents (Codina, J., Hildebrandt, J.D., Sekura, R.D., Birnbaumer, M., Bryan, J., Manclark, C.R. and Birnbaumer, L. [1984] J. Biol. Chem. 259, in press). Since the submission of that report, several modifications have been introduced to the purification procedure and additional fractions have been processed from which N proteins are obtained. This article describes the updated protocols and presents methodological details not included in the previous publication. The final products are N_s, the stimulatory N, N_i the inhibitory N, both of subunit structure αβγ, and a M_r=40,000 protein of βγ composition. They are obtained from human erythrocytes.     

Guanosine 5'-O-(3-thiotriphosphate) reduces ADP-ribosylation of the inhibitory guanine nucleotide-binding regulatory protein of adenylyl cyclase (Ni) by pertussis toxin without causing dissociation of the subunits of Ni. Evidence of existence of heterotrimeric pt+ and pt- conformations of Ni

The effect of the addition of guanosine 5'-O-(3-thiotriphosphate) (GTP gamma S), the GTP analog which activates the inhibitory guanine nucleotide-binding regulatory protein of adenylyl cyclase (Ni), on the pertussis toxin-mediated ADP-ribosylation reaction was studied in detail. Two effects were discerned: a stimulation of the ADP-ribosyltransferase activity of the toxin, akin to what was described for ATP and GDP in a previous report (Mattera, R., Codina, J., Sekura, R., and Birnbaumer, L. (1986) J. Biol. Chem. 261, 11173-11179), and a decrease in the ability of Ni to be a substrate for the activated toxin. Both effects were time-dependent with activation of the toxin being somewhat faster than inactivation of Ni. The effect of the addition of GTP gamma S on Ni was readily reversed by excess GDP and attenuated by increasing EDTA in the medium from 0.35 to 10 mM, suggesting dependence on trace concentrations of a divalent cation. It is suggested that this cation is Mg2+ on the basis that low (5-10 nM) concentrations of Mg2+ are needed for the endogenous GTPase activity of Ni (Sunyer, T., Codina, J., and Birnbaumer, L. (1984) J. Biol. Chem. 259, 15447-15451). Sucrose density gradient analysis of the Ni X GTP gamma S complexes with decreased susceptibility to ADP-ribosylation by pertussis toxin showed the same sedimentation parameters as Ni or Ni X GDP complexes, indicating that the molecule of Ni with GTP gamma S bound is heterotrimetric as opposed to dissociated into alpha i X GTP gamma S plus beta X gamma. Thus, these experiments define two conformations of heterotrimeric Ni: one -pt+, ADP-ribosylated by pertussis toxin, and the other pt-, poorly or not ADP-ribosylated by pertussis toxin. This latter, hitherto unrecognized conformation, is stabilized by the addition of strongly activating guanine nucleotides such as GTP gamma S and guanyl-5'-yl imidodiphosphate and should be important in the train of events that lead from an inactive heterotrimeric Ni to a fully active and dissociated Ni.     

Dihydropyridine-sensitive calcium channels from skeletal muscle. II. Functional effects of differential phosphorylation of channel subunits.

Dihydropyridine-sensitive Ca2+ channels from skeletal muscle are multisubunit proteins and are regulated by protein phosphorylation. The purpose of this study was to determine: 1) which subunits are the preferential targets of various protein kinases when the channels are phosphorylated in vitro in their native membrane-bound state and 2) the consequences of these phosphorylations in functional assays. Using as substrates channels present in purified transverse (T) tubule membranes, cAMP-dependent protein kinase (PKA), protein kinase C (PKC), and a multifunctional Ca2+/calmodulin-dependent protein kinase (CaM protein kinase) preferentially phosphorylated the 165-kDa alpha 1 subunit to an extent that was 2-5-fold greater than the 52-kDa beta subunit. A protein kinase endogenous to the skeletal muscle membranes preferentially phosphorylated the beta peptide and showed little activity toward the alpha 1 subunit; however, the extent of phosphorylation was low. Reconstitution of partially purified channels into liposomes was used to determine the functional consequences of phosphorylation by these kinases. Phosphorylation of channels by PKA or PKC resulted in an activation of the channels that was observed as increases in both the rate and extent of Ca2+ influx. However, phosphorylation of channels by either the CaM protein kinase or the endogenous kinase in T-tubule membranes was without effect. Phosphorylation did not affect the sensitivities of the channels toward the dihydropyridines. Taken together, the results demonstrate that the alpha 1 subunit is the preferred substrate of PKA, PKC, and CaM protein kinase when the channels are phosphorylated in the membrane-bound state and that phosphorylation of the channels by PKA and PKC, but not by CaM protein kinase or an endogenous T-tubule membrane protein kinase, results in activation of the dihydropyridine-sensitive Ca2+ channels from skeletal muscle.     

