Effect of cromakalim and lemakalim on slow waves and membrane currents in colonic smooth muscle

New understanding of electrical activity brought by surface potential of cardiomyocytes

Aiming at the problem encountered in the previous research: during the electrical activity of cardiomyocytes, the influent ions do not seem to be directly derived from the extracellular fluid. We chose to cut in from the colloidal properties of the cells, follow the basic principles of physical chemistry, and establish hypotheses along the derivation of the structural characteristics of cardiomyocytes. Through the surface ion adsorption experiment and patch clamp experiment of living cells, under the condition of sequentially reducing the concentration of Na⁺ in the extracellular fluid, we observed the exchange and diffusion of adsorbed ions on the cell surface; the changes of inflow I_Na, I_Ca-L and action potential; and correlation between results. The results showed that the hypothesis is true. The observed parameter changes were consistent with the fact that during depolarization of cardiomyocytes, the ions of influx were derived from the inference of adsorbed ions on the cell surface; at the same time, it also provided an objective and realistic explanation for the generation of electrocardiogram.

Hyposmotic challenge modulates function of L-type calcium channel in rat ventricular myocytes through protein kinase C

AIM

To study the effects and mechanisms by which hyposmotic challenge modulate function of L-type calcium current (I(Ca,L)) in rat ventricular myocytes.

METHODS

The whole-cell patch-clamp techniques were used to record I(Ca,L) in rat ventricular myocytes.

RESULTS

Hyposmotic challenge(∼220 mosmol/L) induced biphasic changes of I(Ca,L), a transient increase followed by a sustained decrease. I(Ca,L) increased by 19.1%±6.1% after short exposure (within 3 min) to hyposmotic solution. On the contrary, long hyposmotic challenge (10 min) decreased I(Ca,L) to 78.1%±11.0% of control, caused the inactivation of I(Ca,L), and shifted the steady-state inactivation curve of I(Ca,L) to the right. The decreased I(Ca,L) induced by hyposmotic swelling was reversed by isoproterenol or protein kinase A (PKA) activator foskolin. Hyposmotic swelling also reduced the stimulated I(Ca,L) by isoproterenol or foskolin. PKA inhibitor H-89 abolished swelling-induced transient increase of I(Ca,L), but did not affect the swelling-induced sustained decrease of I(Ca,L). NO donor SNAP and protein kinase G (PKG) inhibitor Rp-8-Br-PET-cGMPS did not interfere with swelling-induced biphasic changes of I(Ca,L). Protein kinase C (PKC) activator PMA decreased I(Ca,L) and hyposmotic solution with PMA reverted the decreased I(Ca,L) by PMA. PKC inhibitor BIM prevented the swelling-induced biphasic changes of I(Ca,L).

CONCLUSION

Hyposmotic challenge induced biphasic changes of I(Ca,L), a transient increase followed by a sustained decrease, in rat ventricular myocytes through PKC pathway, but not PKG pathway. PKA system could be responsible for the transient increase of I(Ca,L) during short exposure to hyposmotic solution.

The reactivity of serotonin, acetylcholine and kcl-induced contractions to relaxant agents in the rat gastric fundus

The effects of nifedipine, cromakalim, diazoxide, caffeine and sodium nitroprusside (SNP) on acetylcholine, serotonin and KCl-induced contractions were studied in rat stomach fundus. Thus, we aimed to demonstrate how these contractions are modified by the substances acting on Ca (2+)influx and intracellular Ca (2+)stores. Serotonin (10(-9) - 10(-5) M) and KCl (20-80 mM) showed a similar contraction profile, which was slightly different from that of acetylcholine (10(-8)- 3 x 10(-3) M). In the experiments with the incubation of calcium-free/EGTA (0.5 mM) Krebs solution for 20 min, serotonin (3 x 10(-7)M) and KCl (40 mM) did not produce any contraction whereas, 10% of contraction to acetylcholine (3 x 10(-5) M) was still intact. Serotonin-induced contractions were readily reversed by nifedipine (10(-10) - 10(-4) M), cromakalim (10(-9) - 10(-4) M), diazoxide (10(-9) - 10(-4) M), caffeine (10(-5) - 10(-2) M) and SNP (10(-4) M) whereas, acetylcholine-induced contractions showed relative refractoriness to the above relaxant agents. 1 mM caffeine nearly fully inhibited serotonin-induced contraction, but not acetylcholine and high K-induced contractions whereas, 10 mM caffeine completely inhibited all the contractions. The relaxation pattern of nifedipine on serotonin and high K (+)-induced contractions was quite similar. Moreover, nifedipine and cromakalim showed equal dose effectiveness in relaxing acetylcholine and serotonin. The maximum relaxations induced by nifedipine and cromakalim in acetylcholine contractions were 61.51 +/- 6.92 % and 58.97 +/- 7.55 %, respectively. However their maximum relaxations in serotonin and high K (+)-induced contractions were almost 100%. The similarity in myorelaxants properties of cromakalim and nifedipine may relate to the similarity of their effects on calcium influx by a different mechanism of action in rat stomach fundus. In conclusion, acetylcholine-induced contraction is partially mediated both by calcium release from the intracellular Ca (2+) pool and calcium influx via L-type Ca (2+) channels. However, serotonin-induced contraction is possibly triggered by Ca (2+) release from sarcoplasmic reticulum and basically mediated by Ca (2+) influx via L-type Ca (2+)channels.

