Chemical irritant algesia assessed using the human blister base.

The chemical irritants o-chlorobenzylidene malononitrile (CS), n-nonanoylvanillylamine (VAN) and dibenzoxazepine (CR) and several of its derivatives have been assayed using the human blister base. The relative potencies found by this method, CR greater than VAN greater than CS, conflicted with those found in non-human test systems but the rank order of potency of CS and CR reflected that reported in tests on the human eye and tongue. Data derived from humans thus appear to be of importance when assessing irritant potency. Interactions between CS, CR, VAN, capsaicin and bradykinin were investigated to discover any common pathways of irritant activity. Self-desensitization developed on repeated application of all agents to the blister base and selective cross-desensitization also occurred.

An uptake of radioactivity from (plus or minus)-3H-isoprenaline and its inhibition by drugs which potentiate the responses to (minus)-isoprenaline in the guinea-pig isolated trachea.

1. The uptake of radioactivity derived from (+/-)-(3)H-isoprenaline by the guinea-pig isolated trachea has been measured, and the assumption is made that all the radioactivity is due to isoprenaline.2. 40% of the total (+/-)-(3)H-isoprenaline taken up was loosely bound to the tissue while 25% was firmly bound.3. The firmly bound component of the uptake was more susceptible to inhibition by drugs than the loosely bound component.4. Desipramine and cocaine did not reduce the accumulation of firmly bound isoprenaline.5. Cooling to 23 degrees C, guanethidine and phentolamine caused a moderate reduction in the accumulation of firmly bound isoprenaline.6. Phenoxybenzamine and (+/-)-metanephrine caused a highly significant reduction in the accumulation of firmly bound isoprenaline.7. These findings are discussed in relation to previous studies of the uptake of isoprenaline and of other processes which may be related.8. The inhibition of uptake by the agents examined correlated with their potentiation of the action of (-)-isoprenaline found previously.9. It is suggested that a tissue uptake can significantly modify the pharmacological response to isoprenaline in vitro.

Some effects of nifedipine in guinea-pig isolated trachealis.

In trachealis depolarized by a K+-rich medium, nifedipine (0.001-1 mumol 1(-1) caused concentration-dependent antagonism of CaCl2-induced increase in tension, moving the CaCl2 log concentration-effect curve to the right and depressing the maximal response. In trachealis in normal Krebs solution, similar concentrations of nifedipine had marked antispasmogenic activity against the responses to potassium chloride (KCl) and tetraethylammonium (TEA). However, nifedipine had little, if any, antispasmogenic activity against the responses to acetylcholine or histamine. Nifedipine 1 mumol 1(-1) was tested for spasmolytic activity in tissues generating tension in response to the EC50 of acetylcholine, KCl or CaCl2. In producing spasmolysis nifedipine was most effective against CaCl2 and least effective against acetylcholine. Nifedipine (0.01-1 mumol-1) had little or no effect on the tone of trachealis in normal Krebs solution. Intracellular electrophysiological recording showed that nifedipine 1 mumol 1(-1) could abolish spontaneous slow wave activity. This was associated with very minor depolarization and little or no loss of mechanical tone. In tissues treated with TEA (8 mmol 1(-1) nifedipine abolished spike and slow wave discharge and reduced mechanical activity to the pre-TEA level. It is concluded that nifedipine prevents KCl- or TEA-induced spasm by inhibition of Ca2+ influx. Spasm evoked by acetylcholine or histamine and the maintenance of spontaneous tone depend largely on mechanisms for increasing the cytoplasmic concentration of free Ca2+ which are resistant to nifedipine.

Some evidence of the active uptake of noradrenaline in the guinea-pig isolated trachea.

1. Guinea-pig isolated trachea immersed in a low concentration (50 nM) of (-)-(3)H-noradrenaline accumulates radioactive material against an apparent concentration gradient.2. Compartmental analysis based on the decay curve of radioactive material content during washout and its comparison with that of (14)C-sorbitol shows that some extracellular noradrenaline is adsorbed. A considerable mass exists in a slowly exchanging compartment, i.e. is retained. This retention is inversely concentration dependent.3. Over a 25-fold range of concentration the entry of either total radioactive material or noradrenaline followed Michaelis-Menten kinetics.4. The uptake of radioactive material was sodium-dependent and ouabain-sensitive.5. The uptake was susceptible to metabolic poisons which deprive the tissue of all available energy but it was not exclusively associated with either oxidative or glycolytic energy supply.6. Although net uptake could not be distinguished from exchange with endogenous amine, other evidence has been obtained for an active noradrenaline transport system with properties similar to neuronal uptake.

