Marked antiinflammatory effects of decentralization of the superior cervical ganglia.

Intravenous challenge with parasite antigens in Nippostrongylus brasiliensis-sensitized rats resulted in anaphylactic shock and, in some animals, death. Surviving animals showed significant drop in mean arterial blood pressure, cardiac output, and blood flow to the trachea, bronchioles, and mesentery. After anaphylaxis, changes in the cellular and protein composition in bronchoalveolar lavage fluids (BALF) were assessed. 8 h after antigen challenge, there was significant influx of inflammatory cells and an increase in the levels of histamine and serum-derived immunoglobulins (IgG and IgM) in BALF. Chemotactic activity for neutrophils was also present in BALF. Once we established this anaphylaxis-induced model of pulmonary inflammation, we sought to determine whether or not the superior cervical ganglia (SCG) modulate this inflammation. We performed bilateral superior cervical ganglionectomy or decentralization of the SCG. Our results show that decentralization significantly reduced mortality (by 68%) after anaphylaxis. Furthermore, the increases in levels of serum-derived proteins, histamine, and influx of cells (especially neutrophils) observed in BALF after anaphylaxis were attenuated by both decentralization and ganglionectomy. By contrast, hemodynamic parameters in the respiratory tract and the presence of neutrophil chemotactic activity in BALF were not influenced by decentralization. Thus, the severity of pulmonary inflammation initiated by systemic anaphylaxis is depressed by bilateral ganglionectomy or decentralization of SCG.

Pancreatobiliary afferent recordings in the anaesthetised Australian possum.

The sensory innervation to the pancreatobiliary system is poorly characterized. Afferent signals from the gastrointestinal tract and biliary tree are transmitted to the central nervous system via the vagus and spinal nerves. We aimed to record afferent discharge in order to characterize the vagal and splanchnic afferent signals from the possum upper gastrointestinal tract, biliary tree and pancreas. In 21 anaesthetised possums nerve fibres were teased from the vagus or splanchnic nerve for multi-unit recording. Mechanical stimuli consisted of balloon distension of the gallbladder and duodenum (2-7 ml) and fluid distension (0-20 mm Hg) of the bile or pancreatic ducts. Approximately 60% of fibres from all nerves displayed spontaneous discharge. Spinal afferent responses to mechanical stimuli were infrequent (n=13). Increased discharge occurred in response to duodenal (12/99 fibres) or gallbladder (7/96 fibres) distension, but not to bile duct (0/73 fibres) or pancreatic duct (0/51 fibres) distension. Vagal afferent responses to distension of the duodenum or stomach (5-30 ml) were more common (n=8). Increased discharge was recorded in response to duodenal (49/134 fibres), or gastric (22/70 fibres) distension. Responses to gallbladder distension were less frequent (6/99 fibres) and as with the spinal afferent no response to bile duct (0/66) or pancreatic duct (0/70) distension were recorded. We conclude that mechanosensitive afferents in the pancreatobiliary system are relatively rare, particularly within the ducts, and/or that they are adapted to monitor stimuli other than luminal distension.

Intracellular pH influences the resting membrane potential of isolated rat hepatocytes.

This study in isolated rat hepatocytes sought to determine if the changes in membrane potential associated with intracellular alkalinization or acidification could be attributed to changes in K+ conductance. Intracellular pHi was manipulated using the 'NH4+-pulse' method: inducing intracellular alkalinization with NH4Cl (10 mM), and producing acidification by diluting the NH4+-loaded cells with ammonium ion-free buffer or by adding sodium proprionate. Membrane potential and resistance were measured in freshly isolated rat liver cells using intracellular microelectrodes. The results indicated that intracellular alkalinization was associated with hyperpolarization and decreased membrane resistance, whereas intracellular acidification caused depolarization with increased membrane resistance. As pHi-mediated electrogenic responses have been related to changes in K+ conductance in other epithelial tissues, the influence of K+ transport inhibitors on NH4+-evoked electrical effects was examined. NH4Cl-evoked membrane potential changes were inhibited by the K+ channel blockers, quinine and barium and in potassium depolarized cells (cells bathed in a high K+ medium where [K+]in = [K+]out = 140 mM). Furthermore, Rubidium-86 (86Rb+) efflux from preloaded hepatocytes, a measure of K+ permeability, was enhanced following intracellular alkalinization but inhibited by intracellular acidification. Thus, these results indicate that pHi-evoked electrogenic effects in hepatocytes are mediated through changes in K+ conductance.