Impaired beta-adrenergic hyperpolarization in arteries from prehypertensive spontaneously hypertensive rats

Stimulation of beta-adrenoceptors leads to vascular smooth muscle hyperpolarization, presumably through the beta-adrenoceptors/Gs protein/adenylate cyclase/ATP-sensitive K(+)-channels (KATP) signaling cascade, which may play an important role in the sympathetic control of membrane potential. beta-Adrenoceptor-mediated hyperpolarization has been shown to be impaired in the established stage of experimental hypertension. The present study tested the hypothesis that beta-adrenergic hyperpolarization may be defective before the development of hypertension in some forms of genetic hypertension. We evaluated beta-adrenoceptor-mediated hyperpolarization using microelectrodes in mesenteric resistance arteries from 5-week-old, prehypertensive, spontaneously hypertensive rats (SHR) and age-matched Wistar-Kyoto rats (WKY). Isoproterenol-induced hyperpolarization was significantly smaller in SHR than in WKY (10(-7) mol/L: -4.6+/-0.6 versus -7.8+/-0.8 mV, P<0.01; 10(-6) mol/L -7.8+/-0.5 versus -9.8+/-0.6 mV, P<0.05; n=9). Furthermore, hyperpolarization to cholera toxin, a direct activator of Gs protein, was also impaired in SHR. On the other hand, hyperpolarization to forskolin, an adenylate cyclase activator, and to levcromakalim, a KATP opener, was comparable between groups. These findings suggest that beta-adrenoceptor-mediated hyperpolarization is defective in SHR before the development of hypertension, presumably because of an abnormality at the Gs protein site. Considering the importance of membrane potential in the control of vascular tone, altered beta-adrenergic control of membrane potential might play a role in the development of hypertension in SHR.

Potassium channels in gastrointestinal smooth muscle

1. Electromechanical coupling in smooth muscle serves to coordinate the contractile activity of the syncytium. Electrical activity of smooth muscle of the gut is generated by ionic conductances that regulate and in turn are regulated by the membrane potential of smooth muscle cells. This activity determines the extent of Ca2+ entry into smooth muscle cells, and thus, the timing and intensity of contractions. 2. Potassium channels play an important role in regulating the excitability of the syncytium. The different types of K+ channel are characterized by different sensitivities to membrane potential, to intracellular Ca2+ levels and to modulation by agonists. 3. This review highlights the different types of K+ channels found in gut smooth muscle and describes their possible roles in regulating the electrical activity of the muscle.

Impaired isoproterenol-induced hyperpolarization in isolated mesenteric arteries of aged rats

Stimulation of vascular beta-adrenoceptors leads to membrane hyperpolarization, presumably via the beta-adrenoceptor/G(s) protein/adenylate cyclase signaling cascade; the ionic mechanisms of this phenomenon remain unclear. beta-Adrenoceptor-mediated vascular relaxation is impaired with aging; however, little is known concerning whether beta-adrenoceptor-mediated hyperpolarization is altered with aging. We sought to determine the ionic mechanisms of isoproterenol-induced hyperpolarization in the rat mesenteric resistance artery, as well as the age-related changes in isoproterenol-induced hyperpolarization and their underlying mechanisms. Isoproterenol-induced hyperpolarization was inhibited by high-K(+) solution and glibenclamide (10(-6) mol/L), an inhibitor of ATP-sensitive K(+) channels (K(ATP)), but not by apamin, iberiotoxin, or charybdotoxin, inhibitors of Ca(2+)-activated K(+) channels. Isoproterenol-induced hyperpolarization was markedly less in aged rats (>/=24 months) than in adults rats (12 to 20 weeks) (3x10(-6) mol/L; -3.1 versus -9.9 mV; P<0.001; n=8 to 9). Cholera toxin (10(-9) g/mL), an activator of G(s), evoked hyperpolarization only in adult rats. Hyperpolarization to forskolin, a direct activator of adenylate cyclase, was also reduced to some extent in aged rats (10(-5) mol/L; -8.8 versus -13 mV; P<0.05; n=6), whereas hyperpolarization to levcromakalim, a K(ATP) opener, was comparable in both groups. These findings suggest that isoproterenol elicits hyperpolarization via an opening of K(ATP) in the rat resistance artery and that isoproterenol-induced hyperpolarization is attenuated in aged rats mainly because of a defective coupling of beta-adrenoceptors to adenylate cyclase and partly because of a defect at the level of adenylate cyclase, but not because of an alteration of K(ATP) per se.

Inflammatory modulation of calcium-activated potassium channels in canine colonic circular smooth muscle cells

BACKGROUND & AIMS

The characteristics of colonic circular smooth muscle slow waves are altered during inflammation. The aim of this study was to examine whether inflammation modulates the open-state probability of Ca2+-activated K+ (KCa) channels in these cells to contribute to these alterations.

