Contractile activity of duodenum, jejunum, and ileum at psychogenic stress in rabbits before and after muscarinic or nicotinic cholinoceptor blockade

In chronic experiments on rabbits, myoelectric activity (contractile activity index) in distal part of the duodenum, proximal and distal parts of the jejunum and proximal part of the ileum was studied under psychogenic stress caused by rigid fastening rabbit to a table in supine position. In duodenum, the stressor impact rendered stimulating, and in an ileum--inhibitory influence on their motility. In a jejunum the inhibition with the subsequent stimulation was observed, the latter being more expressed in a proximal part of the intestine. The proximo-distal gradient of exitatory and inhibitory influences of the psychogenic stress on contractile activity of the small bowel was revealed: in distal direction, inhibitory influences strengthen and stimulatory ones weaken. The muscarinic receptor blockade abolished increase of the duodenal and jejunal contractile activity obsereved in the control. The nicotinic cholinoceptor blockade abolished increase of the duodenal contractile activity in the 1-st phase of the stressor response and did not exclude an increase of the duodenal contractile activity in the 2-nd phase of the response. Muscarinic or nicotinic blockade did not influence the manifestation of the inhibitory reaction of proximal part of the ileum. In the period after release of the animal, the duodenal and jejunal contractile activity exeeded its initial level. This exeeding did not preserve after muscarinic cholinoceptor blockade but did preserve after nicotinic one in duodenum and proximal jejunum. The received data allow to conclude, that produced by the stress increase of the contractile activity of the distal part of duodenum, proximal and distal parts of jejunum produced by the stress, as well as exceeding the initial contractile activity level in the period after release of an animal, are mediated by cholinergic effector neurones of the enteric nervous system.     

The mechanism of the duodenal motility strengthening under psychogenic stress in rabbits

In experiments on unanaesthetized rabbits, myoelectric activity (contractile activity index) of two sites of duodenum and of antral and pyloric parts of the stomach was studied under stress induced by fastening a rabbit to a table in supine position. In both sites of duodenum, the stress impact induced a short-time inhibition of contractile activity which was followed by its strengthening that exceeded the initial level. Meanwhile in antrum and pylorus, the whole period of stress impact was characterized by suppression of contractile activity, the latter being more pronounced in the antrum. The strengthening of the duodenal contractile activity was preserved after muscarinic ornicotinic cholinoceptor blockade. It was concluded that the contractile response of duodenum seemed to be of humoral origin.     

Mechanisms of inhibition of the contractile activity in the ileo-caecal zone in rabbits under psychogenic stress

In experiments on unanaesthetized rabbits, myoelectric activity (contractile activity index) of distal ileum, caecum, and proximal colon in two sites was studied under stress induced by fastening a rabbit to the table in supine position. The stress caused sharp decrease (up to complete disappearance) of the contractile activity in all studied compartments of the ileocaecal intestine with partial or complete restoration after release of the animal. Nonselective blockade of pre- and postsynaptic alpha-adrenoceptor with dihydroergotoxin abolished the initial component of the specified inhibitory response. The latter was caused by "adrenergic inhibition" as a result of action of catecholamines circulating in blood on inhibitory smooth muscle alpha-adrenoceptor. Against the background of muscarinic cholinoceptor blockade, the stressor inhibition of ileocaecal contractile activity observed in control experiments was completely preserved. The periods of supression of ileoceacal contractile activity under stress resistant to blockade of alpha-, beta-adrenoceptor and muscarinic cholinoceptor, are caused by the mechanism of "nonadrenergic noncholinergic inhibition", which is realized at the expence of activation of the enteric inhibitory neurones.     

Changes of contractile activity of the colon under psychogenic stress before and after blockade of M- and N-cholinergic and beta-adrenoceptors

In experiments on conscious rabbits, myoelectric activity (contractile activity index) was recorded in 2 sites of proximal and in 2 sites of distal part of the colon under psychogenic stress induced by firm fastening of the animal to a frame in supine position. Stressor impact caused decrease of the contractile activity in proximal and distal parts of the colon, due to "alpha-adrenergic" (in initial stage of stress reaction) and "nonadrenergic noncholinergic" inhibition. Stress-induced increase of the contractile activity of the colon was limited to the initial segment of its distal part, and was due to centrogenic stimulation of the preganglionic neurons of the parasympathetic nervous system and effector cholinergic neurons of the enteric nervous system.     

