Regulation of spontaneous opening of muscarinic K+ channels in rabbit atrium

Cardiac muscarinic potassium channel activity is attenuated by inhibitors of G beta gamma

The cardiac muscarinic potassium channel (IK.ACh) is activated by a G protein upon receptor stimulation with acetylcholine. The G protein subunit responsible for activation (G alpha versus G beta gamma) has been disputed. We used G beta gamma inhibitors derived from the beta-adrenergic kinase 1 (beta ARK1) to assess the relative importance of G beta gamma in IK.ACh activation. In rabbit atrial myocytes, IK.ACh had a conductance of 49 +/- 6.2 pS. In inside-out patches, the mean open time was 1.60 +/- 0.57 ms, mean time constant (tau o) was 1.59 +/- 0.53 ms, and mean closed time was 3.02 +/- 1.35 ms (n = 38). beta ARK1 is a G beta gamma-sensitive enzyme that interacts with G beta gamma through a defined sequence near its carboxyl terminus. A 28-amino-acid peptide derived from the carboxyl terminus of beta ARK1 (peptide G) increased the closed time to 10.04 ms (P < .001) and decreased opening probability (NPo) by 71% (P < .001). Fusion proteins containing the entire carboxyl terminus of beta ARK1, glutathione S-transferase beta ARK1ct and hexahistidine beta ARK1ct, decreased NPo by 67% (P = .03) and 48% (P = .009), respectively. They also both significantly increased the closed time. None of the inhibitors affected mean open time or channel amplitude. A control peptide derived from a neighboring region of beta ARK1 had no significant effect on IK.ACh activity. These results provide further evidence for the role of G beta gamma in the activation of IK.ACh.

Background conductance attributable to spontaneous opening of muscarinic K+ channels in rabbit sino-atrial node cells

Single myocytes were dissociated from the rabbit sino-atrial node, and the membrane background conductance produced by spontaneous opening of the muscarinic K+ channels was investigated by recording whole-cell and single channel currents in both normal K+ (5.4 mM) and high-K+ (145 mM) external solutions. Increasing external K+ concentration ([K+]o) from 5.4 to 145 mM induced a large inward shift of the whole-cell current accompanied by considerable current fluctuations at -50 mV. The high-K(+)-induced current was both K+ selective and voltage dependent, which was examined by varying [K+]o. This current was almost completely suppressed by 1-5 mM Ba2+ or 2-10 mM Cs+ and it was partly blocked by 10 microM atropine. In high-K+ (145 mM) solution, 20 nM acetylcholine (ACh) further increased the K+ conductance as well as the current noise. The power density spectrum of the noise was fitted with a sum of two Lorentzian functions. The corner frequencies of both the slow (approximately 5 Hz) and fast (approximately 120 Hz) components were comparable between the noise before and during the ACh application. Internal dialysis with a non-hydrolysable derivative of ATP, 5'-adenylylimido-diphosphate (AMP-PNP) or Mg(2+)-free solution markedly decreased both the amplitude and fluctuations of the high-K(+)-induced current. The relation between the variance of the current fluctuations and the mean current amplitude was linear in every experiment using dialysis of AMP-PNP or Mg(2+)-free internal solution, or using superfusion of ACh. The slopes of these relations gave comparable single channel current amplitudes of -0.7 pA at -50 mV. These results indicate that the spontaneous opening of the muscarinic K+ channels is largely responsible for the high-K(+)-induced current. In the high-K+ solution, the variance-mean relation at -50 mV showed that the muscarinic K+ channel provides an inward current of 3.12 +/- 2.13 pA pF-1 (n = 23), which was about 60% of the total inward background current. In the normal K+ solution, the variance-mean relation at -50 mV indicated that an outward current of 6.0 +/- 2.0 pA (0.33 +/- 0.28 pA pF-1, n = 8) was provided by the K+ channel. The single channel current amplitude was estimated to be 0.06 +/- 0.02 pA (n = 9). Cell-attached recordings in the absence of ACh demonstrated sporadic and brief openings of channels identical to the ACh-induced channels. The power density spectra of the single channel currents exhibited kinetic properties comparable with those of the whole-cell currents.(ABSTRACT TRUNCATED AT 400 WORDS)