Sodium-dependent taurocholate uptake by isolated rat hepatocytes occurs through an electrogenic mechanism.

The uptake mechanism for the bile salt, taurocholate, by the liver cell is coupled to sodium but the stoichiometry is controversial. A one-to-one coupling ratio would result in electroneutral transport, whereas cotransport of more than one sodium ion with each taurocholate molecule cause an electrogenic response. To better define the uptake of this bile salt, we measured the effect of taurocholate on the membrane potential and resistance of isolated rat hepatocytes using conventional microelectrode electrophysiology. The addition of 20 microM taurocholate caused transient but significant depolarization accompanied by a significant decrease in membrane resistance. The electrical effect induced by taurocholate mimicked that induced by L-alanine (10 mM), the uptake of which is known to occur through an electrogenic, sodium-coupled mechanism. The sodium dependence of taurocholate-induced depolarization was further confirmed by: (1) replacing Na+ with choline +, and (2) preincubating cells with ouabain (2 mM) or with the Na+-ionophore, gramicidin (25 micrograms/ml); both suppressed the electrogenic response. Further, cholic acid, which inhibits sodium-coupled taurocholate uptake in hepatocytes, inhibited taurocholate evoked depolarization. These results support the hypothesis that sodium-coupled taurocholate uptake by isolated hepatocytes occurs through an electrogenic process which transports more than one Na+ with each taurocholate molecule.

Review article: endocannabinoids and their receptors in the enteric nervous system.

The therapeutic actions of cannabinoids have been known for centuries. In the last 25 years this area of research has grown exponentially with the discovery of specific cannabinoid receptors and endogenous ligands. In the enteric nervous system of gastrointestinal tract, cannabinoid receptors are located on enteric nerve terminals where they exert inhibitory actions on neurotransmission to reduce motility and secretion. Endogenous cannabinoids are present in the enteric nervous system, as are the degradative enzymes necessary to inhibit their action. The cellular mechanism of action of endocannabinoids has not been established in the enteric nervous system. Endocannabinoids not only act at cannabinoid receptors, but potentially also at vanilloid and 5-HT3 receptors, both of which are expressed in the gastrointestinal tract. The interactions between endocannabinoids and these other important receptor systems have not been extensively investigated. A greater understanding of the endocannabinoid system in the enteric nervous system could lead to advances with important therapeutic potential in the treatment of gastrointestinal disorders such as irritable bowel syndrome, inflammatory bowel disease, secretory diarrhoea and gastro-oesophageal reflux disease.

Inhibition of neutrophil chemotaxis and activation following decentralization of the superior cervical ganglia.

Recent studies have shown that bilateral decentralization (sympathectomy) of the superior cervical ganglia (SCG) of rats sensitized to the parasite Nippostrongylus brasiliensis attenuated the development of pulmonary inflammation following allergen challenge. Sympathectomy inhibited total leukocyte infiltration into lung lavage fluids, particularly neutrophil infiltration. To define the effects of decentralization of the SCG on neutrophil responses, peripheral blood neutrophils of rats were isolated and tested in in vitro chemotaxis and phagocytosis assays. Neutrophils from rats that were sympathectomized 7 days previously displayed a marked reduction in chemotaxis to N-formyl-methionyl-leucyl-phenylalanine and leukotriene B4 compared to neutrophils from sham-operated or unoperated groups. Although the degree of chemotaxis was greater in blood neutrophils from parasite-infected rats than from uninfected rats, sympathectomy markedly reduced the chemotactic responses of both groups. In addition, neutrophils of sympathectomized rats were unresponsive to lipopolysaccharide-induced metabolic activation as assessed by in vitro phagocytosis and oxidative reduction of nitroblue tetrazolium. Thus, decentralization of the SCG of rats affects the chemotactic responses and functions of neutrophils. Understanding the role of the sympathetic nervous system in modulating the behavior of neutrophils will shed light on the interactions between the nervous and immune systems.

Platelet activating factor and systemic anaphylaxis in Nippostrongylus brasiliensis-sensitized rats: differential effects of PAF antagonists.