METHODS

The experiments were performed on freshly dissociated single smooth muscle cells from the canine colon using standard patch clamp methods. Inflammation was induced by mucosal exposure to ethanol and acetic acid.

RESULTS

Inflammation decreased the open-state probability of large-conductance KCa (BK) channels in the cell-attached and excised inside-out configurations. The voltage sensitivity of the channels was also reduced during inflammation. Inflammation had no significant effect on the large, medium, and small conductances or the unitary current levels of channel openings. However, it decreased the maximum number of simultaneous channel openings. The channels were Ca2+-dependent and were blocked by tetraethylammonium and charybdotoxin in normal and inflamed cells.

CONCLUSIONS

Inflammation decreases the open-state probability of BK channels. This may partially reverse the decrease in duration and amplitude of slow waves and depolarization of membrane potential seen in inflammation.

Ionic conductances in gastrointestinal smooth muscles and interstitial cells of Cajal

Ion channels are the unitary elements that underlie electrical activity of gastrointestinal smooth muscle cells and of interstitial cells of Cajal. The result of ion channel activity in the gastrointestinal smooth muscle layers is a rhythmic change in membrane potential that in turn underlies events leading to organized motility patterns. Gastrointestinal smooth muscle cells and interstitial cells of Cajal express a wide variety of ion channels that are tightly regulated. This review summarizes 20 years of data obtained from patch-clamp studies on gastrointestinal smooth muscle cells and interstitial cells, with a focus on regulation.

Cellular and molecular basis for electrical rhythmicity in gastrointestinal muscles

Regulation of gastrointestinal (GI) motility is intimately coordinated with the modulation of ionic conductance expressed in GI smooth muscle and nonmuscle cells. Interstitial cells of Cajal (ICC) act as pacemaker cells and possess unique ionic conductances that trigger slow wave activity in these cells. The slow wave mechanism is an exclusive feature of ICC: Smooth muscle cells may lack the basic ionic mechanisms necessary to generate or regenerate slow waves. The molecular identification of the components for these conductances provides the foundation for a complete understanding of the ionic basis for GI motility. In addition, this information will provide a basis for the identification or development of therapeutics that might act on these channels. It is much easier to study these conductances and develop blocking drugs in expression systems than in native GI muscle cells. This review focuses on the relationship between ionic currents in native GI smooth muscle cells and ICC and their molecular counterparts.

Voltage sensitivity of slow wave frequency in isolated circular muscle strips from guinea pig gastric antrum

In circular muscle preparations isolated from the guinea pig gastric antrum, regular spontaneous electrical activity (slow waves) was recorded. Under normal conditions (6 mM K+), the frequency and shape of the slow waves were similar to those observed in ordinary stomach smooth muscle preparations. When the resting membrane potential was hyperpolarized and depolarized by changing the extracellular K+ concentration (2-18 mM), the frequency of slow waves decreased and increased, respectively. Application of cromakalim hyperpolarized the cell membrane and reduced the frequency of slow waves in a dose-dependent manner. Cromakalim (3 microM) hyperpolarized the membrane, and slow waves ceased in most preparations. In the presence of cromakalim, subsequent increases in the extracellular K+ concentration restored the frequency of slow waves accompanied by depolarization. Also, glibenclamide completely antagonized this effect of cromakalim. In smooth muscle strips containing both circular and longitudinal muscle layers, such changes in the slow wave frequency were not observed. It was concluded that the maneuver of isolating circular smooth muscle altered the voltage dependence of the slow wave frequency.

ATP-inhibited K+ channels and membrane potential of identified leech neurons

The effect of the ATP-inhibited K+ channel on the membrane potential of leech Retzius neurons was analyzed using electrolyte-filled single-barrelled microelectrodes. The membrane potential was independent of the external nutrient supply during a period of 11 h, probably because the internal energy reserves were sufficient. The K+ channel activator HOE 234 ((3S,4R)-3-hydroxy-2, 2-dimethyl-4-(2-oxo-1-pyrrolidinyl)-6-phenylsulfonylchromane hemihydrate, 500 microM) induced a membrane hyperpolarization. In the presence of HOE 234, action potentials occurred with a reduced after-hyperpolarization and were discharged in bursts, possibly because of an inhibition of Ca2+ channels. The blocker of ATP-inhibited K+ channels tolbutamide did not significantly alter the membrane potential. In the absence of tolbutamide, the metabolic inhibitors iodoacetate, azide and cyanide (10 mM) evoked membrane hyperpolarizations, but in the presence of 1 mM tolbutamide their hyperpolarizing actions were reduced or abolished while membrane depolarizations were intensified. We conclude that ATP-inhibited K+ channels in the soma membrane of leech Retzius neurons provide coupling of cellular metabolism to electrical activity and ionic fluxes.