Membrane-delimited activation of muscarinic K current by an albumin-associated factor in guinea-pig atrial myocytes

Atrial myocytes obtained by enzymatic perfusion of hearts from adult guinea-pigs and cultured for 0-14 days were studied using different configurations of the patch-clamp technique. Activation of muscarinic K current [IK(ACh)] in whole-cell voltage-clamp mode by strongly diluted sera from various sources could be mimicked by corresponding concentrations of albumin, but not by delipidated ("fatty-acid-free") samples of albumin. In cell-attached membrane patches activity of IK(ACh) channels was significantly higher than basal IK(ACh) channel activity, if the pipette contained serum, whereas application of serum-containing solution to the cell outside the patch did not affect channel activity. In isolated inside-out membrane patches, strong IK(ACh) activation by internal guanosine triphosphate (GTP, 5 microM) was observed if the pipette contained serum. If no activator was presented to the outer face of the membrane, only weak opening activity was observed during bath application of GTP. These results demonstrate that the serum factor which causes activation of IK(ACh) is associated with albumin. Furthermore activation of IK(ACh) by that factor proceeds analogous to ACh or adenosine, i.e. via a membrane-delimited receptor, G-protein, channel interaction.

Atrial G protein-activated K+ channel: expression cloning and molecular properties

Activity of several ion channels is controlled by heterotrimeric GTP-binding proteins (G proteins) via a membrane-delimited pathway that does not involve cytoplasmic intermediates. The best studied example is the K+ channel activated by muscarinic agonists in the atrium, which plays a crucial role in regulating the heartbeat. To enable studies of the molecular mechanisms of activation, this channel, denoted KGA, was cloned from a rat atrium cDNA library by functional coupling to coexpressed serotonin type 1A receptors in Xenopus oocytes. KGA displays regions of sequence homology to other inwardly rectifying channels as well as unique regions that may govern G-protein interaction. The expressed KGA channel is activated by serotonin 1A, muscarinic m2, and delta-opioid receptors via G proteins. KGA is activated by guanosine 5'-[gamma-thio]triphosphate in excised patches, confirming activation by a membrane-delimited pathway, and displays a conductance equal to that of the endogenous channel in atrial cells. The hypothesis that similar channels play a role in neuronal inhibition is supported by the cloning of a nearly identical channel (KGB1) from a rat brain cDNA library.

On the role of G protein activation and phosphorylation in desensitization to acetylcholine in guinea-pig atrial cells

1. The ACh-activated K+ current (IK,ACh) has been investigated in guinea-pig atrial cells at 36 degrees C using the whole-cell patch-clamp technique. 2. During an exposure to ACh, IK,ACh faded as a result of desensitization. Throughout the fade of the current, the current reversed at EK and showed inward-going rectification. The fade was, therefore, the result of a genuine decrease in IK,ACh. 3. The onset of desensitization (as judged by the fade of IK,ACh) was biphasic and the time constants of the fast and slow phases of desensitization were 1.58 +/- 0.14 (n = 16) and 148.2 +/- 12.8 s (n = 18) respectively. Recovery from the fast and slow phases of desensitization (after 30 s and 5 min exposures to ACh respectively) occurred with time constants of 52 and 222 s respectively. This suggests that two processes are involved in desensitization. 4. The Q10 of the rate constant of the fast phase of desensitization was 2.2 +/- 0.3 (n = 6). 5. Intracellular perfusion with guanosine 5'-O-(3-thiotriphosphate) (GTP gamma S) or extracellular perfusion with AlF4- were used to bypass the muscarinic receptor and trigger IK,ACh by directly activating the G protein, GK, that links the muscarinic receptor to the K+ channel. Both GTP gamma S and AlF4- activated a current with the same reversal potential and the same degree of inward-going rectification as the ACh-activated current. 6. Desensitization still occurred when the muscarinic receptor was bypassed and IK,ACh was triggered by direct activation of GK with either GTP gamma S or AlF4-. This suggests that desensitization is, in part, the result of a modification of either GK or the K+ channel. 7. Activation of the muscarinic receptor by ACh resulted in greater desensitization than direct activation of GK; at the end of a 5 min exposure to ACh, current was only 22 +/- 1% (n = 19) of its peak value, whereas, after direct activation of GK by GTP gamma S for 5 min, current was 42 +/- 6% (n = 5) of its peak value. This suggests that desensitization also involves the muscarinic receptor. 8. When cells were perfused with GTP gamma S, the fast phase of desensitization could still occur, but the slow phase was reduced. This suggests that the fast phase involves GK or the K+ channel, whereas the slow phase involves the muscarinic receptor.(ABSTRACT TRUNCATED AT 400 WORDS)