Evidence that adrenergic nerves are responsible for the active uptake of noradrenaline in the guinea-pig isolated trachea.

1 6-Hydroxydopamine (50 mg/kg, i.p.) was given to guinea-pigs to destroy the adrenergic nerve terminals in the trachea. 2 The destruction was demonstrated by fluorescence histochemistry, which showed a marked loss of beaded fluorescent terminal fibres and by electrical transmural stimulation of the isolated atropinized trachea, which showed a marked reduction of dilator responses. 3 Such tracheae showed greatly reduced uptake-with-retention of (minus)-[3H]-noradrenaline in incubation experiments and the efflux curve of radioactive material showed a selective but incomplete reduction in the volume of the slowly exchanging compartment. 4 It is concluded that much, but perhaps not all, of the uptake-with-retention occurs into adrenergic nerves.

A patch-clamp study of K(+)-channel activity in bovine isolated tracheal smooth muscle cells.

1. Single smooth muscle cells were isolated from bovine trachealis by enzymic digestion. The properties of large conductance plasmalemmal K(+)-channels in these cells were studied by the patch-clamp recording technique. 2. Recordings were made from inside-out plasmalemmal patches when [K+] was symmetrically high (140 mM) and when [Ca2+] on the cytosolic side of the patch was varied from nominally zero to 10 microM. Large unitary currents of both Ca(2+)-dependent and -independent types were observed. Measured between + 20 and + 40 mV, the slope conductances of the channels carrying these currents were 249 +/- 18 pS and 268 +/- 14 pS respectively. 3. Lowering [K+] on the cytosolic side of the patches from 140 to 6 mM, shifted the reversal potentials of the two types of unitary current from approximately zero to much greater than + 40 mV, suggesting that both currents were carried by K(+)-channels. 4. The Ca(2+)-dependent and -independent K(+)-channels detected in inside-out plasmalemmal patches could also be distinguished on the basis of their sensitivity to inhibitors (tetraethylammonium (TEA), 1-10 mM; Cs+, 10 mM; Ba2+, 1-10 mM; quinidine, 100 microM) applied to the cytosolic surface of the patches. 5. Recordings were made from outside-out plasmalemmal patches when [K+] was symmetrically high (140 mM) and when [Ca2+] on the cytosolic side of the patch was varied from nominally zero to 1 microM. Ca(2+)-dependent unitary currents were observed and the slope conductance of the channel carrying these currents was 229 +/- 5 pS. 6. Activity of the Ca2+-dependent K+-channel detected in outside-out patches could be inhibited by application of TEA (1 mM), Cs+ (10mM), Ba2(+210mM) or quinidine (100 microM) to the external surface of the patch. 4-Aminopyridine (4-AP; 1 mM) was ineffective as an inhibitor. 7. The activity of the Ca2+-dependent K+-channel recorded from outside-out patches was reversibly inhibited by charybdotoxin (100 nM). 8. When whole-cell recording was performed, the application of a depolarizing voltage ramp evoked outward current which was dependent on the [Ca2 +] in the recording pipette and which could be reversibly inhibited by charybdotoxin (50 nM-I microM) applied to the external surface of the cell.9. We conclude that bovine trachealis cells are richly endowed with charybdotoxin-sensitive, large conductance, Ca2 +-dependent K+-channels. These channels carry most of the outward current evoked by a depolarizing ramp and could play a major role in determining the outward rectifying properties of the trachealis cells. The role of the large Ca2 + -independent K+ -channels remains unclear.

Tracheal relaxation induced by potassium channel opening drugs: its antagonism by adrenergic neurone blocking agents.