Physiological features of visceral smooth muscle cells, with special reference to receptors and ion channels

Visceral smooth muscle cells (VSMC) play an essential role, through changes in their contraction-relaxation cycle, in the maintenance of homeostasis in biological systems. The features of these cells differ markedly by tissue and by species; moreover, there are often regional differences within a given tissue. The biophysical features used to investigate ion channels in VSMC have progressed from the original extracellular recording methods (large electrode, single or double sucrose gap methods), to the intracellular (microelectrode) recording method, and then to methods for recording from membrane fractions (patch-clamp, including cell-attached patch-clamp, methods). Remarkable advances are now being made thanks to the application of these more modern biophysical procedures and to the development of techniques in molecular biology. Even so, we still have much to learn about the physiological features of these channels and about their contribution to the activity of both cell and tissue. In this review, we take a detailed look at ion channels in VSMC and at receptor-operated ion channels in particular; we look at their interaction with the contraction-relaxation cycle in individual VSMC and especially at the way in which their activity is related to Ca2+ movements and Ca2+ homeostasis in the cell. In sections II and III, we discuss research findings mainly derived from the use of the microelectrode, although we also introduce work done using the patch-clamp procedure. These sections cover work on the electrical activity of VSMC membranes (sect. II) and on neuromuscular transmission (sect. III). In sections IV and V, we discuss work done, using the patch-clamp procedure, on individual ion channels (Na+, Ca2+, K+, and Cl-; sect. IV) and on various types of receptor-operated ion channels (with or without coupled GTP-binding proteins and voltage dependent and independent; sect. V). In sect. VI, we look at work done on the role of Ca2+ in VSMC using the patch-clamp procedure, biochemical procedures, measurements of Ca2+ transients, and Ca2+ sensitivity of contractile proteins of VSMC. We discuss the way in which Ca2+ mobilization occurs after membrane activation (Ca2+ influx and efflux through the surface membrane, Ca2+ release from and uptake into the sarcoplasmic reticulum, and dynamic changes in Ca2+ within the cytosol). In this article, we make only limited reference to vascular smooth muscle research, since we reviewed the features of ion channels in vascular tissues only recently.

The effects of nifedipine and other calcium antagonists on the glibenclamide-sensitive K+ currents in smooth muscle cells from pig urethra

1. The effects of nifedipine on both levcromakalim-induced membrane currents and unitary currents in pig proximal urethra were investigated by use of patch-clamp techniques (conventional whole-cell configuration and cell-attached patches). 2. Nifedipine had a voltage-dependent inhibitory effect on voltage-dependent Ba2+ currents at - 50 mV (Ki=30.6 nM). 3. In current-clamp mode, subsequent application of higher concentrations of nifedipine (> or =30 microM) caused a significant depolarization even after the membrane potential had been hyperpolarized to approximately -82 mV by application of 100 microM levcromakalim. 4. The 100 microM levcromakalim-induced inward current (symmetrical 140 mM K+ conditions, -50 mV) was inhibited by additional application of three different types of Ca antagonists (nifedipine, verapamil and diltiazem, all at 100 microM). In contrast, Bay K 8644 (1 microM) possessed no activating effect on the amplitude of this glibenclamide-sensitive current. 5. When 100 microM nifedipine was included in the pipette solution during conventional whole-cell recording at -50 mV, application of levcromakalim (100 microM) caused a significant inward membrane current which was suppressed by 5 microM glibenclamide. On the other hand, inclusion of 5 microM glibenclamide in the pipette solution prevented levcromakalim from inducing an inward membrane current. 6. The levcromakalim-induced K+ channel openings in cell-attached configuration were suppressed by subsequent application of 5 microM glibenclamide but not of 100 microM nifedipine. 7. These results suggest that in pig proximal urethra, nifedipine inhibits the glibenclamide-sensitive 43 pS K+ channel activity mainly through extracellular blocking actions on the K+ channel itself.

Regional hemodynamic dose-response of lemakalim and glybenclamide in anesthetized rats

Studies were undertaken to establish the regional hemodynamic profile and dose-response relation of the adenosine triphosphate (ATP)-dependent potassium channel activator lemakalim in anesthetized rats. In addition, the ability of the sulphonylurea potassium channel blocker glybenclamide to reverse the hemodynamic effects of an infusion of lemakalim was determined. Studies were performed in anesthetized rats instrumented to measure arterial pressure, heart rate, and hemodynamics in the coronary, mesenteric, renal, and hindquarters vascular beds. One group of rats (n = 5) received increasing intravenous infusion rates of the potassium channel activator lemakalim. The doses administered were 0.1, 0.3, 1.0, 3.0, and 10 micrograms/kg/min, and each dose was infused until steady-stateresponses were achieved. Dose-related decreases in mean arterial pressure were observed with the first significant effect occurring at 1 microgram/kg/min. The hindquarters bed was the most sensitive of the four beds measured. Vascular resistance was significantly decreased in this bed with an infusion of 0.3 microgram/kg/min i.v. lemakalim. In addition, this vascular bed was the only one to demonstrate significant increases in blood flow over baseline. Significant reductions in vascular resistance were observed over the dose range of 1-10 micrograms/kg/min for both the coronary and renal vascular beds. The mesenteric bed was less sensitive in that the first significant reduction in resistance was not observed until the infusion dose was increased to 3 micrograms/kg/min. The other group of rats (n = 5) was used to determine the dose-response relation of glybenclamide. These rats received an intravenous infusion of lemakalim at 1 microgram/kg/min to establish a moderate cardiovascular effect. Ascending cumulative intravenous injections of glybenclamide from 0.3 to 30 mg/kg were then administered. The lowest dose, 0.3 mg/kg, significantly attenuated the depressor response to the lemakalim infusion, but the response was not fully reversed until the dose of glybenclamide reached 10 mg/kg i.v.. Doses > 10 mg/kg i.v. of glybenclamide were required for complete reversal of the hemodynamic responses to this dose of lemakalim. Therefore lemakalim exerts vasodilatory properties in each of the beds measured but demonstrates a selectivity for the hindquarters. The results with glybenclamide demonstrate also that the responses to lemakalim are the result of activation of the ATP-dependent potassium channel. Last, doses > 10 mg/kg of glybenclamide are required to ensure that ATP-dependent potassium channels are blocked in the circulatory system in rats.

