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Notes: Abstract This study investigates the role of tachykinin NK1 and NK2 receptors in motor responses induced by the intravesical instillation of capsaicin in urethane-anaesthetized rats. SR 140,333 (1 µmol/kg, i.v.), a non-peptide NK1 receptor antagonist, abolished urinary bladder contractions induced by the selective NK1 receptor agonist [Sar9]SP-sulfone (0.1-100 nmol/kg, i.v.) without affecting those induced by the NK2 receptor agonist [ßAla8]NKA(4-10). MEN 11,420 (100 nmol/kg, i.v.), a cyclic peptide NK2 receptor antagonist, abolished bladder contractions induced by [ßAla8]NKA(4-10) (0.3-300 nmol/kg, i.v.) without modifying those induced by [Sar9]SP-sulfone. Intravesical instillation of capsaicin (6 nmol/0.6 ml/rat) produced a motor response consisting in a primary contraction followed by a series of high amplitude phasic contractions. The intravesical instillation of saline (0.6 ml/rat) produced a primary contraction of lower amplitude with respect to that induced by capsaicin and the total area under the curve was also lower in saline-instilled rats, however the number and the amplitude of phasic contractions was similar to that induced by capsaicin. MEN 11,420 (100 nmol/kg, i.v.) did not modify motor responses induced by the intravesical administration of saline. In contrast, in capsaicin-instilled rats, MEN 11,420 (100 nmol/kg, i.v.) reduced the primary contraction, the area under the curve and also the number of phasic contractions. SR 140,333 (1 µmol/kg, i.v.) reduced the primary contraction but not other parameters. The combination of SR 140,333 (1 µmol/kg, i.v.) and MEN 11,420 (100 nmol/kg, i.v.) produced an additive inhibitory effect on the primary contraction but not a further inhibition on other parameters with respect to that observed with MEN 11,420 alone. In hexamethonium (110 µmol/kg, i.v.)-pretreated animals the intravesical instillation of capsaicin produced a tonic contraction having greater amplitude and area than that induced by saline. MEN 11,420, but not SR 140,333, significantly reduced the bladder response to capsaicin in hexamethonium-pretreated rats. Again, the combined administration of MEN 11,420 and SR 140,333 did not produce further inhibitory effect in comparison to MEN 11,420 alone. It is concluded that the motor responses induced by the intravesical instillation of capsaicin are mediated by the activation of peripheral tachykinin NK2 receptors.

Notes: Abstract The study aimed to establish the possible role of tachykinins as mediators of atropine-resistant reflex contractions evoked by balloon distension in the proximal duodenum of urethane-anesthetized, guanethidine (34 μmol/kg s.c.)-pretreated rats. Distension of the balloon with a small amount (0.2–0.3 ml) of saline induced the appearance of phasic rhythmic contractions (about 11 mmHg in amplitude) which were promptly suppressed by either atropine (3 μmol/kg i.v.) or hexamethonium (28 μmol/kg i.v.). Despite the continuous i.v. infusion of atropine (2 μmol/h), low-amplitude rhythmic phasic contractions recovered, which were promptly suppressed by hexamethonium, to indicate the involvement of an atropine-resistant excitatory reflex. The amplitude of these atropine-resistant contractions was increased to about 4–5 mmHg by further distension of the balloon (0.4–0.6 ml) : under these conditions, the atropine-resistant contractions undergo a progressive fading. The fading was prevented by i.v. administration of the nitric oxide (NO) synthase inhibitor, L-nitroarginine methyl ester (L-NAME, 55 μmol/h), to provide a suitable baseline (amplitude of contractions was 7–8 mmHg) for studying the effect of tachykinin receptor antagonists. I.v. administration of the selective tachykinin NK2 receptor antagonists, MEN 10,627 (10–100 nmol/kg) and SR 48968 (100–300 nmol/kg) or of the selective NK1 antagonist SR 140333 (100 nmol/kg), at doses which do not affect the duodenal contractions induced by acetylcholine (5.5 µmol/kg i.v.), produced a prompt and long