1. We have studied the ability of some adrenergic neurone blocking agents to inhibit the tracheal relaxant actions of isoprenaline, theophylline and the potassium channel openers (KCOs) BRL 38227, pinacidil and RP 52891. 2. BRL 38227, isoprenaline, pinacidil, RP 52891 and theophylline each caused concentration-dependent suppression of the spontaneous tone of guinea-pig isolated trachealis. The maximal relaxant effects of isoprenaline and pinacidil were equal to that of theophylline. In contrast, the maximal effects of BRL 38227 and RP 52891 were approximately 85-95% of that of theophylline. 3. Guanethidine (5-500 microM) did not itself modify the spontaneous tone of the trachealis muscle but antagonized BRL 38227 in a concentration-dependent manner. Guanethidine (50 microM) also antagonized pinacidil and RP 52891. However, guanethidine did not antagonize either isoprenaline or theophylline. 4. Bretylium (50 microM) did not itself modify the spontaneous tone of the trachealis muscle but antagonized BRL 38227, pinacidil and RP 52891. Bretylium did not antagonize either isoprenaline or theophylline. 5. Guanidine (50 and 500 microM) did not itself modify the spontaneous tone of the trachea and failed to modify the tracheal relaxant activity both of BRL 38227 and theophylline. 6. BRL 38227 (1 and 10 microM) stimulated, in a concentration-dependent manner, the efflux of 86Rb+ from strips of bovine trachealis muscle that had been pre-loaded with the radiotracer. Guanethidine (50 microM), bretylium (50 microM) and debrisoquine (50 microM) did not themselves modify the efflux of 86Rb+ from bovine trachealis but each of these agents markedly inhibited the stimulant effect of BRL 38227 (10 microM) on 86Rb+ efflux.7. It is concluded that the adrenergic neurone blocking agents guanethidine and bretylium can inhibit the tracheal relaxant actions of KCOs such as BRL 38227, pinacidil and RP 52891 without antagonizing isoprenaline or theophylline. The ability of the adrenergic neurone blocking agents to antagonize BRL 38227 in promoting 86Rb+ efflux from trachealis muscle may suggest that the adrenergic neurone blocking agents act to prevent the opening of the plasmalemmal K+-channel that is involved in the tracheal relaxant actions of the KCOs.

The effects of the dihydropyridine Bay K 8644 in guinea-pig isolated trachealis.

In trachea bathed by Krebs solution containing indomethacin 0.8 mumol l-1, Bay K 8644 (0.01-1 mumol l-1) evoked mild spasm. Peak tension was achieved after 10 min and was generally less than 20% of an acetylcholine (ACh) maximum. The effect of Bay K 8644 was not potentiated by addition of 2.5 mmol l-1 potassium chloride (KCl) to the Krebs solution. Bay K 8644 (1 mumol l-1) caused a small potentiation of KCl and tetraethylammonium (TEA). In contrast it did not modify the actions of ACh or histamine. Bay K 8644 (1 mumol l-1) caused a small potentiation of the effect of calcium chloride (CaCl2) tested in trachea bathed by a K+-rich, Ca2+-free, MOPS-buffered physiological salt solution. Organic inhibitors of calcium influx such as nifedipine (0.1 mumol l-1), verapamil (1 mumol l-1) or diltiazem (10 mumol l-1) each caused marked depression of concentration-effect curves to KCl. Bay K 8644 (0.01-1 mumol l-1) provided concentration-dependent protection against this effect in all three cases. Estimation of calcium influx by the lanthanum technique revealed that Bay K 8644 (1 mumol l-1) was able to promote the cellular influx of Ca2+. Intracellular electrophysiological recording showed that Bay K 8644 (1 mumol l-1) caused no change in the resting membrane potential of trachealis cells and no change in the properties of the spontaneous electrical slow waves. However, Bay K 8644 was able to delay the slow wave suppression evoked by 1 mumol l-1 nifedipine. The ability of Bay K 8644 to promote Ca2+ influx and its ability to protect against the effects of several structurally-unrelated inhibitors of Ca2+ influx are consistent with Bay K 8644 acting as an agonist at the dihydropyridine receptor associated with the voltage-operated Ca2+ channel (VOC) of trachealis muscle. By this action it potentiates those spasmogens (KCl, TEA) which act by permitting Ca2+ influx through VOCs. In contrast it has no effect on those spasmogens (ACh, histamine) which principally act to liberate Ca2+ from intracellular sites of sequestration.

The spasmogenic action of potassium chloride in guinea-pig trachealis.

Tissue bath experiments showed that potassium chloride (KC1) at 10-40 mmoll-1 evoked spasm of guinea-pig trachealis which was unaffected by atropine (1 mumoll-1), mepyramine (1 mumoll-1), tetrodotoxin (3 mumoll-1) or indomethacin (2.8 mumoll-1). Spasm evoked by KC1 was depressed in Ca2+-free Krebs solution or by exposure of tissues to LaCl3 (0.25-1 mmoll-1). Extracellular electrical recording showed that the spasm evoked by KCl 10 mmoll-1 was associated with promotion of electrical slow wave activity. Higher concentrations of KC1 abolished slow wave activity but caused further tension development. Intracellular recording confirmed the ability of KC1 10 mmoll-1 transiently to promote slow wave activity in individual trachealis cells. This action was associated with depolarization and tension development. Higher concentrations of KC1 evoked further tension development but slow waves were suppressed as the depolarization evoked by KC1 increased. KC1 (10-40 mmoll-1) increased the lanthanum-resistant calcium fraction of muscle-containing strips of trachea. It is concluded that KC1 acts directly on the smooth muscle of guinea-pig trachea. The spasmogenic action is associated with transient promotion of slow wave activity and a fall in resting membrane potential. The spasm involves the cellular influx of Ca2+ and is dependent on the presence of Ca2+ in the extracellular fluid.