Glucose modulates rat substantia nigra GABA release in vivo via ATP-sensitive potassium channels

Glucose modulates beta cell insulin secretion via effects on ATP-sensitive potassium (KATP) channels. To test the hypothesis that glucose exerts a similar effect on neuronal function, local glucose availability was varied in awake rats using microdialysis in the substantia nigra, the brain region with the highest density of KATP channels. 10 mM glucose perfusion increased GABA release by 111 +/- 42%, whereas the sulfonylurea, glipizide, increased GABA release by 84 +/- 20%. In contrast, perfusion of the KATP channel activator, lemakalim, or depletion of ATP by perfusion of 2-deoxyglucose with oligomycin inhibited GABA release by 44 +/- 8 and 45 +/- 11%, respectively. Moreover, the inhibition of GABA release by 2-deoxyglucose and oligomycin was blocked by glipizide. During systemic insulin-induced hypoglycemia (1.8 +/- 0.3 mM), nigral dialysate GABA concentrations decreased by 49 +/- 4% whereas levels of dopamine in striatal dialysates increased by 119 +/- 18%. We conclude that both local and systemic glucose availability influences nigral GABA release via an effect on KATP channels and that inhibition of GABA release may in part mediate the hyperexcitability associated with hypoglycemia. These data support the hypothesis that glucose acts as a signaling molecule, and not simply as an energy-yielding fuel, for neurons.

Functional evidence for a glibenclamide-sensitive K+ channel in rat ileal smooth muscle

The motor activity of gastrointestinal smooth muscle is closely related to the membrane potential. Controlling the membrane potential via modulation of K+ channels is essential for the action of neurotransmitters on smooth muscle. In the present study the effect of the K+ channel activator, lemakalim, on longitudinal smooth muscle of the rat ileum was investigated. Segments of rat ileum were stimulated by the muscarinic receptor agonist, carbachol (10(-6) M). Lemakalim (10(-10) to 3 x 10(-5) M) induced a dose-dependent inhibition of the carbachol-induced contraction. This inhibitory effect of lemakalim was not modified by neural blockade with tetrodotoxin (10(-6) M, n = 9). Glibenclamide (10(-7) to 10(-5) M), a specific blocker of ATP-dependent K+ channels antagonized dose dependently the relaxant effect of lemakalim (IC50: 3.4 x 10(-6) M, n = 11, P < 0.001). In contrast, apamin (10(-7) M, n = 9, n.s.) and charybdotoxin (10(-7) M, n = 9, n.s.), specific blockers of Ca2+-dependent K+ channels and the non-specific K+ channel blocker, tetraethylammonium (10(-4) to 10(-1) M), had no influence on the inhibitory effect of lemakalim. Contractions induced by the Ca2+ channel activator, Bay-K-8644, were completely inhibited by lemakalim (10(-5) M, n = 12). This inhibitory effect was also selectively antagonized by glibenclamide (10(-5) M). Potential non-adrenergic non-cholinergic (NANC) inhibitory mediators like ATP, nitric oxide (NO) or neurotensin showed no sensitivity to glibenclamide. These functional data indicate that the relaxant effect of lemakalim is due to a specific activation of glibenclamide-sensitive K+ channels, which in turn can modulate the activity of dihydropyridine-sensitive (voltage-dependent) Ca2+ channels. A physiological or pathophysiological role of the glibenclamide-sensitive K+ channels in intestinal smooth muscle is discussed; however, they seem not to be involved in the effect of the NANC inhibitory mediators tested.

Mechanism of action of a K+ channel activator BRL 38227 on ATP-sensitive K+ channels in mouse skeletal muscle fibres

1. Investigations were made into the effects of BRL 38227, a potassium channel activator, on ATP-sensitive potassium channels (K+ATP channels) in single fibres dissociated from the flexor digitorum brevis muscle of C57BL/6J mice. 2. In cell-attached patches BRL 38227 (100 microM) caused activation of a glibenclamide-sensitive potassium current. Linear slope conductance of the inward current, partial rectification of the outward current and glibenclamide sensitivity indicate that K+ATP channels are the site of action of BRL 38227. 3. In the absence of ATP at the cytoplasmic side of excised inside-out patches, BRL 38227 caused direct and magnesium-dependent activation of K+ATP channels. The degree of activation diminished with successive applications of BRL 38227. 4. BRL 38227 also caused activation of K+ATP channels in the presence of low (< 100 microM) but not high (1.0 mM) ATP, particularly in patches containing large numbers of channels. 5. BRL 38227 and 5 microM MgATP failed to activate channels following complete run-down. 6. Results show that BRL 38227 caused direct activation of K+ATP in skeletal muscle and that this was mediated through a magnesium-dependent binding site rather than alleviation of inhibition by competitive displacement of ATP from the inhibitory site.