Agonist-independent effects of muscarinic antagonists on Ca2+ and K+ currents in frog and rat cardiac cells

1. The whole-cell patch clamp and intracellular perfusion techniques were used for studying the effects of atropine and other muscarinic acetylcholine receptor (mAChR) antagonists on the L-type calcium currents (ICa) in frog and rat ventricular myocytes, and on the mAChR-activated K+ current (IK(ACh)) in frog atrial myocytes. 2. In frog ventricular myocytes, atropine (0.1 nM to 1 microM) reversed the inhibitory effect of acetylcholine (ACh, 1 nM) on ICa previously stimulated by isoprenaline (Iso, 2 microM), a beta-adrenergic agonist. However, in the concomitant presence of Iso, ACh and atropine, ICa was > 50% larger than in Iso alone. 3. The effects of atropine were then examined in the absence of mAChR agonists. After a preliminary stimulation of ICa with Iso (0.1 or 2 microM), atropine induced a dose-dependent stimulation of ICa. EC50 (i.e. the concentration of atropine at which the response was 50% of the maximum) and Emax (i.e. maximal stimulation of ICa expressed as percentage increase in ICa with respect to the level in Iso alone) were respectively 0.6 nM and 35%. The stimulatory effect of atropine on ICa was not voltage dependent. 4. Atropine (1 microM) had no effect on frog ICa (i) under basal conditions, (ii) upon stimulation of ICa by the dihydropyridine agonist (-)-Bay K 8644 (1 microM), or (iii) when ICa had been previously stimulated by intracellular perfusion with cyclic AMP (3 microM). However, atropine increased ICa after a stimulation by forskolin (0.3 microM). Therefore, an increased adenylyl cyclase activity was required for atropine to produce its stimulatory effect on ICa. 5. The order of potency of mAChR antagonists to reverse the inhibitory effect of ACh on Iso elevated ICa in frog ventricle was atropine > AF-DX 116 >> pirenzepine. In the absence of ACh, mAChR antagonists produced their stimulatory effect on Iso elevated ICa with the same order of potency. 6. Intracellular substitution of Gpp(NH)p (5'-guanylylimidiphosphate) for GTP (420 microM) induced a strong inhibition of frog ICa in the presence of Iso (2 microM). This effect was attributed earlier to the spontaneous and irreversible activation of the GTP-binding regulatory protein (G protein), Gi, responsible for adenylyl cyclase inhibition. Atropine (1 microM) slowed down by a factor of 2 the rate of ICa inhibition induced by Gpp(NH)p. 7. In frog atrial myocytes, intracellular perfusion with 1 mM Gpp(NH)p induces spontaneous activation of IK(ACh). This effect was attributed earlier to the spontaneous and irreversible activation of the G protein, GK.(ABSTRACT TRUNCATED AT 400 WORDS)

Activation of muscarinic K+ current in guinea-pig atrial myocytes by a serum factor

