The nature and origin of spontaneous noise in G protein-gated ion channels

Arrival of agonist is generally thought to initiate the signal transduction process in G protein-receptor coupled systems. However, the muscarinic atrial K+ (K+[ACh]) channel opens spontaneously in the absence of applied agonist, giving a noisy appearance to the current records. We investigated the nature and origin of the noise by measuring single channel currents in cell-attached or excised, inside-out membrane patches. Guanosine triphosphate (GTP) produced identical single channel currents in a concentration- and Mg(2+)-dependent manner in the presence or absence of carbachol, but the requirements for GTP were greater in the absence of agonist. Hence the agonist-independent currents appeared to be produced by an endogenous G protein, Gk. This prediction was confirmed when an affinity-purified, sequence-specific Gi-3 alpha antibody or pertussis toxin (PTX) blocked the agonist-independent currents. Candidate endogenous agonists were ruled out by the lack of effect of their corresponding antagonists. Thus agonist-independent currents had the same nature as agonist-dependent K+[ACh] currents and seemed to originate in the same way. We have developed a hypothesis in which agonist-free, empty receptors prime Gk with GTP and Gk activates atrial K+ [ACh] channels producing basal currents or noise. Agonist-independent activation by G proteins of effectors including ion channels appears to be a common occurrence.     

Interaction of aluminum ions with phosphoinositide metabolism in rat cerebral cortical membranes

Aluminum (Al) is believed to exert a primary role in the neurotoxicity associated with dialysis encephalopathy and has been suggested to be involved in a number of other neurological disorders, including Alzheimer's disease. Al, complexed with fluoride to form fluoroaluminate (AlF4-), can activate the GTP-binding (G) proteins of the adenylate cyclase and retinal cyclic GMP phosphodiesterase systems. Since an involvement of G-proteins with cerebral phosphoinositide (PtdIns) metabolism has also been suggested, in this study we investigated the interaction of the stable GTP analogue GTP(S), Al salts and NaF with this system. In rat cerebral cortical membranes, GTP(S) dose-dependently stimulated [3H]inositol phosphates ([3H]InsPs) accumulation. This effect was potentiated by carbachol and was partially prevented by the GTP-binding antagonist GDP(S), indicating that CNS muscarinic receptor activation is coupled to PtdIns hydrolysis via putative G-protein(s). GTP(S) stimulation was also inhibited by phorbol 12-myristate 13-acetate (PMA), an activator of protein kinase C, which is known to exert a negative feedback control on agonist-stimulated PtdIns metabolism. Both Al salts and NaF mimicked the action of GTP(S) in stimulating PtdIns turnover. Their actions were highly synergistic, suggesting that AlF4- could be the active stimulatory species. However, the stimulatory effects of AlCl3 and/or NaF were not potentiated by carbachol and were not inhibited by GDP(S) and PMA, suggesting that separate sites of action might exist for GTP(S) and AlF4-. In the nervous tissue, activation of PtdIns hydrolysis by Al (probably as AlF4-) may be mediated by activating a regulatory G-protein at a location distinct from the GTP-binding site or by a direct stimulation of phospholipase C.     

Characterization of the aluminum and beryllium fluoride species which activate transducin. Analysis of the binding and dissociation kinetics.