Effects of cromakalim or pinacidil on pacing- and ischemia-induced ventricular fibrillation in the anesthetized pig

The effects of the potassium channel openers (KCO), cromakalim or pinacidil, were evaluated in an anesthetized porcine model of pacing- and ischemia-induced ventricular fibrillation (VF). Hearts were paced at 180 bpm and the left anterior descending coronary artery was occluded until VF was induced. Reproducible times to VF (in seconds) were obtained allowing at least 20 min recovery following defibrillation. Cromakalim (0.3 mg/kg) or pinacidil (3 mg/kg) produced equivalent drops in mean arterial blood pressure. At these doses, cromakalim reduced monophasic action potential duration measured at 90% repolarization (APD90). Although time to VF in the cromakalim group was significantly greater than the vehicle treated group, it was not significantly different from its predrug value. In contrast, pinacidil reduced APD90, and significantly increased time to VF from 134 +/- 5 to 322 +/- 62 s (p < 0.05). Neither cromakalim nor pinacidil affected whole-cell calcium currents recorded in guinea pig myocytes. During ischemia, cromakalim or pinacidil further reduced APD90; however, pinacidil had a two-fold greater effect than did cromakalim. The Class III antiarrhythmic agent, dofetilide, prolonged APD90, but did not increase time to VF. In conclusion, the increased time to VF observed with pinacidil coincides with its ability to shorten APD, and is consistent with activation of ATP-sensitive K+ channels (K+ ATP). It is suggested that indirect reduction of calcium influx through K+ ATP activation and APD shortening is sufficient to increase time to VF in this model. However, the inability of dofetilide to be effective suggests that this model would not be useful to test for Class III antiarrhythmic agents.

Effects of K+ channel openers on the vascular actions of human gamma globulin

The aim of this study was to determine if the stimulatory action of human gamma globulin on the spontaneous activity of the rat mesenteric portal vein is due to decreased K+ conductance. Glibenclamide potentiated the action of human gamma-globulin on the portal vein by 45% and on its own had a concentration- and time-dependent biphasic (increase followed by a decrease) effect on the spontaneous activity of the portal vein. Diazoxide and pinacidil both inhibited the action of human gamma-globulin on the rat mesenteric portal vein. Levcromakalim (BRL 38227) potentiated the stimulatory action of human gamma-globulin on the integrated force of the spontaneous contractions of the rat mesenteric portal vein by 40% and 49% at concentrations of 0.5 and 5 microM, respectively. These studies suggest that human gamma-globulin can act by directly modulating a K+ channel.

Cloning and expression of a Kv1.2 class delayed rectifier K+ channel from canine colonic smooth muscle

A cDNA (CSMK1) encoding a delayed rectifier K+ channel of the Kv1.2 class was cloned from canine colonic circular smooth muscle and expressed in Xenopus oocytes. These channels appear to be uniquely expressed in gastrointestinal muscles and may participate in the electrical slow wave activity. Functional expression of CSMK1 in Xenopus oocytes demonstrated a K+ current that activated in a voltage-dependent manner upon depolarization. This current was highly sensitive to 4-aminopyridine (IC50, 74 microM). A low-conductance K+ channel was identified in inside-out patches from oocytes injected with CSMK1. This channel displayed a linear current-voltage relation with a slope conductance of 14 pS. The channels were blocked in a concentration-dependent manner by 4-aminopyridine. Northern blot analysis demonstrated that CSMK1 is expressed in a wide variety of gastrointestinal smooth muscles. Portal vein, renal artery, and uterus do not express CSMK1, suggesting that, among smooth muscles, expression of this K+ channel may be restricted to gastrointestinal smooth muscles. CSMK1 is 91% homologous to RAK, a delayed rectifier K+ channel cloned from rat heart, but displays unique pharmacological properties and tissue distribution.

K channel openers activate different K channels in vascular smooth muscle cells

The properties of K channels activated by K channel openers (nicorandil, cromakalim, pinacidil, etc.) were investigated using conventional microelectrode and patch-clamp methods. In single smooth muscle cells of the rat and rabbit portal veins, K channel openers produced an outward current sensitive to glibenclamide, 4-AP, and TEA (1 mM), but insensitive to apamin and charybdotoxin. Glibenclamide-sensitive K channels in both tissues had a small unitary conductance (10 pS and 15 pS) and were inhibited by intracellular ATP. The activity of the 15 pS channel in the rabbit portal vein was not changed by an increase in the intracellular free Ca concentration, but the activity of the 10 pS channel in the rat portal vein was markedly modified by Ca concentration. These results coincided with previous observations using a conventional microelectrode and whole-cell voltage-clamp experiments. In the inside-out membrane patch, the 10 pS channel in the rat portal vein was activated by the application of K channel openers, while the 15 pS channel in the rabbit portal vein was rapidly inactivated, even in the presence of K channel openers. GDP, but neither GTP gamma S nor GDP beta S, reopened the 15 pS channel in the presence of K channel openers. These results suggested that the 15 pS channel had two channel states, that is, both operative and inoperative states, while the 10 pS channel did not have an inoperative state. The K channel openers open the ATP-sensitive K channel only at the operative state.(ABSTRACT TRUNCATED AT 250 WORDS)