Some effects of chemical irritants on the membrane of the giant amoeba.

1 The effects of chemical irritants on the membrane potential and input resistance of the giant amoeba, Chaos carolinense, have been investigated. The membrane potential and input resistance were -111.5 mV and 8.6 M pi respectively. 2 In the resting state the cell membrane of Chaos carolinense was found to be impermeable to Na+ but permeable to K+. The distribution of K+ across the cell membrane conformed to a Donnan equilibrium with the resting membrane potential being the K+ equilibrium potential. 3 The chemical irritants dibenzoxazepine and its 2-chloro- and 3-chloro-analogues and o-chlorobenzylidene malononitrile produced a fall in input resistance but no change in membrane potential. It is suggested that these effects are caused by an increase in K+ permeability. 4 The potencies of a series of chemical irritants with respect to dibenzoxazepine were measured on the giant amoeba. These potencies did not reflect those found in mammalian preparations.

A study of the sympathomimetic action of guanethidine on the isolated anococcygeus muscle of the rat.

Guanethidine, acting on the rat isolated anococcygeus, causes adrenergic neurone blockade (slowly terminated by washing), noradrenaline potentiation and, with higher concentrations, spasm (both rapidly terminated by washing). 2 The spasm is an indirect sympathomimetic action, for it is sensitive to phentolamine and reserpine and shows tachyphylaxis. 3 The concentration of cocaine equieffective with the spasmogenic concentration of guanethidine as an inhibitor of noradrenaline uptake caused much less spasm. Moreover, it did not enhance noradrenaline efflux from anococcygeus loaded with (-)-[3H]-noradrenaline, as guanethidine did. 4 The spasm induced by guanethidine in excess of cocaine is due to guanethidine-evoked noradrenaline release.

Some features of the spasmogenic actions of acetylcholine and histamine in guinea-pig isolated trachealis.

Intracellular electrophysiological recording showed that acetylcholine (1 mumol l-1) and histamine (2 mumol l-1) depolarized trachealis cells and often increased the frequency of slow waves. Higher concentrations of these agents caused greater depolarization and abolition of slow waves. Marked depolarization was often associated with the appearance of electrical 'noise'. These electrical phenomena were accompanied by tonic tension development in a contiguous segment of trachea. Electrical 'noise' and tension evoked by high concentrations of acetylcholine or histamine could be dissipated by washing the agonist from the tissue. Acetylcholine-induced 'noise' was resistant to tetrodotoxin (3 mumol l-1) and to hexamethonium (1 mmol l-1). Neither acetylcholine (10-1,000 mumol l-1) nor histamine (2-200 mumol l-1) increased the lanthanum-resistant calcium fraction of muscle-containing strips of trachea. It is concluded that, while developing tension under the influence of acetylcholine or histamine, trachealis cells depolarize markedly but there is relatively little cellular influx of Ca2+.

Evidence that the spasmogenic action of tetraethylammonium in guinea-pig trachealis is both direct and dependent on the cellular influx of calcium ion.

1 Tetraethylammonium (TEA, 1-8 mmol/l) evoked spasm of guinea-pig trachealis which was unaffected by atropine (1 mumol/l), mepyramine (1 mumol/l) or tetrodotoxin (3 mumol/l). 2 The spasm evoked by TEA was markedly suppressed in Ca2+-free Krebs solution while that evoked by acetylcholine was much less affected. 3 Extracellular electrical recording showed that exposure to Ca2+-free Krebs solution suppressed both spontaneous electrical slow wave activity of the trachea and the spasm and slow waves induced by TEA. These effects were reversible. 4 TEA (2 and 8 mmol/l) increased the lanthanum-resistant calcium fraction of trachea. 5 It is concluded that TEA acts directly on the smooth muscle of guinea-pig trachea, that the spasm and electrical slow waves evoked are Ca2+-dependent and that the cellular influx of Ca2+ is increased.

Antagonism of Ca2+ and other actions of verapamil in guinea-pig isolated trachealis.