Aluminofluoride and beryllofluoride complexes can activate the heterotrimeric G-proteins by binding next to GDP in the nucleotide site of their G alpha subunit and acting as analogs of the gamma-phosphate of a GTP. However, the exact structures of the activatory complexes in solution as well as those of the bound complexes in the nucleotide site are still disputed. We have studied, by monitoring the activation-dependent tryptophan fluorescence of transducin T alpha subunit, the pF (-log[F-]) and pH dependencies of the kinetics of activation and deactivation of T alpha GDP in the presence of NaF and aluminum or beryllium salts. Comparisons were made with the calculated pF and pH dependencies of the distribution of the metallofluoride complexes, in order to identify the activating species. We observed that the contribution of a magnesium-dependent mechanism of activation by fluoride (Antonny, B., Bigay, J., and Chabre, M. (1990) FEBS Lett. 268, 277-280) and effects due to slow equilibration kinetics between various aluminofluoride complexes could give rise to puzzling kinetics that had caused misinterpretations of previous results. Once corrected for these effects, our results suggest that with aluminum AlF3(OH)- is, rather than AlF4-, the main activating species and that the bound form of the complex is tetracoordinated GDP-AlF3. Deactivation kinetics depend on the free fluoride concentration in the medium, suggesting that the simple bimolecular scheme: T alpha GDP-AlF3 in equilibrium with T alpha GDP+AlF3(OH) does not fully describe the interaction. Fluorides in the bound complexes can also exchange with free F- ions in solution. With beryllium, two complexes are activatory: BeF3-.H2O and BeF2(OH)-.H2O. In the nucleotide site these give two tetracoordinated complexes, GDP.BeF3 and GDP.BeF2(OH), as shown by their different dissociation rates.     

Beta gamma dimers of G proteins inhibit atrial muscarinic K+ channels

It has been proposed that beta gamma dimers of signal-transducing G proteins mediate muscarinic activation of atrial K+ channels. We examined this hypothesis by testing the effects of beta gamma dimers from four sources (human erythrocytes, human placenta, bovine brain, and bovine retina) on single channel muscarinic K+ (K+[acetylcholine (ACh)]) currents in inside-out membrane patches of adult guinea pig atria. None of the four beta gamma dimer preparations stimulated K+[ACh] currents; on the contrary, each inhibited the currents whether the currents were activated with GTP alone (agonist-independent activity) or with GTP plus a muscarinic agonist (agonist-dependent activity). Detergents at concentrations used to suspend erythrocyte, brain, and placental beta gamma dimers had no effect by themselves, and detergents were not used with the retinal beta gamma dimers. We conclude that beta gamma dimers do not mediate stimulatory effects of the endogenous G protein that regulates the K+ channels. In fact beta gamma dimers appear to inhibit activation by the endogenous G alpha subunits. Further insight into the role of beta gamma dimers came from the observation that agonist-independent GTP-activated K+[ACh] currents were inhibited by beta gamma dimers at about one-tenth the concentration required to inhibit agonist-dependent activation. One possibility is that dimeric beta gamma may have a higher affinity for free alpha subunits than for alpha subunits associated with agonist-occupied receptors. Thus, in addition to the known requirement of beta gamma dimers for the interaction of alpha subunits with receptors, beta gamma dimers may also improve the signal-to-noise ratio for agonists by reducing agonist-independent background activities.     

Leukotriene C4 modulation of muscarinic K+ current activation in bullfrog atrial myocytes

The effects of leukotriene C4 (LTC4) on activation of muscarinic acetylcholine receptor (mAChR)-stimulated, inwardly rectifying K+ current (IK[ACh]) were examined in single bullfrog atrial myocytes using the whole-cell patch clamp technique. LTC4 produced a reversible, concentration-dependent increase in steady-state, guanosine-gamma- thiotriphosphate (GTP gamma S)-activated IK[ACh], with a K0.5 of 3.1 microM. LTC4 also increased the rate of GTP gamma S-mediated IK[ACh] activation, both in the absence and presence of 1 nM ACh, with comparable K0.5 values of 4.7 microM under basal conditions and 4.9 microM in the presence of 1 nM ACh. LTC4 did not alter the relative affinities of the G protein, Gk, for GTP gamma S and GTP. We hypothesize that all of the effects of LTC4 on the kinetics of Gk- mediated IK[ACh] activation are produced at a common site with a K0.5 of 3-5 microM. The effects of LTC4 on IK[ACh] activation are fully reversible in the presence of GTP gamma S. Under physiological conditions (i.e., intracellular GTP), 10 microM LTC4 increased the ACh- activated peak IK[ACh]. Inhibitors of cellular LTC4 production, including 5,8,11,14-eicosatetraynoic acid, baicalein, cinnamyl-3,4- dihydroxy-alpha-cyanocinnamate, and alpha-pentyl-4-(2- quinolinylmethoxy)-benzene methanol, greatly attenuated ACh-dependent IK[ACh] activation, preventing activation of peak, and producing a lower steady-state IK[ACh] (when compared with the control response in the same cell). Addition of exogenous LTC4 was able to overcome the effects of LTC4 synthesis inhibitors, restoring both the peak and steady-state IK[ACh] responses. Although the mechanism of LTC4-mediated modulation of IK[ACh] activation is not known, our results suggest that endogenously produced lipoxygenase metabolites of arachidonic acid, specifically LTC4, are involved in the physiological process of IK[ACh] activation.     

