Inhibitory effects of cicletanine on smooth muscle in comparison to those of nifedipine and sodium nitroprusside.

The inhibitory effect of cicletanine was studied, in comparison to the effects of nifedipine and sodium nitroprusside (SNP), in various types of smooth muscle: portal vein and iliac artery of rabbit; gastric fundus and antrum of rabbit and guinea pig; guinea pig taenia coli and uterus. In all types of tissue the nifedipine-sensitive component (LCA, L-type calcium channel dependent activation) was inhibited by cicletanine (threshold concentration 10(-6) mol/l to 10(-5) mol/l). The nifedipine to resistant component (NLCA) was in some tissues preferentially inhibited by SNP (gastric fundus) and in other tissues preferentially by cicletanine (portal vein), with graded intermediate forms (iliac artery). Consequently, the inhibitory effect of cicletanine on NLCA is different in mechanism to that of SNP. Only papaverine suppressed all types of activation.

Effects of cicletanine on whole-cell currents of single smooth muscle cells from the guinea-pig portal vein.

1. Smooth muscle cells of the guinea-pig portal vein were dispersed by enzymatic treatment and recordings of membrane currents were made in the whole-cell mode by the patch-clamp technique. The effects of extracellular application of cicletanine-hydrochloride on the whole-cell currents of isolated smooth muscle cells from the guinea-pig portal vein were studied in solutions containing a normal concentration of calcium (2.5 mM). 2. Cicletanine, 10 to 100 microM, reduced the voltage-dependent inward calcium current with an IC50 of 250 microM. These effects of cicletanine were reversible. 3. The action of cicletanine on calcium currents can be interpreted as a decrease of the availability of calcium channels but not by an alteration of the time course or voltage-dependency of inactivation. 4. The control calcium current was enhanced by application of Bay K 8644. On this enhanced inward current, cicletanine also exerted inhibitory effects which were not use-dependent. 5. Cicletanine, 1 to 100 microM, did not enhance outward potassium currents. 6. It is concluded that at least one component of the vasorelaxant effects of cicletanine is produced by inhibition of calcium currents.

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.

Characterization of potassium currents modulated by BRL 38227 in rat portal vein.

1. Smooth muscle cells of the rat portal vein were dispersed by enzymatic treatment and recordings of whole-cell membrane potassium currents were made by the voltage-clamp technique. In isolated cells by use of combined voltage- and current-clamp the effect of BRL 38227 on membrane potential and ionic currents was also studied. 2. BRL 38227 (0.1 to 10 microM) induced a non-inactivating potassium current (IKCO) which developed slowly (900 s to 300 s, respectively) to its full size. These effects of BRL 38227 were reversible. 3. In addition to its K-channel opening properties, BRL 38227 (1 to 10 microM) inhibited the amplitude and changed the activation and inactivation characteristics of a slowly-inactivating, calcium influx-independent, outward potassium current (I(TO)). 4. Application of stationary fluctuation analysis to IKCO, showed a mean single channel current of 0.65 pA at -10 mV under a quasi-physiological potassium gradient. 5. In a combined voltage-clamp/current-clamp configuration, BRL 38227 (1 microM) induced a mean hyperpolarization of 22 mV. 6. The induction of IKCO by BRL 38227 and the associated hyperpolarization were suppressed by glibenclamide (1 to 10 microM) in a concentration-dependent manner. Glibenclamide (1 microM) had no effect on the inhibition of I(TO) by BRL 38227 (1 microM).

Comparison of the relaxing effects of cicletanine and cromakalim on vascular smooth muscle.

Cicletanine inhibited the spontaneous activity of portal vein preparations (rat, guinea pig, and rabbit) and that produced by norepinephrine or an increase in external K+ concentration to 20 mmol/L in seven types of vascular smooth muscle preparation (portal vein of rat, guinea pig, and rabbit; aorta of rat and guinea pig; and iliac artery and ear artery of rabbit). The cicletanine EC50 was approximately 10(-4) mol/L. Contractions produced by K+ = 80 mmol/L were also inhibited by cicletanine in most preparations. Only in aortic strips of rat and guinea pig and in rabbit iliac artery were the concentration-response relationships for cicletanine shifted to the right, yielding EC50 values of approximately 3 x 10(-4) mol/L. In contrast, the inhibitory effects of the potassium channel opener cromakalim (BRL 34915) were completely abolished during K+ = 80 mmol/L treatment in all preparations. The inhibitory effect of cromakalim under the other test conditions (above) was completely antagonized by application of glibenclamide, 10(-5) mol/L, whereas this treatment had only negligible effects on cicletanine inhibition in most preparations. The results indicate that a potassium channel opening effect does not contribute significantly to the inhibitory effect of cicletanine on vascular smooth muscle.