Excitatory beta-adrenoreceptors on enteral cholinergic interneurons of the large intestine and ileocecal sphincter]

Acute experiments were performed on the isolated intestinal loop, vascularly perfused with arterial blood by means of the constant flow perfusion pump. Contractile activity of the ileocecal sphincter and proximal parts of the large intestine was estimated by the maximal isometric tension and total (integrated) contractile activity. Isoprenaline (1-2 mg) induced contractile responses of the colonic segment and ileocecal sphincter. These responses were abolished or dramatically diminished by the blockade of beta-adrenoceptors, muscarinic, and nicotinic cholinergic receptors. Data obtained support the idea, that the large intestine and ileocecal sphincter have excitatory beta-adrenoceptors localized on cholinergic interneurones of the enteric nervous system.     

On the mechanism of gastroduodenal motility inhibition under psychogenic stress in rabbits

In experiments on unanaesthetized rabbits, myoelectric activity (contractile activity index) in antral and pyloric parts of the stomach and in two sites of proximal duodenum was studied under stress induced by fastening rabbit to a table in supine position. The stressor impact induced inhibition of contractile activity in antrum and pylorus. The duodenal contractile activity after initial complete suppression overshot its initial level. Blockade of beta1/beta2-adrenoceptor with propranolol and blockade of alpha2-adrenoceptor with yohimbine did not influence qualitatively the pattern of the stressor responses of antrum and pylorus, and of the postpyloric part of duodenum. In conditions of unselective blockade of alpha-adrenoceptor with dihydroergotoxin there was no initial complete inhibition of duodenal contractile activity, and its strengthening was more expressed than in the control experiments. The received data indicate that the stressor inhibition of antral and pyloric contractile activity possibly results from activation of non-adrenergic inhibitory neurons of the enteric nervous system. The initial short-term suppression of duodenal motility resulted from its "adrenergic" inhibition which can also be a factor limiting the manifestation of stimulating effect of the humoral agent on the duodenal motility. In the period after release of the animal, index of antral and pyloric contractile activity did not significantly differ from its initial level; after beta1/beta2-adrenoceptor blockade in antral and after alpha2-adrenoceptor blockade or nonselective alpha-blockade in antral and pyloric parts of the stomach, there was decrease of contractile activity compared with its initial level; after alpha2- or beta1/beta2-adrenoceptor blockade there was no poststressor exceeding of the initial level of the duodenal contractile activity, observed in the control experiments.     

Non-adrenergic mechanisms of inhibition of the contractile activity of the cat small intestine by histamine, bradykinin, and met-enkephalin

I. a. histamine and bradykinin caused both an activation and an inhibition of jejunal contractile activity. The inhibitory effect was preserved after blockade of muscarinic cholinoreceptors, alpha- and beta-adrenoceptors, and abolished with the nicotinic cholinoceptor blockade. Metenkephalin inhibited the jejunal contractile activity after first activating it. The inhibitory effect of the peptide was preserved after blockade of alpha- and beta-adrenoceptors as well as the nicotinic cholinoceptors. The data obtained suggest that the non-adrenergic inhibitory effect of metenkephalin on intestinal contractions was the result of its depressing action on motor cholinergic neurons, whereas the inhibition of intestinal contractile activity with histamine and bradykinin resulted from their activating action on cholinergic interneurons which activate non-adrenergic inhibitory neurons through nicotinic cholinoceptors.     

Indirect stimulation by thyrotropin-releasing hormone of canine gallbladder motility

Thyrotropin-releasing hormone (TRH) was unable to induce any noticeable contraction of canine isolated gallbladder strips up to the dose of 10(-4) g/ml, while caerulein (CAER) was spasmogenic in a dose-related manner beyond 10(-11) g/ml. This effect of CAER was unaffected by either atropine or tetrodotoxin. In conscious dogs, the intravenous bolus of TRH (20 micrograms/kg) or CAER (0.2-2.0 micrograms/kg) caused gallbladder emptying. The TRH response, unlike that of an equipotent dose of CAER, was prevented by atropine. In experiments on electrical activity of the digestive tract in conscious dogs, both TRH or CAER induced a concomitant increase on the myoelectrical activity in the proximal part of the small intestine. The excitatory effects were prevented by atropine only in the case of TRH. These results demonstrate that TRH stimulates indirectly the gallbladder and proximal duodenum of the dog. They suggest the involvement of a cholinergic pathway in this excitatory action.     