Effects of cromakalim on the electrical slow wave in the circular muscle of guinea-pig gastric antrum

1. In circular muscle strips of the antrum of guinea-pig stomach, the effects of cromakalim were studied on mechanical activity and intracellular membrane potential. 2. Cromakalim inhibited mechanical activity at concentrations higher than 1 microM, accompanied by membrane hyperpolarization and a decrease in membrane resistance. The hyperpolarization was markedly potentiated in K(+)-free solution and was still observed in the absence of Na+. 3. Slow wave electrical activity was relatively resistant to cromakalim. Changes in its amplitude and frequency were not consistent but blockade of slow waves was never observed. In many preparations cromakalim induced spike-like potentials at the top of slow waves, or when spike-like potentials already existed they were potentiated. However, mechanical activity was always inhibited. 4. Inhibition by cromakalim of the phasic contractions associated with the slow waves, could not be reversed by increasing the external K+ concentration (12-30 mM). 5. The results suggest that in guinea-pig stomach muscle mechanical suppression by cromakalim does not simply result from membrane hyperpolarization or from inhibition of slow waves. A clear dissociation was found between the mechanical and electrical activities. Slow waves, particularly their frequency, are relatively insensitive to membrane hyperpolarization.

Potassium channel modulation in rat portal vein by ATP depletion: a comparison with the effects of levcromakalim (BRL 38227)

1. The effects of levcromakalim and of adenosine 5'-triphosphate (ATP) depletion on membrane potential and ionic currents were studied in freshly-dispersed smooth muscle cells of rat portal vein by use of combined voltage- and current-clamp techniques. 2. Levcromakalim (1 microM) induced a glibenclamide-sensitive, non-inactivating K-current (IKCO) and simultaneously inhibited the slow, transient outward, delayed rectifier K-current (ITO). Levcromakalim also hyperpolarized the portal vein cells by approximately 20 mV. 3. Reduction of intracellular ATP by removal of glucose and carboxylic acids from the recording pipette and of glucose from the bath fluid, induced a slowly-developing, non-inactivating and glibenclamide-sensitive K-current (Imet) within 60-300 s after breaking the membrane patch. Imet reached peak amplitude after 300-900 s, remained at a plateau for 200-800 s and then slowly ran down. At the peak of Imet, the cells were hyperpolarized by approximately 20 mV and their input conductance was increased by 42%. 4. At the time of maximum development of Imet, the delayed rectifier current, ITO, was reduced by 48%. 5. In the absence of glucose and carboxylic acids, addition of 1 microM free ATP to the recording pipette almost doubled the magnitude of Imet. At a holding potential of -10 mV, Imet was increased from 124 +/- 11 pA to 228 +/- 54 pA whereas the time-course of development and run-down of Imet was unaffected. 6. During the development and after the run-down of Imet, levcromakalim (1-10 microM) failed to induce IKCO. 7. Stationary fluctuation analysis of the current noise associated with Imet revealed a unitary conductance of between 10-20 pS in a physiological potassium gradient. A second contaminating current with an underlying unitary conductance of approximately 150 pS remained after Imet had run down. 8. It is concluded that IKCO induced by levcromakalim and Imet are carried by the same population of relatively small conductance, glibenclamide-sensitive K-channels. The open state of these is increased by procedures designed to lower intracellular ATP concentrations. 9. The simultaneous inhibition of the delayed rectifier current (ITO) by both levcromakalim and during the development of Imet is highly significant. It suggests that levcromakalim could modify the interaction of ATP with sites linked to more than one type of K-channel. This results in the opening of those channels which underlie IKCO (and which are normally inhibited by ATP binding) together with the modulation of phosphorylation-dependent channels such as those which underlie ITO.

On the pharmacological and physiological role of glibenclamide-sensitive potassium channels in colonic smooth muscle

Actions of activators of glibenclamide sensitive K+ channels on canine colonic circular muscle were investigated. Cromakalim as well as its (-) enantiomer lemakalim caused inhibition of spontaneous phasic contractile activity (EC50's 4.4 +/- 0.1 x 10(-7) M and 2.3 +/- 0.4 x 10(-7) M, respectively) and of carbachol induced activity (EC50's: 9.4 +/- 5.1 x 10(-7) M and 4.3 +/- 1.4 x 10(-7) M, respectively). Cromakalim and lemakalim effects were completely inhibited by glibenclamide. Additive effects between K+ channel activators and other drugs relaxing colonic muscle (the L-type calcium channel blocker D600 and forskolin) were seen. A physiological role for specific glibenclamide sensitive K+ channels, if existing, remains unresolved. The present study indicates that the non-adrenergic inhibitory nerves do not act through these channels, neither does stimulation of muscarinic or beta-adrenergic receptors.