1. The effects of two platelet-activating factor (PAF) antagonists, WEB 2086 and BN 52021, in reducing the changes in extravasation (Evans blue technique) and blood flow (radiolabelled microsphere method) to various organs and tissues following anaphylactic shock in the Nippostrongylus brasiliensis-sensitized rat were investigated. 2. Both antagonists attenuated anaphylaxis-induced increases in plasma protein leak in the trachea, stomach and small intestine, although they did not block extravasation in the colon and kidneys. 3. Anaphylaxis-induced decreases in blood flow to the adrenals were effectively antagonized by WEB 2086, although this antagonist did not reverse blood flow decreases to any other tissues. BN 52021, on the other hand, did not alter anaphylaxis-induced decreases in blood flow to the adrenals, but effectively prevented dramatic decreases in blood flow to the large and small bowel and spleen. 4. Anaphylactic shock produced marked reduction in blood pressure that was partly reversed by WEB 2086, whereas BN 52021 effectively blocked the decreases in cardiac output. 5. Thus, PAF is responsible for some of the haemodynamic and extravasation of protein changes associated with systemic anaphylaxis in the rat, although the differential inhibition observed with the two antagonists suggests that PAF alters vascular responsiveness through different mechanisms in selected tissues.

The effects of atropine and secoverine on gastric secretion and motility in the mouse isolated stomach.

The isolated perfused stomach of the mouse was used to study the effect of atropine and secoverine on bethanechol-induced gastric acid secretion and gastric motility. Both atropine and secoverine inhibited cholinergically induced gastric acid secretion and gastric motility. Inhibition of gastric acid secretion by atropine and secoverine occurred at a similar dose-range (10(-9) and 2 X 10(-9) M). Secoverine inhibited bethanechol-induced hypermotility at doses (10(-11) M and above) that were lower than those of atropine (2 X 10(-9) M and above) required to produce this effect. Secoverine, unlike atropine markedly inhibited gastric motility at lower doses than those which affected secretion.

Alterations in regional blood flow in rats following sensitization to the nematode Nippostrongylus brasiliensis: effects of PAF antagonists.

1. Changes in tissue and organ blood flow associated with sensitization of rats to the nematode parasite, Nippostrongylus brasiliensis, were studied 30 to 35 days after infection, a time when very few worms remain in the animal. 2. Neither active nor passive sensitization modified heart rate, mean arterial blood pressure, cardiac output or total peripheral resistance. Passive sensitization and administration of non-immune sera did not modify blood flow to any of the tissues studied. 3. Active sensitization increased hepatic arterial blood flow, but decreased blood flow to the stomach, duodenum, jejunum and the submandibular glands. These effects cannot be attributed to residual nematode infections as treatment with the anthelmintic, thiabendazole, did not alter blood flow relative to untreated, actively sensitized rats. 4. The effects of active sensitization on blood flow were probably due to an action of platelet-activating factor (PAF) since treatment of actively sensitized animals with the selective antagonists, WEB-2086 and BN 52021, reversed the decrease in flow seen to the intestinal regions. The PAF antagonists increased blood flow to the kidneys and the trachea of sensitized animals. 5. These results suggest that the PAF released from undetermined sources in nematode-sensitized rats, produces altered blood flow, primarily to the stomach and proximal small bowel.

Capsaicin-sensitive vagal stimulation-induced gastric acid secretion in the rat: evidence for cholinergic vagal afferents.

1. The effects of electrical vagal stimulation on frequency-dependent gastric acid secretion were investigated in urethane-anaesthetized rats in vivo. 2. Stimulation at 4, 16 or 32 Hz was performed in rats treated with atropine (1 mg kg-1, i.v.), hexamethonium (10 mg kg-1, i.v. bolus and 1 mg kg-1 min-1, i.v. infusion) or atropine and hexamethonium (doses as above); in some experiments pentagastrin (1.2 micrograms kg-1 h-1, i.v. infusion) was infused prior to stimulation. 3. Maximal acid secretion occurred at 16 Hz. This was significantly reduced but not abolished by atropine or hexamethonium and completely abolished after atropine and hexamethonium. In the presence of pentagastrin, the acid secretory response to 16 Hz stimulation was augmented, atropine or hexamethonium reduced stimulated secretion by about 70%, whereas atropine and hexamethonium completely abolished stimulated secretion. 4. In rats in which the vagus nerve was pretreated with capsaicin 10-14 days before experimentation there was a significant reduction (by about 40%) in stimulated acid secretion at 16 Hz, which was virtually abolished by atropine treatment. After acute treatment of the vagus nerve with capsaicin (at the time of experimentation) maximally stimulated acid secretion was significantly reduced by about 50%. 5. Taken together, these results indicate that capsaicin-sensitive afferent fibres contribute to the acid secretory response induced by electrical vagal stimulation in the rat. Based on pharmacological evidence, the capsaicin-sensitive afferent fibres may be cholinergic, since atropine and hexamethonium totally abolish vagal stimulation-induced acid secretion.