Mechanism of the serotonin effect on motility of the duodenum,ileum, and jejunum in awake rabbits

I. v. administration of serotonin to alert rabbits produced a phasic change of contractile activity of duodenum, ileum, and jejunum including excitatory and inhibitory components. It is shown that stimulation of the small bowel motility is caused by serotonin activation of non-cholinergic excitatory mechanism with participation of effector cholinergic neurones. The initial suppression of the motility is caused by participation of nonadrenergic noncholinergic inhibitory mechanism, and the secondary inhibition of contractile activity of a small bowel with serotonin has an adrenergic nature.     

Modular and functionally-different descending recto-anal motor pathways in a rat model

We evaluated the motor responses in recto-anal preparations obtained from rats, in terms of the excitation displayed by modules of nerve networks and descending distally directed pathways, when subjected to the mechanographic on-line technique, a partitioned organ bath, electrical stimulation (EFS, 0.8 ms, 5 Hz) and distension. EFS elicited modular contractions, which increased in amplitude distally, in circular muscle rings isolated from the proximal, middle or distal rectum. The modular responses of the internal anal sphincter or anal canal were relaxation or contraction, respectively. The application of EFS to the distal rectum induced a descending contractile response in the anal canal (5.24±0.34 mN), while distension by balloon evoked a descending response consisting of contraction (1.72±0.20 mN) followed by relaxation (3.42±0.24 mN). The responses were sensitive to tetrodotoxin. Atropine considerably depressed the contractions in all preparations. Whether or not atropine was present, L-NNA increased the excitatory responses, while L-arginine decreased the contractions and extended the relaxation of internal anal sphincter and anal canal. The results suggest that excitatory neurotransmission(s) expressed in the distal rectum dominate modular nerve networks. Functionally-different descending pathways are involved in the motor activity of the anal canal. Stimulatory cholinergic pathways are dependent on the electrically-induced excitation, and inhibitory nitrergic pathways are sensitive to distension of rectal wall.     

Mechanism of action of neurotensin at the ileocecal sphincter region

Neurotensin, a neuropeptide identified in the distal small intestine, plays an unclear role in ileocecal sphincter regional function. The purpose of this study was to determine the effect and mechanism of action of neurotensin on the feline ileocecal sphincter (ICS), proximal colon, and distal ileum. Intraluminal pressures were recorded at these sites in anesthetized cats after superior mesenteric artery injection of neurotensin. Dose dependent tonic and phasic contractions were seen at all sites. Peak pressure responses were seen at the maximal dose used and were greater for the ICS than the distal ileum and the proximal colon. The threshold dose for peak pressures for neurotensin was 0.05 microgram/kg for all sites with the maximal peak pressures occurring at the maximal dose used (100 micrograms/kg). The motility index (MI [number of contractions x mean amplitude of contractions]) was determined for three minutes before and after neurotensin injection. The change in the motility index after neurotensin increased at doses above 0.05 micrograms/kg for the ileum and the ICS and 0.25 microgram/kg for the colon. Maximal responses for the motility index were seen at 1 microgram/kg for the distal ileum, and 10 micrograms/kg for the ICS and the proximal colon, with the greatest response seen at the ICS. Neurotensin-induced ICS relaxation was seen at 1 microgram/kg (50 +/- 10%, p less than 0.01) in 33% of cats. The contractile responses of the distal ileum and the proximal colon were not inhibited by naloxone, trimethaphan, tetrodotoxin, or atropine. The ICS contractile response was decreased by tetrodotoxin by 53%, p less than 0.05. The alpha 2 antagonist, yohimbine reduced the neurotensin induced ICS contraction from 31.6 +/- 3.4 to 21.9 +/- 3.3 mm Hg, p less than 0.05. Prazosin had no effect on neurotensin-induced contractions. In the presence of cimetidine and diphenhydramine, trimethaphan did not affect the neurotensin-induced contractile response at all three sites. However, neurotensin inhibited contractions induced by trimethaphan alone at all three sites. Conclusions: 1. Neurotensin causes a dose-dependent contractile response at the distal ileum, ICS, and proximal colon. 2. Neurotensin has an inhibitory effect at all three sites. 3. The contractile response at the distal ileum and the proximal colon is mediated via smooth muscle receptors. 4. The contractile response of neurotensin at the ICS is mediated partly via alpha 2 receptors and partly via smooth muscle receptors.     

Changes in muscarinic acetylcholine receptors in the isolated duodenum from repeatedly cold-stressed rats and the effect of neurotropin.