On the mechanism of basal and agonist-induced activation of the G protein-gated muscarinic K+ channel in atrial myocytes of guinea pig heart

Using the patch clamp technique, we examined the agonist-free, basal interaction between the muscarinic acetylcholine (m-ACh) receptor and the G protein (GK)-gated muscarinic K+ channel (IK.ACh), and the modification of this interaction by ACh binding to the receptor in single atrial myocytes of guinea pig heart. In the whole cell clamp mode, guanosine-5'-O-(3-thiotriphosphate) (GTP-gamma S) gradually increased the IK.ACh current in the absence of agonists (e.g., acetylcholine). This increase was inhibited in cells that were pretreated with islet-activating protein (IAP, pertussis toxin) or N-ethylmaleimide (NEM). In inside-out patches, even in the absence of agonists, intracellular GTP caused openings of IK.ACh in a concentration-dependent manner in approximately 80% of the patches. Channel activation by GTP in the absence of agonist was much less than that caused by GTP-gamma S. The agonist-independent, GTP-induced activation of IK.ACh was inhibited by the A promoter of IAP (with nicotinamide adenine dinucleotide) or NEM. As the ACh concentration was increased, the GTP-induced maximal open probability of IK.ACh was increased and the GTP concentration for the half-maximal activation of IK.ACh was decreased. Intracellular GDP inhibited the GTP-induced openings of IK.ACh in a concentration-dependent fashion. The half-inhibition of IK.ACh openings occurred at a much lower concentration of GDP in the absence of agonists than in the presence of ACh. From these results, we concluded (a) that the interaction between the m-ACh receptor and GK is essential for basal stimulation of IK.ACh, and (b) that ACh binding to the receptor accelerates the turnover of GK and increases GK's affinity to GTP analogues over GDP.     

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.     

Evidence that guanine-nucleotide binding regulatory proteins couple cell-surface receptors to the breakdown of inositol-containing lipids during T-lymphocyte mitogenesis

We have studied the role of guanine-nucleotide binding regulatory proteins (G proteins) in the stimulation of inositol lipid breakdown during mitogenic activation of normal human T lymphocytes. The effect of the mitogen phytohemagglutinin (PHA) was compared with the action of two G-protein activators, fluoroaluminate (AlF4-) and guanosine-5'-O-thiotriphosphate (GTP gamma S). PHA and AlF4- stimulated the breakdown of inositol lipids via both the phospholipase A and C pathways when added to intact lymphocytes. PHA, AlF4- and GTP gamma S also triggered both these pathways when added to permeable lymphocytes. The magnitude of the response obtained with AlF4- and GTP gamma S was about four-fold less than with PHA. This difference was attributable to increases in cAMP elicited by AlF4- and GTP gamma S which inhibited the phospholipase pathways. AlF4-, GTP gamma S, and PHA all stimulated the phosphorylation of a 42 kDa protein on tyrosine residues. We propose a model for the early steps following mitogen binding, including sequential activation of a G protein, phospholipase C, protein kinase C and a tyrosine protein kinase. A parallel pathway involving G protein mediated activation of phospholipase A is also implicated.     