Salivary glands, their hormones, and thermoregulation.

The effects of the removal of the submandibular glands (sialadenectomy) on the fever induced by bacterial lipopolysaccharide (LPS) were examined. Thermally sensitive radiotransmitters were implanted into the abdomens of adult male Sprague-Dawley rats that experienced at this time either a sham operation or a sialadenectomy, and one week later body temperatures were recorded by telemetry in these rats when conscious. The initial fever (up to 180 min following LPS) response, following the intraperitoneal injection of 150 micrograms/kg E. coli LPS, was similar in the two groups of rats, but the second phase of the fever (240 to 420 min post-LPS) was modestly, but significantly higher (mean = 0.26 degree C) in sialadenectomized rats. A submandibular gland peptide (compound T; 100 micrograms/kg), given one-half hour before the LPS, did not affect the early fever, but suppressed the late-phase fever by 0.37 degree C (mean). The submandibular glands, which form an integral part of the neuroendocrine mechanisms responsible for attenuating the responses of the immune system to inflammatory stimuli, also appear to modulate thermogenic responses to these stimuli.

Inhibition of breathing associated with gallbladder stimulation in dogs.

The effect of mechanical stimulation of the gallbladder on breathing was studied in anesthetized spontaneously breathing dogs. Measurements of tidal volume, breathing frequency, rib cage and abdominal diameter, transdiaphragmatic pressure, and electrical activity of the diaphragm were made while traction or compression was applied to the gallbladder for periods of 30 s. Both forms of mechanical stimulation produced similar changes, including large decreases in tidal volume, respiratory rate, electrical activity of the diaphragm, and transdiaphragmatic pressure swings. Inspiratory rib cage expansion was little affected, but abdominal expansion was greatly reduced, and swings in gastric pressure were reduced more than swings in pleural pressure, indicating a selective decrease in diaphragmatic activity. Recovery of all measured parameters returned toward control values, despite continued traction or compression. Some inhibition persisted after the stimulus was withdrawn. The very brief interval between stimulus and response suggested that the mechanism was a neural reflex. The afferents involved are unknown but are not purely vagal in nature, since qualitatively similar results were seen in animals after vagotomy. The alteration in breathing frequency indicates that at least part of the reflex is supraspinally mediated. The change in pattern of breathing closely resembles that seen in subjects after abdominal surgery and supports the theory that reflex inhibition of breathing contributes to postoperative pulmonary complications seen in those subjects.

Attenuation of intestinal and cardiovascular anaphylaxis by the salivary gland tripeptide FEG and its D-isomeric analog feG.

The effects of the submandibular gland peptide-T (SGP-T; Thr-Asp-Ile-Phe-Gly-Gly; TDIFEGG), its carboxy-terminal fragment (the tripeptide FEG; Phe-Glu-Gly), and the D-isomeric analog (feG) on intestinal and cardiovascular anaphylactic reactions were studied. The tripeptides, FEG and feG, when administered intravenously or orally to egg albumin-sensitized Hooded Lister or Sprague-Dawley rats 30 min prior to challenge with the antigen, totally prevented the disruption of intestinal motility and the development of anaphylaxis provoked diarrhea and inhibited anaphylactic hypotension by 66%. Submandibular gland peptides participate in the regulation of systemic inflammatory reactions, and the D-amino acid tripeptide, feG, is a potent, orally active anti-anaphylactic agent.

Neuropeptide Y, peptide YY, and pancreatic polypeptide modulate duodenal and colonic motility at a thoracic spinal site in rats.

Neuropeptide Y, PYY, and PP (200 pmol) alter intraluminal pressure in the duodenum and colon of rats following their administration into the thoracic (T8-T10) region of the spinal cord. Neuropeptide Y decreases the tone of the duodenum and the colon following intrathecal (T8-T10) administration prior to an increase in tone to baseline or greater. There is no effect on intraluminal pressure of either the duodenum or the colon following intrathecal administration of NPY or PP into the lumbar (L4-L5) region of the spinal cord. Following intrathecal (T8-T10) administration of PYY and PP, increases in intraduodenal pressures are observed (+2.1 and +3.0 mmHg from saline baseline). Phasic contractions of the duodenum are increased following intrathecal administration of PYY into the thoracic spinal cord of rats. Neuropeptide Y, PYY, and PP increase intracolonic pressure +2.2, +3.3, and +3.7 mmHg from saline baseline, respectively. Phasic contractions of the colon are increased following PP intrathecal thoracic administration. Responsiveness of the duodenum or colon to the different ligands of the PP-fold peptide family in the absence of alpha-adrenergic blockade did not vary. The increases in intraluminal pressure of the duodenum and colon following intrathecal administration of the PP-fold peptides are attenuated by both alpha-1 adrenergic (prazosin) and alpha-2 adrenergic (yohimbine) blockade. There is a difference in responsiveness of the colon between the ligands of the PP-fold family in the presence of the alpha-2 adrenergic blockade. The findings of this study indicate that duodenal and colonic motility are modulated by the PP-fold peptides at thoracic spinal sites via alteration of sympathetic outflow.