In rats repeatedly cold-stressed by specific alternation of rhythm in environmental temperature (SART-stressed rats), the contractile response to acetylcholine (ACh) of the isolated duodenum was remarkably decreased, whereas the contractile responses to K+, Ba2+ and Ca2+ were comparable to those in non-stressed rats. The amount of [3H]quinuclidinyl benzilate in the duodenum of SART-stressed rats was about 50% of that in non-stressed rats, but the KD value remained unchanged. Long-term administration of hexamethonium prevented the changes in SART-stressed rats. The daily treatment with Neurotropin, an extract isolated from inflamed rabbit dermis inoculated with vaccinia virus, dose-dependently prevented the changes in SART-stressed rats. However, Neurotropin had no effect on the ACh-induced decrease in muscarinic ACh receptor (m-ACh.R) in cultured vas deferens of guinea pig. These results suggest that down-regulation of m-ACh.R in duodenum by SART stress may be associated with enhanced activity in the parasympathetic center. Moreover, Neurotropin is thought to prevent the down-regulation of m-ACh.R throughout the central nervous system.     

Cloning and sequence analysis of the human brain beta-adrenergic receptor. Evolutionary relationship to rodent and avian beta-receptors and porcine muscarinic receptors

Two cDNA clones, lambda-CLFV-108 and lambda-CLFV-119, encoding for the beta-adrenergic receptor, have been isolated from a human brain stem cDNA library. One human genomic clone, LCV-517 (20 kb), was characterized by restriction mapping and partial sequencing. The human brain beta-receptor consists of 413 amino acids with a calculated Mr of 46480. The gene contains three potential glucocorticoid receptor-binding sites. The beta-receptor expressed in human brain was homology with rodent (88%) and avian (52%) beta-receptors and with porcine muscarinic cholinergic receptors (31%), supporting our proposal [(1984) Proc. Natl. Acad. Sci. USA 81, 272 276] that adrenergic and muscarinic cholinergic receptors are structurally related. This represents the first cloning of a neurotransmitter receptor gene from human brain.     

Neuronal and myogenic muscarinic effects of McN-A-343 on guinea pig longitudinal smooth muscle-myenteric plexus.

Among muscarinic agonists, the compound McN-A-343, originally proposed as selective stimulant of M1 cholinergic site, was subsequently questioned as a useful pharmacological tool in the classification of muscarinic receptors. In this work, evidence is presented for a dual response of McN-A-343 on longitudinal muscle-myenteric plexus preparation. On electrically-stimulated preparation, this agonist exhibited a pirenzepine-sensitive inhibition of the twitch contractions due to the involvement of neural M1-muscarinic receptor. On the other hand, a direct myogenic contractile action on the unstimulated tissue was observed using McN-A-343 in the same range of concentrations. This latter response, on the basis of the effects of muscarinic and non-muscarinic antagonists tested, seems to involve effectorial muscarinic sites with an unusual mechanism.     

Mechanisms of serotonin effect on motility of ileocaecal zone in alert rabbits

I.V. administration of serotonin (2 mg kg(-1)) to alert rabbits changed the ileal, caecal, and colon motility including excitatory and inhibitory components. Initial rise of contractile activity was quickly replaced by its diminishing followed by a longer enhancement of the motility, and then by the final, inhibitory, phase. Under blockade of beta1- and beta2-adrenoreceptors with propranolol inhibition of ileal and caecal contractile activity with serotonin was preserved, the effect of circulating catecholamines on beta-adrenoreceptors of smooth muscle cells seems to be excluded as a cause of the serotonin inhibitory effect. In conditions of blockade of pre- and postsynaptic alpha-adrenoreceptors with phentolamine, there was no significant diminishing of the contractile activity in the ileo-caecal zone below the initial level induced by serotonin in control experiments. Intensification of the ileo-caecal zone contractile activity under the effect of serotonin persisted in conditions of blockade of muscarinic cholinoreceptors and was proceeding with participation of non-cholinergic excitatory mechanism.     

The effects of different receptor blockers on the H-Phe-Ile-Tyr-His-Ser-Tyr-Lys-OH induced inhibition of extinction of active avoidance behaviour

H-Phe-Ile-Tyr-His-Ser-Tyr-Lys-OH after intracerebroventricular (icv.) administration inhibited the extinction of active avoidance behaviour for a short period. The dopamine receptor blocker haloperidol completely blocked this effect of the heptapeptide, while the muscarinic anticholinergic agent atropine only partly inhibited it. The alpha 1-receptor blocker phenoxybenzamine and the beta-receptor blocker propranolol did not significantly influence the extinction inhibition induced by the peptide. These results suggest that the dopaminergic and, in part the cholinergic system, play important roles in this behavioural action of H-Phe-Ile-Tyr-Ser-Tyr-Lys-OH.     