1. Atrial myocytes obtained by enzymatic perfusion of hearts from adult guinea-pigs and cultured for 0-14 days were studied using the whole-cell voltage-clamp technique. 2. Superfusion of the myocytes with diluted sera (1:100 to 1:10,000) from different species (human, horse, guinea-pig) evoked an inward rectifying K+ current. The voltage-dependent properties of this current were identical to those of the K+ current activated by acetylcholine (IK(ACh)). Current density in the presence of horse serum (1:100) approximately corresponded to the non-desensitizing fraction of IK(ACh) during superfusion with 1-2 x 10(-6) M ACh. 3. During a maximal serum-evoked current, application of ACh (10(-6) M) failed to evoke additional K+ current. After switching superfusion from serum-containing to serum-free solution, the K+ current decayed 1-2 orders of magnitude slower than ACh-activated IK(ACh). During the decay of the serum-evoked current, a proportional increase in responsiveness to ACh was recorded. During submaximal activation of K+ current by serum, a saturating concentration of ACh resulted in a total current that was identical to the current evoked by ACh alone minus the desensitizing component. Thus, activation of K+ current by serum caused desensitization of IK(ACh). From these results it is concluded that sera contain a factor that activates the same population of K+ channels as ACh. 4. Irreversible activation of IK(ACh) by ACh in myocytes dialysed with the GTP-analogue GTP-gamma-S abolished sensitivity to serum and vice versa. 5. The effect of serum was not modified by atropine (10(-6) M) which completely blocked the response to 2 x 10(-6) M ACh. Furthermore, theophylline (1 mM), which completely inhibited IK(ACh) activation by adenosine (100 microM), failed to inhibit the effect of serum. Thus, neither muscarinic nor purinergic (A1) receptors are involved. 6. The peptide somatostatin (10(-6) M) and the alpha 1-agonist phenylephrine (1 microM) which previously have been shown to cause activation of IK(ACh) channels, in the present study failed to evoke any measurable current, which excludes the involvement of the corresponding receptors. 7. Pre-incubation of the cells with pertussis toxin completely abolished IK(ACh) evoked by ACh, adenosine and serum, suggesting that the activating factor, like the classical agonists, causes opening of IK(ACh) channels via a G protein (Gi, GK). 8. The potency of serum to activate IK(ACh) was not reduced by dialysis, suggesting the molecular mass of the unknown factor to be > or = 5 kDa. No activating potency was found in the dialysing solutions.(ABSTRACT TRUNCATED AT 400 WORDS)

Acetylcholine-mediated K+ channel activity in guinea-pig atrial cells is supported by nucleoside diphosphate kinase

We studied the role of nucleoside diphosphate kinase (NDPK) in acetylcholine-mediated muscarinic K+ channel activation in inside-out patches of guinea-pig atrial cells. NDPK-catalysed activation of the muscarinic K+ channels by adenosine triphosphate-Mg2+ (ATP-Mg2+) is not prevented by occupation of the muscarinic receptor [by acetylcholine (ACh) or atropine], nor by uncoupling of the receptor from the G protein by pertussis-toxin-catalysed adenosine diphosphate (ADP)-ribosylation of GK. In the presence of ACh, addition of 0.1 mM guanosine triphosphate (GTP) after activation of the channels by 4 mM ATP alone resulted in a moderate increase of channel activity (in contrast to block in the absence of ACh): NDPK-mediated direct transphosphorylation is uncoupled by the G nucleotide but agonist-induced guanosine diphosphate (GDP)-to-GTP exchange takes over activation of the channels. Moreover, ACh-dependent channel stimulation was possible in inside-out patches while ATP and GDP were present in the bathing solution (in contrast to the complete absence of channel activation in the absence of ACh). This indicates that NDPK synthesizes sufficient GTP to support channel activation by exchange. Hence, it is postulated that the main functional role of NDPK under physiological conditions is to provide a local supply of GTP (using GDP and ATP) in the immediate vicinity of the G protein, thereby maintaining a high local GTP/GDP ratio and ensuring adequate receptor-mediated regulation of muscarinic K+ channel activity.

Membrane-bound nucleoside diphosphate kinase activity in atrial cells of frog, guinea pig, and human

Muscarinic K+ channels in inside-out patches of atrial cells from guinea pig or rabbit can be activated by Mg(2+)-ATP in the absence of acetylcholine and GTP or GDP. The ATP-dependent activation involves a phosphorylation and is postulated to be due to the association of a membrane-bound nucleoside diphosphate kinase (NDPK) with the G protein GK: direct phosphorylation of the GK-bound GDP into GTP, catalyzed by NDPK, would result in activation of the G protein and, hence, activation of the channels. The aim of this study was to identify the presence of NDPK activity in atrial membranes by investigating the phosphate transfer between tritium-labeled nucleotides. We show that frog, guinea pig, and human atrial membranes contain a substantial NDPK activity since they catalyze the conversion from [3H]GDP+nucleoside triphosphate (NTP or NTP gamma S) to [3H]GTP (or [3H]GTP gamma S), from [3H]ADP+NTP to [3H]ATP, and from [3H]GTP+nucleoside diphosphate (NDP) to [3H]GDP. The phosphate transfer rates for the [3H]GDP+ATP to [3H]GTP conversion are 1.8, 0.5, and 2.4 mumol inorganic phosphate formation/mg per 10 minutes at 37 degrees C in frog, guinea pig, and human, respectively. The order of substrate efficiency for different NTPs was ATP greater than ITP approximately equal to GTP greater than UTP greater than CTP, which parallels the efficiency of these nucleotides in their activation of the muscarinic K+ channels. Addition of other nucleotides blocked the transphosphorylation reaction, indicating that the NTP-NDP conversion mechanism is aspecific, as is expected for an NDPK-catalyzed reaction. In conclusion, the data support the concept of NDPK involvement in the atrial muscarinic signal transduction cascade.