In trachealis bathed by a K+-rich, Ca2+-free physiological salt solution, calcium chloride (CaCl2) at 0.01 to 10 mmol l-1 evoked concentration-dependent spasm. Verapamil (0.1 to 10 mumol l-1) was an effective antagonist of CaCl2. Spasm evoked by acetylcholine, histamine, potassium chloride (KCl) and tetraethylammonium (TEA) was studied in trachealis bathed by normal Krebs solution. Verapamil (0.1 to 10 mumol l-1) markedly suppressed spasm evoked by KCl and TEA. In contrast the actions of acetylcholine and histamine were much less affected by verapamil. Spasm evoked by prostaglandin E2 was studied in trachealis bathed by Krebs solution containing indomethacin (2.8 mumol l-1). Verapamil (0.1 to 10 mumol l-1) had little or no effect against prostaglandin E2-induced spasm. Verapamil (0.1 to 10 mumol l-1) had relatively little effect on the tone of trachealis bathed by normal Krebs solution. In contrast bathing in Krebs solution lacking CaCl2 caused almost complete tone loss. Extracellular electrophysiological recording showed that verapamil (10 mumol l-1) suppressed not only TEA-evoked spasm but also TEA-evoked slow waves and spike potentials. Verapamil also abolished the transient period of slow wave activity associated with the spasm evoked by KCl. Intracellular electrophysiological recording showed that TEA-induced spike activity was resistant to tetrodotoxin (3 mumol l-1). However, verapamil (10 mumol l-1) abolished the tetrodotoxin-resistant spikes without increasing the resting membrane potential. It is concluded that verapamil suppresses TEA- or KCl-induced spasm, slow waves or spikes by inhibition of Ca2+ influx. Spasm evoked by acetylcholine, histamine and prostaglandin E2 depends on mechanisms for increasing the cytoplasmic concentration of free Ca2+ which are resistant to verapamil. The failure of verapamil markedly to depress tissue tone is consistent with the proposal that tone results from the activity of endogenous prostaglandins.

The relaxant action of nicorandil in guinea-pig isolated trachealis.

Nicorandil (1-1000 mumol l-1) caused concentration-dependent relaxation of guinea-pig isolated trachealis. Propranolol (1 mumol l-1) did not modify the relaxant action of nicorandil but antagonized isoprenaline. Among K+-channel inhibitors tested, apamin (0.1 mumol l-1) and procaine (5 mmol l-1) did not modify the relaxant action of nicorandil. In contrast, tetraethylammonium (TEA, 8 mmol l-1) caused five fold antagonism. Trachealis exposed to K+-rich (120 mmol l-1) Krebs solution developed near-maximal tension. Nicorandil relaxed the K+-depolarized tissue though its concentration-effect curve was shifted markedly to the right. In tissues in which tone was induced by histamine, methylene blue (100 mumol l-1) antagonized nicorandil and sodium nitroprusside but did not modify the relaxant action of aminophylline. Intracellular electrophysiological recording showed that nicorandil (1 mumol l-1) could evoke some relaxation in the absence of electrical changes. Higher concentrations (10-1000 mumol l-1) reduced the amplitude and frequency of spontaneous electrical slow waves. Nicorandil also caused concentration-dependent hyperpolarization and relaxation. When the hyperpolarization was sufficiently pronounced slow wave activity was abolished. TEA (8 mmol l-1) induced slow waves which were surmounted by a spike potential. TEA slightly reduced the maximal hyperpolarization induced by nicorandil and increased the time required for nicorandil to abolish slow wave discharge. Procaine (5 mmol l-1) induced slow waves of relatively low frequency. Sometimes these were surmounted by a spike potential Procaine markedly reduced the hyperpolarization induced by nicorandil and increased the time required for abolition of slow waves. In studies of the efflux of 86Rb+ from muscle-rich strips of trachea, nicorandil (1000 mumol l-1) increased the efflux rate constant, whereas isoprenaline (1 mumol l-1) was without effect. It is concluded that nicorandil-induced relaxation does not involve the activation of beta-adrenoceptors but is partly attributable to the formation of nitric oxide from the nitrate moiety in its molecular structure. Nicorandil can evoke relaxation in the absence of membrane potential change but towards the upper end of its effective concentration range, nicorandil increases membrane K+ conductance and thereby evokes hyperpolarization of trachealis cells. The K+ channels opened by nicorandil are permeable to 86Rb, insensitive to apamin and TEA but may be inhibited by procaine.

Inhibitory responses to nicotine and transmural stimulation in hyoscine-treated guinea-pig isolated trachealis: an electrical and mechanical study.