Opioid-induction of migrating motor activity in chickens.

Enkephalin and morphine initiation of phase III of MMC has been reported in dog and humans. In chickens, a similar migrating activity initiated at the duodenum occurs 7-9 times a day while the gastric activity ceases. The main objective was to determine whether this migrating activity could be induced by opioids. Electrodes for electromyography were implanted in the stomach, proximal and distal duodenum, jejunum and proximal and distal ileum of 4 wk old chickens. Met-enkephalin, morphine and beta-casomorphin-5 (5 x 10(-7) moles/Kg) were infused i.v.. All these substances initiated an intestinal migrating activity concurrent with gastric inhibition. The mean duration of gastric inhibition depended on the substance, lasting from 5 min (met-enkephalin) to 27 min (beta-casomorphin-5). The migrating activity started in the distal duodenum and propagated to the ileum in about 18 min. These effects were partially blocked by naloxone at equimolar doses. In conclusion, in chickens, as in dogs and humans, migrating myoelectrical activity can be initiated by opioids.     

Increase in muscarinic receptors in rat intestine by thyrotropin releasing hormone (TRH)

The effect of Thyrotropin Releasing Hormone (TRH) on the contractile activity elicited by acetylcholine and electric stimulation in the rat ileus terminalis was investigated. TRH did not show any intrinsic contractile activity but, after a 30 minute latency period, the peptide caused a shift to the left of the dose-response curve for both acetylcholine and electric stimulation. The binding of 3H-quinuclidinylbenzilate (3H-QNB) assayed on ileum slices disclosed that the addition of TRH increased the number of muscarinic cholinergic receptors without changes in affinity when incubation was performed at pH 7.8, but no effect TRH was demonstrated at pH 7.4. Therefore, in spite of its neural and direct actions on intestine motor activity, TRH may affect the acetylcholine induced contraction by increasing the number of muscarinic receptors at a specific pH.     

Motor effects of gastrin releasing peptide (GRP) and bombesin in the canine stomach and small intestine

Close intraarterial injections of synthetic porcine gastrin releasing peptide (GRP) or bombesin stimulated contractions in the stomach and inhibited ongoing contractile activity in the small intestine of anaesthetized dogs. Contractile activity of the circular muscle was recorded by serosal strain gauges and phasic activity when desired was elicited by local field stimulation or intraarterial motilin injections. In the stomach (corpus and antrum) following tetrodotoxin blockade of field-stimulated contractions, the contractile response to either peptide was not present, suggesting that stimulation of receptors on nerves initiated contractions in the stomach. Similarly, in the small intestine, the inhibitory response was eliminated by tetrodotoxin suggesting a neural receptor. Pre-treatment with reserpine did not alter the inhibitory response, either in the presence or absence of atropine, therefore, adrenergic inhibitory mechanisms did not appear to be involved. The concentration of bombesin producing 50% inhibition of field stimulation (ED50) was increased following treatment with the putative M1 muscarinic antagonist, pirenzipine suggesting activation of M1 cholinergic inhibitory receptors by bombesin. After blockade by atropine of field-stimulated contractions and the contractile response to intraarterial acetylcholine, the ED50 for bombesin inhibition of motilin contractions was increased. After muscarinic blockade, the residual inhibitory response of GRP/bombesin may involve activation of a neural non-cholinergic non-adrenergic inhibitory mechanism. These results suggest that GRP and bombesin act to alter motility in the dog in vivo by affecting neural activity.     

5-Hydroxytryptamine involvement in the intrinsic control of oesophageal EMG activity

The effects and the sites of action of 5-Hydroxytryptamine (5HT) were examined in transverse muscular strips of pigeon oesophagus. 5-Hydroxytryptamine (0.001 to 30 microM) induced a concentration-dependent excitatory effect on the EMG activity. This response was mainly characterized by an increase in burst frequency. The maximum 5-HT-induced excitatory effect was not altered by methysergide (10 microM), but was abolished by tetrodotoxin (3 microM). Excitatory response to 5-HT was partly opposed by atropine (1 microM), potentiated by 5-methoxy-N, N-dimethyltryptamine (1 microM) and was not altered by guanethidine (10 microM). These results indicate that 5-HT activates the pigeon oesophagus indirectly via neural elements and has no direct action on the smooth muscle cells. 5-HT is thought to stimulate three different intramural neuron types: excitatory cholinergic neurons, excitatory non-cholinergic neurons and inhibitory non-cholinergic non-adrenergic neurons. The action on these different neurons seems to be mediated via different receptors.