lasting suppression of the atropine-resistant reflex duodenal contractions produced by balloon distension in urethane-anesthetized rats, whilst SR 48965 (300 nmol/kg), the enantiomer of SR 48968 devoid of NK2 receptor blocking activity, was without effect. I.v. administration of the selective NKi receptor agonists [Sar9] substance P sulfone and septide or of the NK2 receptor selective agonist, βAla8] neurokinin A(4–10) produced dose-dependent contractions of the duodenum. SR 140333 (100 nmol/kg i.v.) selectively antagonized the duodenal contractions produced by [Sar9] substance P sulfone and septide without affecting those produced by [βAla8] neurokinin A(4–10). On the other hand, MEN 10,627 (30–100 nmol/kg i.v.) and SR 48968 (100–300 nmol/kg i.v.) but not SR 48965 (300 nmol/kg i.v.) antagonized, at a comparable extent, duodenal contractions induced by both the selective NK2 and NK1 receptor agonists. We conclude that endogenous tachykinins are involved in mediating atropine-resistant reflex contractions evoked by distension of the rat duodenum in vivo: both NK1 and NK2 receptors are activated by endogenous ligands to produce NANC contractions of rat duodenum in vivo. However, the contractile response to i.v. administered NK1 receptor agonists, [Sar9] substance P sulfone and septide, may involve the release of mediators producing smooth muscle contraction via NK2 receptors.

Notes: Abstract. The aim of this study was to compare the stimulus-response characteristics of the cholinergic and tachykininergic excitatory transmission to the circular muscle of the guinea-pig proximal colon and their susceptibility to inhibition by the N-type calcium channel blocker ω-conotoxin (CTX). All experiments were performed in the presence of guanethidine (3 μM), indomethacin (10 μM), L-nitroarginine (L-NOARG, 30 μM) and apamin (0.1 μM). In the presence of the tachykinin receptor antagonists, FK 888 (10 μM) and GR 94800 (3 μM), to block NK1 and NK2 receptors, respectively, electrical field stimulation (EFS) produced frequency-dependent atropine- (1 μM) sensitive contractions. In the presence of atropine (1 μM), EFS produced tachykininergic contractions which were abolished by the combined administration of FK 888 (10 μM) and GR 94800 (3 μM). The maximal responses produced by cholinergic and tachykininergic neurotransmission ranged between 80 and 100% of the maximal contractile response to 80 mM KCl. The frequency of stimulation, pulse width and voltage required to produce 50% of the maximal cholinergic and tachykininergic contraction were not different from each other, although cholinergic transmission appeared more efficient in producing twitch contractions in response to single pulse EFS. Furthermore, cholinergic transmission was more efficient than tachykininergic transmission in producing contraction in response to short periods of EFS.   CTX (0.1 μM for 30 min) produced a large and comparable rightward shift of the cholinergic and tachykininergic frequency-response curve (19 and 17 fold increase in the frequency of stimulation producing 50% of the maximal response, respectively) and markedly depressed (51 and 43% inhibition, respectively) the maximal concentrations response. CTX failed to affect the contraction of the colon produced by submaximally effective concentrations of the muscarinic receptor agonist, methacholine (0.1–0.3 μM) and those produced by the tachykinin NK1 and NK2 receptor selective agonists [Sar9] substance P sulfone and [βAla8] neurokinin A (4–10) (1–3 nM).   The present findings demonstrate that the cholinergic and tachykininergic components of the excitatory transmission to the circular muscle of the guinea-pig colon are activated at comparable intensities of nerve stimulation and are both inhibited, in a qualitatively and quantitatively comparable manner, by CTX at the prejunctional level. These findings are consistent with the idea that acetylcholine and tachykinins are co-released from the same population of enteric motoneurones which innervate the circular muscle of the colon.