Activation of ?1-adrenoceptors modulates the inwardly rectifying potassium currents of mammalian atrial myocytes

The selective alpha 1-adrenergic agonist methoxamine (10(-4)-10(-3) M), in the presence of propranolol (10(-6) M), can reduce both the inwardly rectifying K+ background current (IK1) and the muscarinic cholinergic receptor-activated K+ current (IK,ACh) in rabbit atrial myocytes resulting in action potential prolongation during the final phase of repolarization and a depolarization of the resting membrane potential. The reduction of these K+ currents(s) by alpha 1-adrenoceptor stimulation was insensitive to pre-treatment of atrial myocytes with pertussis toxin (0.15-0.5 micrograms/ml) and was irreversible following intracellular dialysis with the non-hydrolysable guanosine triphosphate (GTP) analogue, Gpp(NH)p (1-5 x 10(-3) M). Neither the protein kinase C (PKC) inhibitors, 1((5-isoquinolinesulphonyl)-2-methylpiperoxine (H-7) (5 x 10(-5) M) and staurosporine (1 x 10(-7) M), nor "downregulation" of PKC by prolonged phorbol ester exposure (5 x 10(-7) M, for 7-8 h) had an effect on the alpha 1-adrenergic modulation of this K+ current. Under cell-attached patch-clamp conditions, bath application of methoxamine reversibly decreased acetylcholine-induced single-channel activity, thus confirming the observed reduction of the ACh-induced current under whole-cell voltage clamp. These results demonstrate that the alpha 1-adrenoceptor, once activated, can reduce current through two different inwardly rectifying K+ channels in rabbit atrial myocytes. These current changes are mediated via a pertussis toxin-insensitive GTP-binding protein, and do not appear to involve the activation of PKC.

Neuromodulation

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

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-.

Tonic inhibition and rebound facilitation of a neuronal calcium channel by a GTP-binding protein

A significant fraction of differentiated NG108-15 neuroblastoma/glioma cells have Ca2+ channel current different from that of undifferentiated cells. In the former cells, the Ca2+ channel sensitive to omega-conotoxin GVIA had slowed activation kinetics and was facilitated by depolarizing prepulses. These kinetic features are identical to those produced by inhibition of the channel by G proteins. Prolonged treatment with prostaglandin E1 and theophylline, agents that cause cellular differentiation, promoted incidence and extent of the tonic inhibition. Intracellular guanosine 5'-[beta-thio]diphosphate removed the tonic inhibition, suggesting sustained activation of a G protein, but pertussis toxin did not block it. A sulfhydryl alkylating agent, N-ethylmaleimide (0.1 mM), rapidly eliminated agonist-induced inhibition, whereas N-ethylmaleimide spared the tonic inhibition and the one induced by intracellular guanosine 5'-[gamma-thio]triphosphate. An agonist could further inhibit the Ca2+ channel that was already tonically inhibited. After washout of an inhibitory agonist, the tonic inhibition was temporarily removed. This "rebound facilitation" gradually faded within a few minutes. Pertussis toxin or N-ethylmaleimide prevented the rebound facilitation, whereas phorbol ester, forskolin, or arachidonic acid induced neither the rebound facilitation nor the tonic inhibition. Whatever its mechanism, the tonic inhibition of Ca2+ channels may serve as the basis for long-term and bidirectional regulation of activity of neuronal Ca2+ channels.