Arachidonic acid metabolites alter G protein-mediated signal transduction in heart. Effects on muscarinic K+ channels

The muscarinic acetylcholine receptor (mAChR)-stimulated, inwardly rectifying K+ current (IK [ACh]) was examined in single bullfrog atrial cells using the whole-cell patch clamp technique. IK[ACh] was activated either by bath addition of 1 microM ACh or via activation of the G protein, Gk, with guanosine-gamma-thiotriphosphate (GTP gamma S). Arachidonic acid (AA) modulated IK[ACh] under both conditions. AA decreased mAChR-stimulated IK[ACh] and increased the rate of decay from the peak current (desensitization). In addition, AA affected GTP gamma S-activated IK[ACh] by modulation of Gk. The effects of AA and its metabolites on Gk were assessed by examining their effects on both the basal rate of Gk activation by GTP gamma S, and the mAChR-mediated increase in activation rate produced by nanomolar ACh. AA increased the basal rate of GTP gamma S-mediated IK[ACh] activation, but reduced the ACh-induced augmentation of this rate. All of the effects of AA on GTP gamma S-mediated IK[ACh] activation were produced by metabolites. A lipoxygenase inhibitor, nordihydroguaiaretic acid (NDGA), decreased the basal and ACh-enhanced rate of IK[ACh] activation in both the presence and absence of exogenous AA. In contrast, indomethacin (INDO), a cyclooxygenase inhibitor, increased the basal rate of IK[ACh] activation by GTP gamma S in both the presence and absence of exogenous AA, and reversed the effects of AA on the ACh-augmented basal rate. AA metabolites produced via lipoxygenase and cyclooxygenase pathways thus have opposing effects on the signal transduction pathway from mAChR to IK[ACh]. We directly tested a lipoxygenase pathway metabolite, LTC4, on GTP gamma S-mediated IK[ACh] activation and found that it not only overcame the inhibitory effects of NDGA, but also increased both the basal and ACh-augmented rate of IK[ACh] activation. From these data, we propose that AA metabolites modulate the function of Gk by altering its kinetic properties.     

Minimal determinants for binding activated G alpha from the structure of a G alpha(i1)-peptide dimer

G-proteins cycle between an inactive GDP-bound state and an active GTP-bound state, serving as molecular switches that coordinate cellular signaling. We recently used phage display to identify a series of peptides that bind G alpha subunits in a nucleotide-dependent manner [Johnston, C. A., Willard, F. S., Jezyk, M. R., Fredericks, Z., Bodor, E. T., Jones, M. B., Blaesius, R., Watts, V. J., Harden, T. K., Sondek, J., Ramer, J. K., and Siderovski, D. P. (2005) Structure 13, 1069-1080]. Here we describe the structural features and functions of KB-1753, a peptide that binds selectively to GDP x AlF4(-)- and GTPgammaS-bound states of G alpha(i) subunits. KB-1753 blocks interaction of G alpha(transducin) with its effector, cGMP phosphodiesterase, and inhibits transducin-mediated activation of cGMP degradation. Additionally, KB-1753 interferes with RGS protein binding and resultant GAP activity. A fluorescent KB-1753 variant was found to act as a sensor for activated G alpha in vitro. The crystal structure of KB-1753 bound to G alpha(i1) x GDP x AlF4(-) reveals binding to a conserved hydrophobic groove between switch II and alpha3 helices and, along with supporting biochemical data and previous structural analyses, supports the notion that this is the site of effector interactions for G alpha(i) subunits.     

Phosphatase is responsible for run down, and probably G protein- mediated inhibition of inwardly rectifying K+ currents in guinea pig chromaffin cells