Guinea-pig isolated trachealis muscle treated with hyoscine (1 microM) exhibited mechanical tone which could be suppressed by transmural stimulation and, in a concentration-dependent manner, by nicotine (10-1000 microM). Hexamethonium (500 microM) did not itself cause tone changes, antagonized effects of nicotine but did not antagonize those of isoprenaline. Tetrodotoxin (0.3 microM) did not itself cause tone changes, did not modify the action of isoprenaline but antagonized the effects of nicotine and very markedly reduced responses to transmural electrical stimulation. Guanethidine (50 microM) did not itself cause tone changes, potentiated the action of isoprenaline, antagonized effects of nicotine and reduced responses to transmural electrical stimulation. Propranolol (1 microM) did not itself cause tone changes, antagonized effects of both isoprenaline and nicotine and reduced responses to transmural electrical stimulation. Propranolol (10 microM) caused greater antagonism of isoprenaline but did not further antagonize nicotine or further reduce responses to electrical stimulation. Intracellular electrophysiological recording from hyoscine-treated trachealis showed that 10 microM nicotine caused little or no mechanical or electrical change. Higher concentrations (100 microM and 1 mM) evoked relaxation which was often though not invariably accompanied by transient hyperpolarization and transient inhibition of electrical slow waves in the impaled cell. Hexamethonium (500 microM), tetrodotoxin (0.3 microM), guanethidine (50 microM) and propranolol (1 microM) each suppressed the electrical or mechanical changes evoked by nicotine (100 microM). However, nicotine (1 mM) tested in the presence of propranolol (1 microM), caused relaxation which could be accompanied by slow wave suppression but not by change in resting membrane potential. Transmural stimulation of hyoscine-treated trachea with single pulses of supramaximal voltage and 0.5 ms duration evoked neither relaxation nor membrane potential changes. Stimulation with similar pulses in trains of 5 s duration evoked relaxation which was dependent on pulse frequency. In many cells this relaxation was not accompanied by membrane potential change. In other cells suppression of slow waves occurred. At high pulse frequencies (greater than 16 Hz) this was generally accompanied by membrane hyperpolarization. In tissue treated with hyoscine and propranolol (both 1 microM), transmural stimulation with pulse trains as described above always evoked relaxation but no membrane potential changes were observed. 10 It is concluded that nicotine and transmural stimulation can excite intramural noradrenergic nerves in guinea-pig trachea and thereby evoke relaxation. The membrane potential changes (slow wave suppression and hyperpolarization) are similar to those evoked by the administration of agonists at beta-adrenoceptors. Nicotine and transmural stimulation also excite non-adrenergic non-cholinergic inhibitory (NANCI) nerves. The relaxation evoked by the NANCI neurotransmitter is accompanied by little, if any, membrane potential change.

Inhibitory effects of AH 21-132 in guinea-pig isolated ileum and taenia caeci.

1. AH 21-132 is being investigated as a potential chemotherapeutic agent for bronchial asthma. The present experiments were designed to determine whether AH 21-132 shares the activity of theophylline as an antagonist at adenosine A1 receptors and to assess its potency as a relaxant in intestinal smooth muscle. 2. In the transmurally-stimulated guinea-pig ileum, theophylline (1 mM), but not AH 21-132 (1 and 10 microM), antagonized twitch depression induced by adenosine. Higher concentrations (100 microM and 1 mM) of AH 21-132 themselves had a depressant effect. Neither theophylline (1 mM) nor AH 21-132 (1 and 10 microM) antagonized twitch depression induced by noradrenaline. 3. AH 21-132 (100 microM and 1 mM) depressed maximum contractions of ileum induced by both acetylcholine (ACh) and histamine. 4. In ileum treated with hyoscine (1 microM), AH 21-132 (greater than 10 microM) caused a concentration-dependent depression of the log concentration-effect curve for potassium chloride. 5. Simultaneous extracellular electrophysiological and mechanical recording from taenia caeci showed that AH 21-132 (100 microM-1 mM) inhibited spontaneous tension waves and their associated bursts of electrical spike activity. 6. Intracellular electrophysiological recording from taenia caeci showed that the mechano-inhibitory effect of 1 mM AH 21-132 was accompanied by abolition of spontaneous spike activity. Following spike abolition, the membrane potential assumed a value very close to that observed during periods of electrical quiescence prior to drug exposure. 7. AH 21-132 inhibited the activity of cyclic AMP-dependent and cyclic GMP-dependent phosphodiesterases derived from homogenates of ileal smooth muscle. The effective concentration ranges were 0.1-1OOO microM and 1-1000 microM, respectively. Theophylline, too, inhibited these enzymes but in each case was less potent than AH 21-132. 8. It is concluded that AH 21-132 is devoid of antagonist activity at adenosine Al receptors which modulate ACh release from intramural cholinergic nerves in the ileum. At concentrations greater than IO microM, AH 21-132 has a relaxant effect on intestinal smooth muscle characterized by suppression of spontaneous action potentials but by minor change in resting membrane potential. AH 21-132 previously has been reported to depress the spontaneous tone of trachealis muscle with an EC50 value of less than lO microM and the present experiments therefore show that this agent is much less potent in inhibiting intestinal muscle. This potency difference cannot be attributed to a tissuerelated difference in the potency of AH 21-132 as an inhibitor of cyclic AMP- or cyclic GMPdependent phosphodiesterases.