Spinal and peripheral modulation of gastric acid secretion and arterial pressure by neuropeptide Y, peptide YY, and pancreatic polypeptide in rats.

Spinal and peripheral modulation of pentagastrin-stimulated gastric acid secretion by the pancreatic polypeptide-fold (PP-fold) peptides, neuropeptide Y (NPY), peptide YY (PYY), and pancreatic polypeptide (PP), in urethane-anesthetized rats was evaluated. Neuropeptide Y, PYY, and PP (400 pmol) were administered via intravenous (IV) and intrathecal (IT) injections. The alpha 2 antagonist, yohimbine, was used to evaluate the role of the alpha 2 adrenergic receptors in the modulation of pentagastrin-stimulated gastric acid secretion by NPY, PYY, and PP. Peptide YY and PP (IV) rapidly increased pentagastrin-stimulated gastric acid secretion. Peptide YY and PP (IT) increased pentagastrin-stimulated gastric acid secretion following administration into the thoracic (T8-T10) region of the spinal cord. The alpha 2 adrenergic receptor antagonist, yohimbine, did not modify the increases in pentagastrin-stimulated gastric acid secretion following PYY and PP (IV or IT) administration. Neuropeptide Y (IT) decreased pentagastrin-stimulated gastric acid secretion. However, in the presence of alpha 2 adrenergic receptor blockade, pentagastrin-stimulated gastric acid secretion was potentiated by NPY (IT) administration. Therefore, the inhibitory effect of NPY (IT) on pentagastrin-stimulated gastric acid secretion required the activation of alpha 2 adrenergic receptors in the spinal cord of rats. Mean arterial blood pressure (MAP) was increased immediately following NPY and PYY (IV) administration. During the same time period, PP (IV) decreased MAP in anesthetized rats. Mean arterial blood pressure was rapidly increased by NPY and PYY (IT) in anesthetized rats. The increase in MAP following PYY (IT) was partially attenuated in the presence of yohimbine.(ABSTRACT TRUNCATED AT 250 WORDS)

The peripheral modulation of duodenal and colonic motility in rats by the pancreatic polypeptide-fold family: neuropeptide Y, peptide YY, and pancreatic polypeptide.

Neuropeptide Y (NPY), peptide YY (PYY), and pancreatic polypeptide (PP) altered intraluminal pressure in the duodenum and colon of fasted anesthetized rats following intravenous bolus administration. There were rapid increases in intraluminal pressure of the duodenum and colon of anesthetized rats following peripheral injections of NPY, PYY and PP. Administration (IV) of NPY, PYY, and PP increased intraduodenal pressure +1.8, +3.2, and +3.7 mmHg compared to saline baseline. Prazosin, an alpha-2 adrenergic antagonist, did not alter the response of the duodenum of urethane-anesthesized rats to any of the PP-fold peptides following peripheral administration. Yohimbine, an alpha 2-adrenergic antagonist, attenuated the excitatory response of rat duodenum following NPY (IV) but did not alter the duodenal response to PP (IV). Intravenous NPY, PYY, and PP increased intracolonic pressure +2.0, +3.3, and +6.2 mmHg compared to saline baseline. In the presence of prazosin, an alpha 1-adrenergic antagonist, the intraluminal pressure of the colon increased +2.6, +2.4, and +8.1 mmHg compared to saline baseline by NPY, PYY, and PP (IV), respectively. In the presence of alpha 2-adrenergic blockade by yohimbine, NPY, PYY, and PP (IV) increased intraluminal pressure of the colon +4.2, +2.9, and +2.5 mmHg compared to saline baseline. The response of the duodenum to the excitatory effect of PYY (IV) was enhanced in the presence of yohimbine. Duodenal and colonic tone were modulated by the PP-fold peptides following peripheral administration. The alpha-adrenergic nervous system played only a minor role in the modulation of GI motility by the PP-fold peptides at peripheral sites.