N-linked protein glycosylation is a major determinant for basal TRPC3 and TRPC6 channel activity

The TRPC family of receptor-activated cation channels (TRPC channels) can be subdivided into four subfamilies based on sequence homology as well as functional similarities. Members of the TRPC3/6/7 subfamily share common biophysical characteristics and are activated by diacylglycerol in a membrane-delimited manner. At present, it is only poorly understood whether members of the TRPC3/6/7 subfamily are functionally redundant or whether they serve distinct cellular roles. By electrophysiological and fluorescence imaging strategies we show that TRPC3 displays considerable constitutive activity, while TRPC6 is a tightly regulated channel. To identify potential molecular correlates accounting for the functional difference, we analyzed the glycosylation pattern of TRPC6 compared with TRPC3. Two NX(S/T) motifs in TRPC6 were mutated (Asn to Gln) by in vitro mutagenesis to delete one or both extracellular N-linked glycosylation sites. Immunoblotting analysis of HEK 293 cell lysates expressing TRPC6 wild type and mutants favors a model of TRPC6 that is dually glycosylated within the first (e1) and second extracellular loop (e2) as opposed to the monoglycosylated TRPC3 channel (Vannier, B., Zhu, X., Brown, D., and Birnbaumer, L. (1998) J. Biol. Chem. 273, 8675-8679). Elimination of the e2 glycosylation site, missing in the monoglycosylated TRPC3, was sufficient to convert the tightly receptor-regulated TRPC6 into a constitutively active channel, displaying functional characteristics of TRPC3. Reciprocally, engineering of an additional second glycosylated site in TRPC3 to mimic the glycosylation status in TRPC6 markedly reduced TRPC3 basal activity. We conclude that the glycosylation pattern plays a pivotal role for the tight regulation of TRPC6 through phospholipase C-activating receptors.     

Direct activation of trpl cation channels by G alpha11 subunits.

G proteins of the Gq/11 subfamily functionally couple cell surface receptors to phospholipase C beta (PLC beta) isoforms. Stimulation of PLC beta induces Ca2+ elevation by inositol 1,4,5-trisphosphate (InsP3)-mediated Ca2+ release and store-dependent 'capacitative' Ca2+ entry through Ca(2+)-permeable channels. The Drosophila trp gene, as well as some human trp homologs, code for such store-operated channels. The related trp-like (trpl) gene product also forms a Ca(2+)-permeable cation channel, but is not activated by store depletion. Co-expression of the constitutively active Gq subfamily member G alpha 11 (G alpha 11) with trpl enhanced trpl currents 33-fold in comparison with co-expression of trpl with other G alpha isoforms or G beta gamma complexes. This activation could not be attributed to signals downstream of PLC beta. In particular, InsP3 infusion, modulation of protein kinase C activity or elevation of intracellular calcium concentration failed to induce trpl currents. In contrast, purified G alpha 11 (but not other G protein subunits) activated trpl channels in inside-out patches. We conclude that trpl is regulated by G11 proteins in a membrane-confined manner not involving cytosolic factors. Thus, G proteins of the Gq subfamily may induce Ca2+ entry not only indirectly via store-operated mechanisms but also by directly stimulating cation channels.     

Reconstitution of the voltage-sensitive calcium channel purified from skeletal muscle transverse tubules