The involvement of potassium channels in the action of ciclazindol in rat portal vein.

1. In whole portal veins, ciclazindol (0.3-10 microM) increased the amplitude and duration, but decreased the frequency of spontaneous contractions. Glibenclamide (0.3-10 microM) produced a small increase in contraction amplitude and duration with a small reduction in contraction frequency. 2. In whole portal veins, ciclazindol (1-10 microM) antagonized the relaxant effects of BRL 38227 in a non-competitive manner. Under identical conditions, the effects of glibenclamide (0.3-10 microM) appeared to be competitive. 3. In whole portal veins loaded with 42K, ciclazindol itself (up to 3 microM) had no detectable effect on basal 42K exchange. However, the increase in 42K efflux produced by BRL 38227 (5 microM) was antagonized by ciclazindol (3 microM). Similar effects were produced by glibenclamide (up to 3 microM). 4. In freshly-isolated portal vein cells examined by the whole-cell voltage-clamp technique, ciclazindol (1-100 microM) inhibited the slowly-activating and inactivating transient outward current (ITO) which could be generated at potentials more positive than -30 mV. In addition ciclazindol (1-10 microM) inhibited the non-inactivating K-current (IKCO) induced by BRL 38227 (10 microM). 5. In freshly-isolated portal vein cells under current-clamp conditions, the hyperpolarization produced by BRL 38227 (10 microM) was reversed by ciclazindol (1-10 microM). 6. In porcine brain membrane fragments, glibenclamide (0.65 nM) displaced 50% of the binding of [3H]-glibenclamide whereas ciclazindol (up to 10 microM) had no effect. 7. It is concluded that ciclazindol is a K-channel blocker. Its action is not selective for the channel(s) which carry IKCO but also extends to those which carry ITO.Its inability to displace [3H]-glibenclamide from porcine brain fragments may indicate that antagonism of BRL 38227 by ciclazindol in smooth muscle is exerted at a site different from that of glibenclamide.

Characterization of membrane currents in single smooth muscle cells from the guinea-pig gastric antrum.

1. Smooth muscle cells, enzymatically isolated from the antrum of the guinea-pig stomach, were voltage clamped at room temperature using the whole-cell patch clamp technique. In physiological salt solution (PSS), step depolarization from a holding potential of -90 mV elicited inward calcium current (ICa) followed and superimposed by outward potassium current. 2. Outward current was divided into components depending on the presence of extracellular Ca2+ and others which were not activated as a result of Ca2+ influx. Ca(2+)-dependent components were (1) a fast transient component most likely representing Ca(2+)-activated K+ current (IK(Ca)) immediately triggered by the initial peak of ICa and (2) spontaneous transient outward currents (STOCs) apparently reflecting synchronized opening of IK(Ca) channels by cyclic release of Ca2+ from intracellular stores. Ca2+ influx-independent outward current could be divided into two main components: (1) a transient component (I(to)) showing voltage-dependent activation and inactivation and (2) a non-inactivating component (Ini). 3. I(to) activated with a threshold around -30 mV, was fully available at -90 mV and completely inactivated at -10 mV. The time course of both activation and inactivation of I(to) at different potentials could be described by single exponential functions. Time constants of activation decreased from 35 ms at -10 mV to 10 ms at +40 mV. The time constant of inactivation was about 2 s and only weakly voltage dependent. Time constants for exponentially developing recovery from inactivation of I(to) ranged from 0.1 s at -100 mV to 10 s at -30 mV. I(to) was insensitive to 4-aminopyridine (4-AP, 5 mmol/l), slightly sensitive to tetraethylammonium (TEA, 10 mmol/l), but substantially inhibited by caffeine (10 mmol/l) and Cd2+ (5 mmol/l). Estimates of the single-channel conductance by current fluctuation analysis indicated a small value of about 2.5 pS. 4. The action of TEA on current elicited from a holding potential of -10 mV indicated a major contribution to Ini of a distinct component (Ini,K) that was completely blocked by this substance at a concentration of 10 mmol/l. Ini was almost unaffected by 4-AP (5 mmol/l) and caffeine (10 mmol/l), but strongly suppressed by Cd2+ (5 mmol/l). Current fluctuation analysis of Ini,K gave a value for the single-channel conductance of about 60 pS. 5. Ca2+ inward current was studied in PSS ([Ca2+]o = 2.5 mmol/l) using pipette solution in which K+ was replaced by Cs+ to suppress outward K+ currents.(ABSTRACT TRUNCATED AT 400 WORDS)