The cholecystokinin antagonist, proglumide, increases food intake in the rat.

Cholecystokinin, secreted in response to ingested food entering the duodenum, may play a role in limiting food intake. Inhibition of cholecystokinin should therefore induce an increase in food intake. Proglumide, a specific antagonist of cholecystokinin was used to block the satiety effect of a food preload in rats. A significant increase in food intake was obtained following proglumide injection, thus supporting the hypothesis that cholecystokinin, released by food in the duodenum, acts as a short-term satiety factor.

The effect of vagotomy on the increase in food intake induced by the cholecystokinin antagonist, proglumide.

Cholecystokinin, secreted when ingested food enters the duodenum, may act as a satiety factor. Injection of proglumide, a specific antagonist of cholecystokinin, induced an increase in food intake. The satiety effect of administered cholecystokinin is abolished by bilateral subdiaphragmatic vagotomy. If endogenous and exogenous cholecystokinin act via the same mechanism, then vagotomy should abolish the proglumide-induced increase in food intake. Proglumide was used to block the satiety effect of a food preload in sham-operated and vagotomized rats. Proglumide induced an increase in food intake in sham-operated rats confirming earlier results. No change in meal size was observed in vagotomized rats following proglumide injection. These results suggest that vagotomy abolishes the effect of endogenous cholecystokinin on food intake. However, evidence of dumping in vagotomized rats prevents the interpretation of the data as a direct vagal involvement in endogenous CCK-induced satiety.

Evidence for substance P as a functional neurotransmitter in guinea pig small intestinal mucosa.

We showed previously that electrical transmural stimulation (TS) of guinea pig jejunal mucosa in vitro released neurotransmitters from submucosal plexus neurons which caused alterations in ion transport. The present studies were performed to obtain information regarding the identity of the neurotransmitters. The addition of exogenous substance P (SP) to the serosal side of the tissue caused a transient increase in short-circuit current (Isc) which closely mimicked the response to TS. Both TS and SP caused net secretion of Cl- ions by stimulating movement toward the luminal side. Tetrodotoxin abolished the response to TS, inhibited approximately 70% of the response to SP but did not affect the response to urecholine, a cholinergic muscarinic agonist. In the presence of the muscarinic antagonist, atropine, Isc responses to both TS and SP were reduced suggesting that a portion of both responses was due to action on enteric nerves causing release of acetylcholine. Following desensitization of the tissue with supramaximal doses of SP the response to TS was significantly reduced but the response to urecholine was unchanged. In the presence of atropine, SP desensitization reduced the nerve-stimulated response by approximately 65%; treatment of tissue with SP antibodies reduced the response by approximately 55%. Under the same conditions Isc responses to histamine were unaltered. Our results suggest that both SP (or a structurally analogous neurotransmitter) and acetylcholine as well as additional unidentified neurotransmitter(s) are functionally important in the regulation of intestinal ion transport in guinea pig jejunum.

The source of calcium for CCK-induced contraction of the guinea-pig gall bladder.

The sources of calcium for cholecystokinin octapeptide (CCK-OP)-induced gallbladder smooth muscle contraction are considered both extracellular and intracellular, but the relative need for intracellular calcium especially at low, physiological concentrations is not clear. To better define the calcium sources responsible for guinea-pig gallbladder contractions in vitro, we inhibited calcium influx using the calcium channel blocker, methoxyverapamil, and a calcium-free Krebs' solution. Availability and release of intracellular calcium stores were depleted by strontium substitution and ryanodine. CCK-OP was compared to bethanechol and potassium chloride (KCl). Preventing calcium influx with 10(-5) M methoxyverapamil depressed the responses to CCK-OP, bethanechol and KCl. Methoxyverapamil, however, had little effect on the time-dependent generation of tension to CCK-OP, but significantly reduced the response to bethanechol and KCl, each at ED50. The duration of the contractile response in the calcium-free Krebs' solution to CCK-OP was longer than that for bethanechol. Strontium (2.5 mM) significantly attenuated the response to CCK-OP and bethanechol, but not to KCl. Ryanodine significantly reduced contractions induced by CCK-OP but not for bethanechol, both at low dose ED25. These results indicate that contraction of the guinea-pig gallbladder induced by CCK-OP, bethanechol and KCl requires extracellular calcium influx. Further, the initiation and maintenance of contraction by CCK-OP and bethanechol necessitates calcium mobilisation from intracellular stores. CCK-OP may have a greater penchant for these calcium stores, particularly at physiological doses.