The purified calcium antagonist receptor of the voltage-sensitive calcium channel from skeletal muscle transverse tubule membrane consists of three subunits: alpha with Mr 135 000, beta with Mr 50 000, and gamma with Mr 33 000. Purified receptor preparations were incorporated into phosphatidylcholine (PC) vesicles by addition of PC in 3-[(3-cholamidopropyl)dimethylammonio]-1-propanesulfonate and removal of detergent by molecular sieve chromatography. Forty-five percent of the alpha, beta, and gamma polypeptides and the [3H]dihydropyridine/receptor complex were recovered in association with PC vesicles. The rate of dissociation of the purified and reconstituted dihydropyridine/receptor complex was identical with that in T-tubule membranes, and allosteric modulation by verapamil and diltiazem was retained. The reconstituted calcium antagonist receptor, when occupied by the calcium channel activator BAY K 8644, mediated specific 45Ca2+ and 133Ba2+ transport into the reconstituted vesicles. 45Ca2+ influx was blocked by the organic calcium antagonists PN200-110 (K0.5 = 0.2 microM), D600 (K0.5 = 1.0 microM), and verapamil (K0.5 = 1.5 microM) and by inorganic calcium channel antagonists (La3+ greater than Cd2+ greater than Ni2+ greater than Mg2+) as in intact T-tubules. A close quantitative correlation was observed between the presence of the alpha, beta, and gamma subunits of the calcium antagonist receptor and the ability to mediate 45Ca2+ or 133Ba2+ flux into reconstituted vesicles. Comparison of the number of reconstituted calcium antagonist receptors and functional channels supports the conclusion that only a few percent of the purified calcium antagonist receptor polypeptides are capable of mediating calcium transport as previously demonstrated for calcium antagonist receptors in intact T-tubules.     

The G226A mutant of Gs alpha highlights the requirement for dissociation of G protein subunits.

Adenylylcyclase cannot be activated by hormones or guanine nucleotide analogs in membranes from cells that express the G226A mutant form Gs alpha instead of the wild-type protein. The mutant Gs alpha protein appears incapable of undergoing the conformational change necessary for guanine nucleotide-induced dissociation of the G protein alpha subunit from the beta gamma subunit complex (Miller, R.T., Masters, S.B., Sullivan, K.A., Beiderman, B., and Bourne, H.R. (1988) Nature 334, 712-715). G226A Gs alpha was synthesized in Escherichia coli, purified, and characterized. Examination of the kinetics of dissociation of guanosine 5'-3-O-(thio)triphosphate (GTP gamma S) suggests that G226A Gs alpha is incapable of assuming the conformation necessary for high affinity binding of Mg2+ to the alpha subunit-GTP gamma S complex. Associated changes include the failure of Mg2+ and GTP gamma S to confer resistance to tryptic proteolysis upon the protein, to enhance intrinsic tryptophan fluorescence, or to cause dissociation of alpha from beta gamma. However, the GTPase activity of the mutant protein is near normal (at high Mg2+ concentrations), and the protein is capable of activating adenylylcyclase. A similar defect is present in G49V Gs alpha. Failure of G protein subunit dissociation appears to be the explanation for the phenotypic properties of cells that express G226A Gs alpha, and this mutation thus highlights the crucial nature of this reaction as a component of G protein action.     

On the mechanism of G protein beta gamma subunit activation of the muscarinic K+ channel in guinea pig atrial cell membrane. Comparison with the ATP-sensitive K+ channel

The mechanism of G protein beta gamma subunit (G beta gamma)-induced activation of the muscarinic K+ channel (KACh) in the guinea pig atrial cell membrane was examined using the inside-out patch clamp technique. G beta gamma and GTP-gamma S-bound alpha subunits (G alpha *'s) of pertussis toxin (PT)-sensitive G proteins were purified from bovine brain. Either in the presence or absence of Mg2+, G beta gamma activated the KACh channel in a concentration-dependent fashion. 10 nM G beta gamma almost fully activated the channel in 132 of 134 patches (98.5%). The G beta gamma-induced maximal channel activity was equivalent to or sometimes larger than the GTP-gamma S-induced one. Half-maximal activation occurred at approximately 6 nM G beta gamma. Detergent (CHAPS) and boiled G beta gamma preparation could not activate the KACh channel. G beta gamma suspended by Lubrol PX instead of CHAPS also activated the channel. Even when G beta gamma was pretreated in Mg(2+)-free EDTA internal solution containing GDP analogues (24-48 h) to inactivate possibly contaminating G i alpha *'s, the G beta gamma activated the channel. Furthermore, G beta gamma preincubated with excessive GDP-bound G o alpha did not activate the channel. These results indicate that G beta gamma itself, but neither the detergent CHAPS nor contaminating G i alpha *, activates the KACh channel. Three different kinds of G i alpha * at 10 pM-10 nM could weakly activate the KACh channel. However, they were effective only in 40 of 124 patches (32.2%) and their maximal channel activation was approximately 20% of that induced by GTP-gamma S or G beta gamma. Thus, G i alpha * activation of the KACh channel may not be significant. On the other hand, G i alpha *'s effectively activated the ATP-sensitive K+ channel (KATP) in the ventricular cell membrane when the KATP channel was maintained phosphorylated by the internal solution containing 100 microM Mg.ATP. G beta gamma inhibited adenosine or mACh receptor-mediated, intracellular GTP-induced activation of the KATP channel. G i alpha *'s also activated the phosphorylated KATP channel in the atrial cell membrane, but did not affect the background KACh channel. G beta gamma subsequently applied to the same patch caused prominent KACh channel activation. The above results may indicate two distinct regulatory systems of cardiac K+ channels by PT-sensitive G proteins: G i alpha activation of the KATP channel and G beta gamma activation of the KACh channel.     