The mechanism of G protein-mediated inhibition of an inwardly rectifying K+ current (IIR) in adrenal chromaffin cells was investigated using the whole-cell version of the patch clamp technique. In case of recording with use of ATP-containing patch solution, the IIR was well maintained; otherwise, it ran down within 15 min. This run down was not prevented by replacement with adenylyl-imidodiphosphate, a nonhydrolysable analogue of ATP, but was markedly reduced by the addition to the ATP-free solution of 1 microM calyculin A, a specific inhibitor of serine/threonine phosphatase 1 (PP1) and 2A (PP2A). The addition of alkaline phosphatase to the ATP-containing solution facilitated run down of the current, and application of 100 microM H-7, a general kinase inhibitor, reversibly suppressed IIR. These results taken together suggest that inwardly rectifying K+ channels are under the influence of kinase and phosphatase without external signals. Infusion of nonhydrolysable analogues of GTP, guanosine-5'-O-(3- thiophosphate) (GTP gamma S) or guanylyl-imidodiphosphate, through the pipette produced little inward current at -55 mV, but completely inhibited IIR within approximately 5 or 6 min in all cells tested in the presence of 12 microM Mg2+ inside the cell. In contrast, infusion of aluminum fluoride (AlF) complex, another GTP binding (G) protein activator, consistently produced large inward currents, but did not alter IIR noticeably for 15 min in 17% of the cells tested. In the other cells, the inhibition of IIR developed slowly after long latent periods. This inhibitory potency of AlF was not enhanced by an increase in Mg2+ concentrations. Subtraction of the current-voltage relationship before from that noted during the generation of inward current by AlF complex revealed that the inward current diminished progressively with hyperpolarizations, as is the case with a nonselective cation current (INS) induced by a muscarinic agonist. Thus, AlF complex seems to be potent with the generation of INS, but not with IIR inhibition. The addition of 3 microM calyculin A significantly retarded the IIR inhibition by GTP gamma S, whereas that of 1 microM okadaic acid, another inhibitor of PPI and PP2A, markedly prevented the decline of IIR by AIF complex. Our observations suggest that the low potency of AlF complex in inhibiting IIR may be due to interference with phosphatase activity and that the activation of G protein suppresses IIR, probably by enhancing the apparent activity of phosphatase, which may explain run down of the current.     

Calcium sensitization produced by G protein activation in airway smooth muscle

We determined whether activation of G proteins can affect the force developed for a given intracellular Ca(2+) concentration ([Ca(2+)]; i.e., the Ca(2+) sensitivity) by mechanisms in addition to changes in regulatory myosin light chain (rMLC) phosphorylation. Responses in alpha-toxin-permeabilized canine tracheal smooth muscle were determined with Ca(2+) alone or in the presence of ACh, endothelin-1 (ET-1), or aluminum fluoride (AlF; acute or 1-h exposure). Acute exposure to each compound increased Ca(2+) sensitivity without changing the response to high [Ca(2+)] (maximal force). However, chronic exposure to AlF, but not to chronic ACh or ET-1, increased maximal force by increasing the force produced for a given rMLC phosphorylation. Studies employing thiophosphorylation of rMLC showed that the increase in force produced by chronic AlF exposure required Ca(2+) during activation to be manifest. Unlike the acute response to receptor agonists, which is mediated solely by increases in rMLC phosphorylation, chronic direct activation of G proteins further increases Ca(2+) sensitivity in airways by additional mechanisms that are independent of rMLC phosphorylation.     

Effects of adenyl nucleotides and carbachol on cooperative interactions among G proteins.