Notes: Summary 1. The effects of capsaicin, substance P (SP) and neurokinin A (NKA) on motor activity and vascular permeability was investigated in the rat lower urinary tract (bladder dome and neck, proximal urethra and ureters). 2. Capsaicin produced contractions of the rat bladder dome and neck and of the proximal urethra in vitro, which were unaffected by tetrodotoxin and abolished by ganglionectomy. SP and NKA were almost equipotent in producing a contraction of the rat isolated bladder dome or neck and urethra. However, the maximal response to NKA was about twice that of SP on the urethra and bladder neck. 3. Capsaicin did not affect motility of the unstimulated rat isolated ureter, while NKA or SP activated rhythmic contractions, NKA being about 850 times more potent than SP. Either capsaicin or field stimulation produced a transient inhibition of the NKA-activated rhythmic contractions of the rat isolated ureter which was prevented by capsaicin-desensitization. 4. The capsaicin-(1 μM) or field stimulation-induced inhibition of NKA-activated rhythmic contractions of the rat isolated ureter were unaffected by removal of pelvic ganglia but abolished by cold storage (72 h at 4°C). 5. Intravenous capsaicin induced an inflammatory response (Evans blue leakage) in the bladder, proximal urethra and ureters in vivo. Plasma extravasation was greater in the ureters, urethra and bladder neck than in the dome. SP, NKA and histamine produced a dose-dependent dye leakage in all segments of the rat urinary tract, the response being slightly greater in the bladder neck than in the dome. 6. The capsaicin-induced inflammatory response was abolished by systemic capsaicin-desensitization and reduced, to a variable extent, by pelvic ganglionectomy, in the various tissues examined. Topical application of tetrodotoxin on the bladder dome failed to affect the capsaicin-induced plasma extravasation in the urinary bladder. 7. These findings indicate that chemoceptive, capsaicin-sensitive nerves are present throughout the whole rat lower urinary tract and their activation determines a variety of visceromotor responses and an increase of vascular permeability. In various instances the response to capsaicin may be explained by the action of tachykinins but some effects may involve other sensory neuropeptides.

Notes: Summary 1. The effect of omega-conotoxin (CTX) GVIA, a peptide which blocks neuronal calcium channels, were investigated on nerve-mediated motor responses in a variety of isolated smooth muscle preparations from rats and guinea-pigs. 2. In the rat or guinea-pig isolated vas deferens CTX (1 nM − 1 μM) produced a concentration and time-related inhibition of the response to field stimulation, while the responses to KCI, noradrenaline or adenosine triphosphate were unaffected. In the presence of CTX a series of tetrodotoxin-resistant contractions could be elicited by field stimulation by increasing pulse width and/or voltage. 3. In the rat or guinea-pig isolated urinary bladder, CTX produced a concentration and time-dependent inhibition of twitch responses to field stimulation without affecting the response to exogenous acetylcholine. In the rat bladder the maximal effect did not exceed 25% inhibition while a much larger fraction of the response (about 70%) was inhibited in the guinea-pig bladder. The CTX-resistant response was abolished, in both tissues, by tetrodotoxin. 4. The effects of CTX in the rat bladder were also studied with a whole range of frequencies of field stimulation (0.1–50 Hz). Maximal inhibition was observed toward contractions elicited at frequencies of 2–5 Hz. At low frequencies the inhibitory effects of CTX and atropine were almost additive while at high frequencies of stimulation a large component of the atropine-sensitive response was CTX-resistant. 5. In the rat isolated proximal duodenum, field stimulation in the- presence of atropine and guanethidine produced a primary relaxation followed by a rebound contraction. Both responses were abolished by tetrodotoxin, indicating the activation of intramural nonadrenergic noncholinergic nerves. The primary relaxation was totally CTX resistant while the rebound contraction was slightly inhibited. 6. The motor responses produced by capsaicin (1 μM) in the rat or guinea-pig bladder (contraction) and in the rat proximal duodenum (relaxation) were unaffected by CTX. Likewise, the release of substance P-like immunoreactivity from sensory nerves of the guinea-pig bladder muscle was unaffected by CTX. 7. These findings indicate that CTX-sensitive calcium channels modulate transmitter release in autonomic nerve terminals of mammals, but noticeable species and organ related variations exist in sensitivity to this peptide, possibly reflecting the existence of a heterogenous population of voltage-sensitive calcium channels. CTX-sensitive calcium channels are apparently not involved in the excitatory action of capsaicin on sensory nerve terminals.