Hormonal regulation of pituitary GH3 cell K+ channels by Gk is mediated by its alpha-subunit

The resolved alpha-GTP gamma S (alpha*) and beta gamma-subunits of human erythrocyte Gk, the stimulatory regulatory component of hormone-responsive K+ channels, were tested for their potential stimulatory activities on the K+ channel of the endocrine GH3 cell. Concentrations as low as 0.5 pM alpha k* consistently activated K+ channels in isolated membrane patches, and saturating effects were obtained with 50 pM alpha k*. In contrast 2000-4000 pM beta gamma was without effect. We conclude that Gk acts on K+ channels through its alpha-subunit in a manner akin to that of Gs acting on adenylyl cyclase and transducin acting on cGMP-specific phosphodiesterase of photo-receptor cells.     

Control of voltage-dependent Ca2+ channels by G protein-coupled receptors

G proteins act as transducers between membrane receptors activated by extracellular signals and enzymatic effectors controlling the concentration of cytosolic signal molecules such as cAMP, cGMP, inositol phosphates and Ca2+. In some instances, the receptor/G protein-induced changes in the concentration of cytosolic signal molecules correlate with activity changes of voltage-dependent Ca2+ channels. Ca2+ channel modulation, in these cases, requires the participation of protein kinases whose activity is stimulated by cytosolic signal molecules. The respective protein kinases phosphorylate Ca2+ channel-forming proteins or unknown regulatory components. More recent findings suggest another membrane-confined mechanism that does not involve cytosolic signal molecules but rather a more direct control of voltage-dependent Ca2+ channels by G proteins. Modulation of Ca2+ channel activity that follows this apparently membrane-confined mechanism has been described to occur in neuronal, cardiac, and endocrine cells. The G protein involved in the hormonal stimulation of Ca2+ channels in endocrine cells may belong to the family of Gi-type G proteins, which are functionally uncoupled from activating receptors by pertussis toxin. The G protein Gs, which is activated by cholera toxin, may stimulate cardiac Ca2+ channels without the involvement of a cAMP-dependent intermediate step. Hormonal inhibition of Ca2+ channels in neuronal and endocrine cells is mediated by a pertussis toxin-sensitive G protein, possibly Go. Whether G proteins act by binding directly to Ca2+ channels or through interaction with as yet undetermined regulatory components of the plasma membrane remains to be clarified.     

Dihydropyridine-sensitive calcium channels from skeletal muscle. I. Roles of subunits in channel activity.

Dihydropyridine-sensitive Ca2+ channels from skeletal muscle are hetero-oligomeric proteins. Little is known about the functional roles of the various subunits, except that the alpha 1 subunit is the essential channel unit. We have reconstituted both partially purified holomeric channels and the separated subunits into liposomes and measured their properties using an assay based on the Ca2+ indicator dye fluo-3. The holomeric channels exhibited Ca2+ influx that was sensitive to membrane potential achieved by the addition of valinomycin in the presence of a K+ gradient. Dissipation of the K+ gradient resulted in the loss of the valinomycin-sensitive Ca2+ flux. In addition, the reconstituted channels were: 1) activated by the dihydropyridine Ca2+ channel activator Bay K 8644 in a dose-dependent manner with a Kd of 20 nM; 2) inhibited by various types of Ca2+ channel inhibitors including the dihydropyridine (+)-PN 200-110, the phenylalkylamine verapamil, and the benzothiazepine d-cis-diltiazem; and 3) modulated in a stereoselective manner by the enantiomers of the dihydropyridine S-202-791. The purified channels used in this work possessed an alpha 1 subunit of 165 kDa and did not appear to contain a larger alpha 1 subunit of approximately 210 kDa, suggesting that channel activity with properties similar to those observed in intact cells can be supported with an alpha 1 subunit of 165 kDa. Reconstituted channels that were 85% depleted in the alpha 2/delta subunits showed a significant decrease in the initial rate of Ca2+ influx induced by valinomycin, but retained responsiveness to Bay K 8644 and (+)-PN 200-110. When the separated alpha 2 and delta subunits were added back to the alpha 1 subunit-containing preparation, the channels exhibited their normal rate of Ca2+ influx. These results demonstrated that the dihydropyridine-sensitive Ca2+ channels from skeletal muscle require the presence of the alpha 2.gamma complex in stoichiometric amounts to exhibit full activity.     