Muscarinic agonists and adenyl nucleotides are noncompetitive modulators of sites labeled by [35S]GTP gamma S in washed cardiac membranes from Syrian golden hamsters. Specific binding of the radioligand and its inhibition by either GTP gamma S or GDP reveals three states of affinity for guanyl nucleotides. In the absence of adenyl nucleotide, carbachol promotes an apparent interconversion of sites from higher to lower affinity for GDP; the effect recalls that of guanyl nucleotides on the binding of agonists to muscarinic receptors. In the presence of 0.1 mM ATP gamma S, the binding of [35S]GTP gamma S is increased at concentrations up to about 50 nM and decreased at higher concentrations. At a radioligand concentration of 160 pM, binding exhibits a bell-shaped dependence on the concentration of both ATP gamma S and AMP-PNP; with ADP and ATP, there is a second increase in bound [35S]GTP gamma S at the highest concentrations of adenyl nucleotide. ATP gamma S and AMP-PNP also modulate the effect of GDP, which itself emerges as a cooperative process: that is, binding of the radioligand in the presence of AMP-PNP exhibits a bell-shaped dependence on the concentration of GDP; moreover, the GDP-dependent increase in bound [35S]GTP gamma S is enhanced by carbachol. The interactions among GDP, GTP gamma S, and carbachol can be rationalized quantitatively in terms of a cooperative model involving two sites tentatively identified as G proteins. Both GTP gamma S and GDP exhibit negative homotropic cooperativity; carbachol enhances the homotropic cooperativity of GDP and induces or enhances positive heterotropic cooperativity between GDP and [35S]GTP gamma S. An analogous mechanism may underlie the guanyl nucleotide-dependent binding of agonists to muscarinic receptors. The data suggest that the binding properties of G proteins and their associated receptors reflect cooperative effects within heterooligomeric arrays; agonist-induced changes in cooperativity may facilitate the exchange of GTP for bound GDP and thereby constitute the mechanism of G protein activation in vivo.     

Regulation of hormone-sensitive GTP-dependent regulatory proteins by chloride

The activities of GTP-dependent regulatory proteins (G proteins) are modulated by anions. Thus, NaCl stimulated the intensity of the intrinsic tryptophan fluorescence of Go alpha with bound guanosine 5'-(3-O-thio)triphosphate (GTP gamma S) and GTP, but not GDP. This mimics the effect of Mg2+. The salt also increased the affinity of Go alpha for GTP gamma S and GTP, but not GDP, an effect primarily due to decreases in rates of dissociation of the nucleotides. Among the effects of NaCl on the hydrolysis of GTP was an inhibition of the catalytic rate. The modulation of these activities occurred with half-maximal effects in the range of 3-20 mM NaCl. Salts of both chloride and bromide increased the affinity of Go alpha for GTP gamma S; fluoride and iodide were essentially ineffective. Nitrates produced only small and variable effects while SO4(2-) always reduced the affinity. The different cations utilized altered the effect of the anions slightly. The demonstration of direct effects of anions on the alpha subunit of Go suggests that G proteins are one site of action for anion modulation of systems that utilize these proteins. The effects of chloride at modest concentrations suggest potential physiological importance. Chloride may allow activation of G proteins with GTP in the absence of Mg2+ and without subsequent hydrolysis of the nucleotide.     

Molecular mechanism of doxorubicin-induced anticholinergic effect in guinea-pig atria

The molecular mechanisms of anticholinergic actions of doxorubicin were examined by electrophysiological methods in atria and myocytes isolated from guinea-pig heart. A direct anticholinergic action of doxorubicin was confirmed with antagonistic action on carbachol-induced negative inotropic effect in atria. Both carbachol and adenosine produced shortening of action potential duration in atria measured by a microelectrode method. Doxorubicin (10-100 microM) inhibited the carbachol-induced action potential shortening in a concentration-dependent manner. However, doxorubicin did not antagonize the shortening elicited by adenosine. The whole-cell voltage clamp technique was performed to induce the muscarinic acetylcholine-receptor-operated K+ current (IK.ACh) in atrial myocytes loaded with GTP or GTPgammaS, a nonhydrolysable analogue of GTP. Doxorubicin (1-100 microM) suppressed carbachol-induced IK.ACh in a concentration-dependent manner (IC50 = 5.6 microM). In contrast, doxorubicin (10 and 100 microM) suppressed neither adenosine-induced IK.ACh nor GTPgammaS-induced IK.ACh. These results indicate that doxorubicin produces a direct anticholinergic effect through the muscarinic receptors in atrial myocytes.     