Notes: Summary We have studied the motor response to ethyenediamine (EDA), a well known releaser of endogenous GABA, on the longitudinal muscle of the rat isolated proximal duodenum in presence of atropine (3 μM) and guanethidine (3 μM). EDA produced a concentration-(0.03 – 3 μM)-dependent relaxation which was potentiated when the preparations were exposed to GABA during the equilibration period. The GABA-induced potentiation of the response to EDA was prevented by nipecotic acid, an inhibitor of GABA uptake. The response to EDA was partially inhibited by 3-mercaptopropionic acid, a known inhibitor of GABA release. However, contrary to the relaxant response produced by exogenous GABA, the EDA-induced relaxation was picrotoxin-(0.1 μM)-resistant. In preparations pre-exposed to GABA, the response to EDA was partially tetrodotoxin-(1 μM)-sensitive. By contrast, in preparations not exposed to GABA, the EDA-induced relaxation was totally tetrodotoxin resistant. The response to EDA was abolished or largely inhibited in preparations excised from rats in which the proximal duodenum was chemically denervated by exposure (2 weeks before), to benzalkonium chloride (BZK). Likewise, the indirect relaxations produced by electrical field simulation, DMPP, capsaicin or GABA were abolished by BZK pretreatment while noradrenaline was still effective. These findings indicate that the relaxant response to EDA is neurogenic in origin, while being largely tetrodotoxin-resistant. A GABAergic mechanism could be involved but also other inhibitory transmitter(s) should be taken into account. EDA appears a useful tool to study the inhibitory non-adrenergic non-cholinergic innervation of the rat proximal duodenum.

Notes: Summary The mechanisms responsible for nerve-mediated, non-adrenergic, non-cholinergic (NANC) relaxation in mucosa-free circular muscle strips from the proximal colon of the guinea-pig were investigated. Electrical field stimulation (EFS, 1–20 Hz, trains of 5 s duration, 100 V, 0.25 ms pulse width) in the presence of atropine (1 μmol/l) and guanethidine (3 μmol/l) evoked a triphasic motor response consisting of. (a) a primary relaxation, (b) a rebound contraction and (c) a secondary relaxation. These three responses were abolished by tetrodotoxin (1 μmol/l). Both apamin (0.01–0.3 μmol/l), a known blocker of low conductance, calcium-activated potassium channels in smooth muscles, and L-nitroarginine (L-NOARG) (1–100 μmol/l), a known blocker of nitric oxide (NO) synthase, increased the tone of the strips. Maximum effects on tone were observed with 0.1 μmol/l apamin (21 ± 3% of KCl-induced contraction) and 30 μmol/l L-NOARG (26 ± 4% of KCl response). The combined administration of 0.1 μmol/l apamin and 30 μmol/l L-NOARG produced an increase in tone (47 ± 5% of KCl response) that was larger than that produced by either compound alone. Neither apamin (0.1 μmol/l) nor L-NOARG (30 μmol/l) affected the isoprenaline-induced relaxation. Apamin (0.1 μmol/l) depressed, but did not abolish, the primary relaxation to EFS at all frequencies without affecting the secondary relaxation. Apamin also enhanced the rebound contraction at a frequency of 1 Hz. L-NOARG (30 μmol/l) depressed, but did not abolish, the primary relaxation to EFS at all frequencies, had no effect on the rebound contraction and inhibited the secondary relaxation evoked at frequencies of 1–5 Hz, but not 10–20 Hz. L-arginine (300 μmol/l) reversed the effect of L-NOARG on tone and the inhibitory effect on the EFS-evoked relaxation. In the presence of apamin and L-NOARG, the primary relaxation was suppressed at all frequencies; the secondary relaxation was inhibited at 1–5 Hz and unchanged at 10–20 Hz, as observed with L-NOARG alone. We conclude that three distinct mechanisms mediate the NANC relaxation of the circular muscle of the proximal colon of the guinea-pig in response to EFS. One mechanism can be operationally defined as apamin-sensitive and a second as L-NOARG-sensitive, the latter implying a possible role of NO as an inhibitory transmitter. A third NANC inhibitory mechanism, which is apamin- and L-NOARG-resistant, is also suggested.