Cromakalim does not act as a calcium antagonist in isolated human mesenteric artery cells

The effects of cromakalim and its active enantiomer BRL 38226 on voltage-gated Ca2+ channels in smooth muscle cells isolated from human mesenteric arteries were studied using the whole cell patch-clamp technique. Neither of these drugs affected the Ca2+ channel current in these cells. These results suggest that the efficacy of cromakalim in lowering blood pressure in human beings does not involve a Ca2+ channel antagonistic effect.

Effects of cromakalim on the contraction and the membrane potential of the circular smooth muscle of guinea-pig stomach

1. The effects of cromakalim on mechanical and electrical activities of the circular smooth muscles of guinea-pig stomach antrum were observed. 2. Cromakalim (greater than 1 x 10(-7) M) decreased the amplitude of spontaneous rhythmic contractions and also the acetylcholine-enhanced spontaneous contractions. Cromakalim was less effective against the 25.9 mM and 35.9 mM K(+)-induced tonic contractions. 3. Glibenclamide (1 x 10(-6) M) itself caused no detectable change in the spontaneous contractions, those potentiated by acetylcholine or tonic contractions induced by high K+ solutions, but attenuated the actions of cromakalim. On the other hand, charybdotoxin (3 x 10(-8) M) increased the amplitude of spontaneous contractions but failed to affect the actions of cromakalim. 4. Cromakalim (greater than 1 x 10(-6) M) decreased the amplitude and duration of slow waves, and hyperpolarized the membrane. These actions of cromakalim were completely antagonized by 1 x 10(-6) M glibenclamide, whereas part of the effects of cromakalim on mechanical activity was resistant to glibenclamide. 5. The results suggest that the inhibition by cromakalim of the electrical activity and the hyperpolarization, which may be associated with the opening of glibenclamide-sensitive K+ channel, are responsible for its inhibitory action on circular smooth muscle of guinea-pig stomach. Further, some effects independent of glibenclamide-sensitive K+ channel may also be responsible for the mechanical effect.

Cromakalim and lemakalim activate Ca(2+)-dependent K+ channels in canine colon

The effects of cromakalim (BRL 34915) and its (-) optical isomer, lemakalim (BRL 38227) on the activity of 265-pS Ca(2+)-activated K+ channels (BK channels) were examined in cell-attached and inside-out patches from canine colonic myocytes. In cell-attached patches lemakalim increased the open probability (Po) of BK channels. Mean NPo, where N is the number of channels per patch, at +50 mV increased from 0.08 to 0.26 (20 microM lemakalim). In inside-out patches, cromakalim and lemakalim increased channel NPo rapidly and reversibly. This increase in NPo was due to a shift in half-maximal activation. Glyburide (20 microM) prevented the increase in NPo caused by lemakalim in cell-attached patches and reversed the increase in NPo in inside-out patches. Under conditions where Ca(2+)-activated K+ channels were maximally activated, lemakalim failed to increase current or induce a second type of K+ channel activity. When tetraethylammonium (200 microM) was added to the pipette solution to block the BK channel half maximally, lemakalim also failed to induce a second type of channel. Adenosine triphosphate (1 or 2 mM) applied to the inner surface of inside-out patches had no effect on Po of BK channels. Finally, the effects of lemakalim on ensemble average currents, constructed from multiple openings of BK channels in cell-attached patches was found to successfully mimic the effects of the drug on whole-cell membrane currents. We conclude that cromakalim and lemakalim activate BK channels in canine colonic cells. Whether this action participates in the membrane hyperpolarization and the decrease in frequency and duration of slow waves produced by these compounds in intact colonic muscles remains to be investigated.

Effects of BRL 38227 on potassium currents in smooth muscle cells isolated from rabbit portal vein and human mesenteric artery

1. Single smooth muscle cells were isolated from the rabbit portal vein and the human mesenteric artery and whole cell currents recorded at room temperature from either cell type by the whole cell voltage clamp technique. 2. In the rabbit portal vein cells addition of 10 microM BRL 38227 induced a quasi-instantaneous, voltage-insensitive and time-independent current which had a reversal potential of -75 mV under experimental conditions where the calculated EK was -83 mV. 3. Cells were held at 0 mV and BRL 38227 was added cumulatively to construct a dose-response relationship. BRL 38227 (0.03-10 microM) caused a dose-dependent outward shift in the holding current with an EC50 of 1.3 microM. 4. BRL 38227 (10 microM) had no effect on the delayed rectifier K+ current measured in the presence of 5 mM tetraethylammonium and no effect on the Ca(2+)-activated K+ current measured in the presence of 5 mM 4-aminopyridine. Similarly BRL 38227 had no effect on the Ca2+ current. 5. The BRL 38227-induced current was blocked by glibenclamide (10 microM) and phentolamine (100 microM), specific blockers of the ATP-sensitive K+ current in single cells. 6. In human isolated mesenteric artery cells, BRL 38227 (10 microM) induced a glibenclamide-sensitive current similar to, but smaller than, that observed in the rabbit portal vein. 7. We conclude that in these cells, BRL 38227 activates a potassium conductance which has the electrophysiological and pharmacological characteristics of ATP-sensitive K+ channels.