Recombinant alpha i-3 subunit of G protein activates Gk-gated K+ channels

G proteins, particularly those sensitive to pertussis toxin, are difficult to separate biochemically, creating uncertainty in functional assignments. For this reason the cDNAs encoding G alpha i-3 and two of the G alpha s splice variants were expressed as fusion proteins in Escherichia coli using a T7 promoter-based expression system. These proteins were denoted r alpha i-3 and r alpha s (short and long) and accumulated in bacteria to as much as 5-10% of total cellular protein, of which 5-10% was soluble in lysates. Soluble r alpha subunits were tested for stimulation of K+ channel activity in inside-out atrial membrane patches and for reconstitution of cyc- adenylyl cyclase activity. r alpha i-3, activated either by guanosine 5'-(3-thio)triphosphate (GTP gamma S) or AlF-4, stimulated in a concentration-dependent manner single channel K+ currents in isolated atrial membrane patches of three species: guinea pigs, neonatal rats, and embryonic chick. In contrast, GTP gamma S-activated r alpha s did not. In agreement with a similar study by Graziano et al. (Graziano, M. P., Casey, P. J. and Gilman, A. G. (1987) J. Biol. Chem. 262, 11375-11381), both r alpha s forms reconstituted GTP gamma S-stimulated cyc- adenylyl cyclase activity, albeit at concentrations 50-100 times higher than those needed with native Gs. The concentrations of r alpha i-3 needed to stimulate the K+ channels were also higher than needed with native human erythrocyte Gk, in this case 30-50 times. Single K+ channel currents stimulated by r alpha i-3 were indistinguishable from those stimulated by the natural effector acetylcholine. Thus, bacterial expression of G alpha subunits provided the means to demonstrate unequivocally that Gi-3 has intrinsic Gk activity.     

Role of GTP-binding proteins in the regulation of mammalian cardiac chloride conductance

Beta-Adrenoceptor agonists activate a time- and voltage-independent Cl- conductance in mammalian cardiac myocytes. To characterize the cellular signaling pathways underlying its regulation, wide-tipped pipettes fitted with a pipette perfusion device were used to record whole-cell current and to introduce nucleotides to the interior of guinea pig ventricular myocytes. Replacement of pipette GTP with GDP beta S prevented activation of the Cl- conductance by Iso, suggesting a requirement for G protein turnover. With GTP in the pipette, the effect of Iso could be abolished by the beta-adrenoceptor antagonist propranolol, and mimicked by histamine or forskolin. These actions of Iso and forskolin are mediated exclusively via cAMP-dependent protein kinase (PKA), because (a) maximal activation of the Cl- conductance by forskolin or pipette cAMP occluded the effect of Iso, and (b) switching to pipette solution containing a synthetic peptide inhibitor (PKI) of PKA completely abolished the Cl- conductance activated by Iso and prevented the action of forskolin, but had no further effect. These results argue against basal activation of the Cl- conductance, and make it extremely unlikely that the stimulatory G protein, Gs, has any direct, phosphorylation-independent influence. The muscarinic receptor agonists acetylcholine (ACh) and carbachol diminished, in a reversible manner, Cl- conductance activated by Iso or forskolin, but not that elicited by cAMP. The muscarinic inhibition was abolished by replacing pipette GTP with GDP beta S, or by preincubating cells with pertussis toxin (PTX), and was therefore mediated by an inhibitory G protein, presumably Gi, influencing adenylyl cyclase activity. Nonhydrolyzable GTP analogues (GTP gamma S or GppNHp) applied via the pipette did not themselves activate Cl- conductance, but rendered Cl- current activation by brief exposures to Iso or histamine, but not to forskolin, irreversible. The Cl- conductance persistently activated by Iso was insensitive to propranolol or ACh, but could still be abolished by pipette application of PKI. The data indicate that stimulation of beta-adrenergic or histaminergic receptors in the presence of nonhydrolyzable GTP analogues causes persistent activation of Gs and uncouples it from the receptors. We conclude that autonomic regulation of cardiac Cl- conductance reflects accurately the underlying modulation of adenylyl cyclase activity and, hence, that this system is a suitable mammalian model for in situ studies of the interactions between adenylyl cyclase, Gs, Gi, and forskolin.     