Notes: Abstract We have investigated the effect of the dihydropyridine calcium channel agonist, Bay K 8644, and of the plant alkaloid blocker of calcium-induced calcium release (CICR) from the sarcoplasmic reticulum, ryanodine, on the refractory period, action potential and mechanical response of the guinea-pig isolated ureter to electrical stimulation. All experiments were performed in ureters pre-exposed to 10 μM capsaicin to eliminate the inhibitory influence exerted by local release of sensory neuropeptides on ureteral excitability and contraction. In organ bath experiments, electrical field stimulation with parameters which produce direct excitation of ureteral smooth muscle (train of pulses at 10 Hz, 5 ms pulse width, 60 V for 1 s) produced tetrodotoxin- (1 μM) resistant phasic contractions. The response to EFS was abolished by nifedipine (1 nM-3 μM) and was enhanced by Bay K 8644 (1 nM-3 μM). In the presence of Bay K 8644 (1 μM), nifedipine (30 μM) abolished the evoked contractions. Ryanodine (10–100 μM) had no significant effect on the amplitude of evoked contraction. The response of the guinea-pig ureter to direct electrical stimulation of smooth muscle is characterized by a refractory period: at least 40 s interstimulus interval was required to produce a second response in all preparations tested. Bay K 8644 (1 μM) markedly reduced the refractory period of the ureter and a similar effect was observed with ryanodine (100 μM). To further analyze the effect of Bay K 8644 and ryanodine on the refractory period, the response of the ureter was investigated over a 10 s period of stimulation (other parameters as above). In control ureters, continuous stimulation for 10 s produced only one phasic contraction just after the beginning of the train of stimuli. In the presence of Bay K 8644 or ryanodine, more than one phasic contraction developed during a 10 s stimulation, i.e. the refractory period became shorter than the train duration. When both Bay K 8644 and ryanodine were tested on the same preparations, an additive excitatory effect was observed on the mechanical response to electrical stimulation. A slight elevation of KCI concentration (5–10 mM) reduced the refractory period of the ureter as observed with ryanodine or Bay K 8644. Application of KCI (80 mM) produced a biphasic contractile response of the ureter: a series of phasic contractions occurred first, which were then replaced by a slowly developing tonic response. Bay K 8644 (1 μM) enhanced both components of the response to KCI. Ryanodine (10 and 100 μM) markedly prolonged the duration of phasic contractions evoked by KCI and, at 100 μM, slightly (about 25%) reduced the amplitude of tonic contraction. In sucrose gap experiments, electrical stimulation (single pulse, 40–130 V, 1–3 ms pulse duration) evoked an action potential and accompanying phasic contraction which were abolished by 1 μM, nifedipine. Bay K 8644 (1 μM) produced a marked prolongation of action potential duration, increased the number of spikes and enhanced contraction amplitude and duration. Ryanodine (100 μM) depolarized the membrane, reduced the delay between stimulus application and onset of the action potential, shortened the action potential at 50% of repolarization and increased afterhyperpolarization, without producing marked effects on the accompanying mechanical response. KCI (5 mM) likewise produced a slight membrane depolarization and decreased latency between stimulus application and onset of the action potential but did not affect action potential duration. The combined administration of ryanodine and Bay K 8644 produced additive effects on action potential and contractions: furthermore, the contractile phase of the overall contraction-relaxation cycle was significantly prolonged by the combined administration of the two agents, an effect not observed with either drug alone. In the presence of both Bay K 8644 and ryanodine, multiple action potentials and contractions were observed during a train of pulses delivered at a frequency of 1 Hz for 12 s: when a second action potential was triggered before relaxation of the preceding contraction, a summation of the contractile response was observed. These findings demonstrate that availability of voltage-dependent L-type calcium channels is a major mechanism in determining the refractory period of the guinea-pig ureter and, consequently, can be considered as a limiting step in regulating the maximal frequency of ureteral peristalsis. Furthermore, a ryanodine-sensitive mechanism regulates the excitability and contraction-relaxation cycle of ureteral smooth muscle. The increased electrical excitability of the ureter observed in the presence of ryanodine may involve blockade of transient outward currents triggered by spontaneous calcium release from the store and consequent membrane depolarization.