Effects of cromakalim on neurally-mediated responses of guinea-pig tracheal smooth muscle.

1. The ability of cromakalim to modulate several different types of neuroeffector transmission has been assessed in guinea-pig isolated trachea. 2. In trachea treated with propranolol (10(-6) M) and indomethacin (2.8 x 10(-6) M), stimulation of the extrinsic vagal nerves evoked contractions which were blocked by hexamethonium (5 x 10(-4) M) or by tetrodotoxin (TTX; 10(-6) M). Cromakalim (10(-5) M) caused a two fold rightward shift of the frequency-response curve. 3. In carinal trachea treated with propranolol and indomethacin, transmural stimulation evoked an initial, rapid contraction followed by a more sustained secondary contraction. The initial, rapid contractile response was virtually ablated by atropine (10(-6) M) or by TTX but was resistant to hexamethonium. Cromakalim (10(-8)-10(-5) M) caused a concentration-dependent rightward shift of the frequency-response curve for the initial contraction. 4. In carinal trachea treated with atropine, propranolol and indomethacin, transmural stimulation evoked only the secondary (non-adrenergic, non-cholinergic (NANC] contractile responses. These were markedly reduced by TTX but were resistant to hexamethonium. Cromakalim (10(-8)-10(-5) M) suppressed the NANC contractile responses in a concentration-dependent manner. This action could be offset by glibenclamide (10(-6) M). 5. In trachea treated with atropine, histamine (10(-4) M), propranolol and indomethacin, transmural stimulation evoked NANC relaxant responses. Cromakalim (up to 10(-5) M) was without effect on the frequency-response curve for the stimulation of NANC inhibitory nerves. 6. Tested on trachea bathed by drug-free Krebs solution, cromakalim (10(-7)-10(-5) M) caused concentration-dependent suppression of tracheal tone. In trachea treated with propranolol and indomethacin, cromakalim (10- 7-1O- 5 M) caused concentration-dependent antagonism of acetylcholine (ACh). In trachea treated with atropine, propranolol and indomethacin, cromakalim (up to 10- 5M) failed to antagonize effects of either histamine or substance P.7. It is concluded that cromakalim can inhibit cholinergic (excitatory) neuroeffector transmission in the trachea but only at a concentration having demonstrable inhibitory activity against the action of exogenous ACh and the spontaneous tone of the airways smooth muscle. In contrast, cromakalim may depress NANC excitatory (putative peptidergic) neuroeffector transmission at a concentration below that exerting inhibitory activity on airways smooth muscle. Cromakalim does not concurrently depress NANC inhibitory neuroeffector transmission. Depression of NANC excitatory neuroeffector transmission could explain the ability of cromakalim to suppress airway hyperreactivity or bronchial asthma at doses lacking direct relaxant effect on airways smooth muscle.

Effects of some K(+)-channel inhibitors on the electrical behaviour of guinea-pig isolated trachealis and on its responses to spasmogenic drugs.