Effects of anions on the G protein-mediated activation of the muscarinic K+ channel in the cardiac atrial cell membrane. Intracellular chloride inhibition of the GTPase activity of GK

The effects of various intracellular anions on the G protein (GK)-mediated activation of the muscarinic K+ (KACh) channel were examined in single atrial myocytes isolated from guinea pig hearts. The patch clamp technique was used in the inside-out patch configuration. With acetylcholine (ACh, 0.5 microM) in the pipette, 1 microM GTP caused different magnitudes of KACh channel activation in internal solutions containing different anions. The order of potency of anions to induce the KACh channel activity at 0.5 microM ACh and 1 microM GTP was Cl- greater than or equal to Br- greater than 1-. In the SO4(2-) or aspartic acid internal solution, no channel openings were induced by 1 microM GTP with 0.5 microM ACh. In both the Cl- and SO4(2-) internal solutions (with 0.5 microM ACh) the relationship between the concentration of GTP and the channel activity was fit by the Hill equation with a Hill coefficient of approximately 3-4. However, the concentration of GTP at the half-maximal activation (Kd) was 0.2 microM in the Cl- and 10 microM in the SO4(2-) solution. On the other hand, the quasi-steady-state relationship between the concentration of guanosine-5'-o-(3-thiotriphosphate) and the channel activity did not differ significantly between the Cl- and SO4(2-) solutions; i.e., the Hill coefficient was approximately 3-4 and the Kd was approximately 0.06-0.08 microM in both solutions. The decay of channel activity after washout of GTP in the Cl- solution was much slower than that in the SO4(2-) solution. These results suggest that intracellular Cl- does not affect the turn-on reaction but slows the turn-off reaction of GK, resulting in higher sensitivity of the KACh channel for GTP. In the Cl- solution, even in the absence of agonists, GTP (greater than 1 microM) or ATP (greater than 1 mM) alone caused activation of the KACh channel, while neither occurred in the SO4(2-) solution. These observations suggest that the activation of the KACh channel by the basal turn-on reaction of GK or by phosphate transfer to GK by nucleoside diphosphate-kinase may depend at least partly on the intracellular concentration of Cl-.     

Involvement of pertussis-toxin-sensitive G protein in muscarinic-receptor-mediated inhibition of K(+)-activated 4-nitrophenylphosphatase activity of cardiac sarcolemma

The effects of the cholinergic agonist carbachol on ouabain-sensitive K(+)-activated 4-nitrophenylphosphatase (K(+)-O2NPhPase) activity of rabbit and pig ventricular sarcolemma were examined. Carbachol (0.01-1000 microM) alone had no effect on K(+)-O2NPase. However, in the presence of GTP (100 microM) or its analog guanosine 5'-[gamma-thio]triphosphate (GTP[S], 1 microM) the agonist reduced this enzymatic activity (IC50 = 0.3 microM) by about 45% in a concentration-dependent manner. The GTP[S]-dependent effect of carbachol was blocked by 10 microM atropine, an antagonist of muscarinic acetylcholine receptor (mAcChoR). In the presence of micromolar concentrations of ATP or the GDP analog guanosine 5'-[beta-thio]diphosphate, carbachol did not change sarcolemmal K(+)-O2NPhPase activity. GTP[S] alone reduced this activity (IC50 = 2 microM) by about 40% in a concentration-dependent manner with a lag period of about 3 min. This lag disappeared in the presence of carbachol. Treatment of sarcolemmal membranes with 20 micrograms/ml pertussis toxin, which catalyzed ADP-ribosylation of the 40-41-kDa alpha-subunits of inhibitory GTP-binding protein (Gi), abolished the GTP[S]-promoted inhibitory effect of carbachol. Immunochemically, these alpha-subunits were identified as alpha 12- and alpha i3-subunits. It is suggested that the carbachol-induced inhibition of ouabain-sensitive K(+)-O2NPhPase activity of mammalian myocardial sarcolemma is a result of a negative coupling between mAcChoR and Na+/K(+)-ATPase via Gi protein.