Suppression of steady membrane currents by acetylcholine in single smooth muscle cells of the guinea-pig gastric fundus.

1. Single smooth muscle cells from the fundus region of the guinea-pig stomach, which showed contractile responses to acetylcholine (ACh) at concentrations greater than or equal to 10(-7) mol/l, were obtained by enzymatic digestion using highly purified collagenase and papain. They were studied by recording membrane currents under voltage clamp with the patch pipette technique in the whole-cell configuration at 25-28 degrees C. 2. By applying voltage jumps from negative holding levels (-70 to -60 mV) to more positive levels, we identified two major activating currents: an initial inward Ca2+ current (ICa) was followed, and partly overlapped, by an outward K+ current (IK). 3. Cholinergic effects on membrane currents were investigated in the range of negative membrane potentials by determining current-voltage relations in the absence of ACh and during its continuous presence in the bathing fluid. 4. ACh induced a decrease in the steady-state conductance which was reversibly blocked by atropine. At physiological external K+ concentration [( K+]o = 6 mmol/l), the reversal potential (Erev) of the current suppressed by ACh (3 x 10(-6) mol/l) was about 20 mV more positive than the calculated K+ equilibrium potential (EK). 5. When [K+]o was increased, Erev was shifted positively; but at each [K+]o, Erev was more positive than EK. 6. Like ACh (10(-6) mol/l), tetraethylammonium (TEA, 1 mmol/l) also suppressed a current with a reversal potential that was, at physiological [K+]o, 20 mV more positive than EK. ACh (10(-5) mol/l) applied in the presence of 1 mmol/l TEA suppressed a pure K+ current (Erev = EK), which was also suppressed by 10 mmol/l TEA. 7. When K+ in the pipette and in the bathing solution was completely replaced by Na+, both ACh (10(-5) mol/l) and TEA (1 mmol/l) caused a reduction of the membrane conductance that appeared to be identical. TEA added to the bathing solution in the presence of ACh did not produce a significant additional conductance decrease. These results did not depend on whether Cl- was present as a charge carrier or not. 8. It is concluded that in fundus muscle of the guinea-pig stomach a major mechanism underlying muscarinic activation is a decrease of a K+ conductance. In addition the results indicate a suppression of a small Na+ conductance which is made up by a population of channels that are also blocked by TEA.

Features of a calcium independent, caffeine sensitive outward current in single smooth muscle cells from guinea pig protal vein.

Using the single electrode voltage-clamp technique, vascular smooth muscle cells from the guinea pig portal vein showed an initial inward (Ca2+) current followed by an outward current which peaked within 100 ms and then declined to a steady level in a few seconds. Caffeine (1 mmol/l) selectively blocked the transient component of the outward current (ITO) and allowed differentiation of the outward current into two components: ITO and a caffeine resistant background current. The potassium channel blockers TEA (10 mmol/l) and 4-AP (5 mmol/l) produced about 90% suppression of ITO. ITO was identified as a calcium independent potassium current. Analysis of the inactivation and recovery from inactivation of ITO revealed similarities to the A-current first described for molluscan neurones (11) and later for crista terminalis of rabbit heart (4). Being much slower than this current it also bears similarities in its inactivation kinetics to a transient outward current identified in rabbit portal vein (2, 6).