1. A study has been made of the effects of inhibitors selective among plasmalemmal K(+)-channels on the sensitivity and responsiveness of guinea-pig trachealis muscle to carbachol, histamine and KCl. The effects of the K(+)-channel inhibitors on the resting membrane potential and spontaneous electrical activity of the trachealis cells have also been examined. 2. In indomethacin (2.8 microM)-treated trachealis muscle, dofetilide (1 microM) and glibenclamide (10 microM) were each devoid of spasmogenic activity. In contrast, 4-aminopyridine (4-AP, 62.5 microM--8 mM), charybdotoxin (ChTX, 100 nM) and iberiotoxin (IbTX, 100 nM) were each spasmogenic. Spasm evoked by 4-AP, IbTX or ChTX was reduced, though not abolished, by atropine (1 microM). Spasm evoked by 4-AP (1 mM), ChTX (100 nM) or IbTX (100 nM) was unaffected by tetrodotoxin (TTX; 3.1 microM) or by tissue pretreatment with capsaicin (1 microM for 30 min). Spasm evoked by IbTX or ChTX was abolished by nifedipine (1 microM). 3. Dofetilide (1 microM) and glibenclamide (10 microM) were each without effect on the tracheal sensitivity or responsiveness to carbachol, histamine or KCl. 4-AP (1 mM) antagonized carbachol, potentiated histamine but did not affect tissue sensitivity to KCl. When the effects of 4-AP were examined in the presence of atropine (1 microM), it potentiated all the spasmogens including carbachol. IbTX and ChTX (each 100 nM) potentiated all three spasmogens. Potentiation of histamine induced by 4-AP (1 mM) or IbTX (100 nM) was also observed in tissues treated with a combination of atropine (1 microM) and TTX (3.1 microM). 4. Dofetilide (1 and 10 microM) was without effect on the resting membrane potential or spontaneous electrical activity of the trachealis cells. 4-AP (1 mM) evoked depolarization and caused a small increase in the frequency of slow wave discharge. The depolarization evoked by 4-AP was abolished by atropine (1 microM). IbTX (100 nM) and ChTX (100 nM) each evoked little or no change in resting membrane potential but converted the spontaneous slow waves into spike-like, regenerative action potentials. These electrophysiological effects of IbTX and ChTX were unaffected by atropine (1 microM). 5. It is concluded that the dofetilide-sensitive, cardiac, delayed rectifier K(+)-channel is either not expressed in trachealis muscle or is of no functional importance in that tissue. The ATP-sensitive K(+)-channel (KATP) does not moderate tracheal sensitivity to spasmogens such as carbachol, histamine and KCl. The 4-AP-sensitive delayed rectifier K(+)-channel (Kdr) and the large Ca(2+)-dependent K(+)-channel (BKCa) each moderate trachealis muscle sensitivity to spasmogens. Neither Kdr nor BKCa plays an important role in determining the resting membrane potential of guinea-pig trachealis cells. However, the BKCa channel is responsible for limiting the effects of the increase in membrane Ca2+ conductance associated with the depolarizing phase of slow waves. It is BKCa channel opening that prevents the development of a slow wave into a spike-like regenerative action potential.

Electrophysiological and other aspects of the relaxant action of isoprenaline in guinea-pig isolated trachealis.

In guinea-pig isolated trachealis isoprenaline (0.001-0.1 mumol l-1) caused concentration-dependent relaxation. Propranolol (1 mumol l-1) antagonized the effects of isoprenaline by more than 100 fold but did not modify the relaxant action of sodium nitrite. The tracheal relaxant actions of isoprenaline and ATP were unaffected by apamin (0.1 mumol l-1) but apamin profoundly antagonized the effects of noradrenaline and ATP on guinea-pig isolated taenia caeci. Tetraethylammonium (TEA; 8 mmol l-1) and procaine (5 mmol l-1) each evoked tracheal spasm but neither agent antagonized the isoprenaline-evoked relaxation of the trachealis. Trachealis exposed to K+-rich (120 mmol l-1) Krebs solution developed near-maximal tension. Both isoprenaline and sodium nitrite relaxed the K+-depolarized tissue though concentration-effect curves for both relaxants were moved to the right compared to those obtained in non-depolarized tissues. The maximal effect of sodium nitrite was markedly reduced. Intracellular electrophysiological recording showed that isoprenaline (0.01-1 mumol l-1) caused hyperpolarization and reduced or abolished slow wave discharge in trachealis muscle. These effects were accompanied by relaxation. Propranolol (1 mumol l-1) virtually abolished both the electrical and mechanical responses to isoprenaline (0.1 mumol l-1). Apamin (0.1 mumol l-1) did not alter the spontaneous electrical activity of trachealis cells or their electrical and mechanical responses to isoprenaline (0.1 mumol l-1). TEA (8 mmol l-1) caused depolarization and often increased slow wave amplitude and induced spike discharge. Isoprenaline (0.01 mumol l-1) failed to hyperpolarize TEA-treated trachealis cells. Higher concentrations of isoprenaline suppressed TEA-induced spasm, caused hyperpolarization and thereby increased slow wave or spike amplitude. Slow wave or spike frequency decreased as the hyperpolarization progressed but abolition of slow waves or spikes sometimes required more than 4 min exposure to isoprenaline. Procaine (5 mmol l-1) increased the amplitude of slow waves and induced spike discharge. Procaine markedly reduced the hyperpolarization induced by isoprenaline (0.1 and 1 mumol l-1) but had little effect on isoprenaline-induced relaxation. It is concluded that isoprenaline activates beta-adrenoceptors in guinea-pig trachealis and thereby evokes relaxation and hyperpolarization of the smooth muscle. The hyperpolarization does not involve the opening of apamin-sensitive K+-channels and it probably plays a supportive rather than a crucial role in the process by which isoprenaline-induced relaxation is achieved.