Proteolytic processing of the C terminus of the alpha(1C) subunit of L-type calcium channels and the role of a proline-rich domain in membrane tethering of proteolytic fragments

Although most L-type calcium channel alpha(1C) subunits isolated from heart or brain are approximately 190-kDa proteins that lack approximately 50 kDa of the C terminus, the C-terminal domain is present in intact cells. To test the hypothesis that the C terminus is processed but remains functionally associated with the channels, expressed, full-length alpha(1C) subunits were cleaved in vitro by chymotrypsin to generate a 190-kDa C-terminal truncated protein and C-terminal fragments of 30-56 kDa. These hydrophilic C-terminal fragments remained membrane-associated. A C-terminal proline-rich domain (PRD) was identified as the mediator of membrane association. The alpha(1C) PRD bound to SH3 domains in Src, Lyn, Hck, and the channel beta(2) subunit. Mutant alpha(1C) subunits lacking either approximately 50 kDa of the C terminus or the PRD produced increased barium currents through the channels, demonstrating that these domains participate in the previously described (Wei, X., Neely, a., Lacerda, A. E. Olcese, r., Stefani, E., Perez-Reyes, E., and Birnbaumer, L. (1994) J. Biol. Chem. 269, 1635-1640) inhibition of channel function by the C terminus.     

Remodeling excitation-contraction coupling of hypertrophied ventricular myocytes is dependent on T-type calcium channels expression

We utilized Wistar rats with monocrotaline (MCT)-induced right ventricular hypertrophy (RVH) in order to evaluate the T-type Ca2+ channel current (ICaT) for myocardial contraction. RT-PCR provides that mRNA for T-type Ca2+ channel alpha1-subunits in hypertrophied myocytes was significantly higher than those in control rats (alpha1G; 264+/-36%, alpha1H; 191+/-34%; P<0.05). By whole-cell patch-clamp study, ICaT was recorded only in hypertrophied myocytes but not in control myocytes. The application of 50 nmol/L nifedipine reduced the twitch tension of the right ventricles equally in the control and RVH rats. On the other hand, 0.5 micromol/L mibefradil, a T-type Ca2+ channel blocker, strongly inhibited the twitch tension of the RVH muscle (control 6.4+/-0.8% vs. RVH 20.0+/-2.3% at 5 Hz; P<0.01). In conclusion, our results indicate the functional expression of T-type Ca2+ channels in the hypertrophied heart and their contribution to the remodeling of excitation-contraction coupling in the cardiac myocyte.     

Roles of G proteins in coupling of receptors to ionic channels and other effector systems

Guanine nucleotide binding (G) proteins are heterotrimers that couple a wide range of receptors to ionic channels. The coupling may be indirect, via cytoplasmic agents, or direct, as has been shown for two K+ channels and two Ca2+ channels. One example of direct G protein gating is the atrial muscarinic K+ channel K+[ACh], an inwardly rectifying K+ channel with a slope conductance of 40 pS in symmetrical isotonic K+ solutions and a mean open lifetime of 1.4 ms at potentials between -40 and -100 mV. Another is the clonal GH3 muscarinic or somatostatin K+ channel, also inwardly rectifying but with a slope conductance of 55 pS. A G protein, Gk, purified from human red blood cells (hRBC) activates K+ [ACh] channels at subpicomolar concentrations; its alpha subunit is equipotent. Except for being irreversible, their effects on gating precisely mimic physiological gating produced by muscarinic agonists. The alpha k effects are general and are similar in atria from adult guinea pig, neonatal rat, and chick embryo. The hydrophilic beta gamma from transducin has no effect while hydrophobic beta gamma from brain, hRBCs, or retina has effects at nanomolar concentrations which in our hands cannot be dissociated from detergent effects. An anti-alpha k monoclonal antibody blocks muscarinic activation, supporting the concept that the physiological mediator is the alpha subunit not the beta gamma dimer. The techniques of molecular biology are now being used to specify G protein gating. A "bacterial" alpha i-3 expressed in Escherichia coli using a pT7 expression system mimics the gating produced by hRBC alpha k.