Identification and immunohistochemistry of cholinergic and non-cholinergic circular muscle motor neurons in the guinea-pig small intestine

Projections of chemically identified myenteric neurons of the small and large intestine of the mouse

The projections of different subpopulations of myenteric neurons in the mouse small and large intestine were examined by combining immunohistological techniques with myotomy and myectomy operations. The myotomies were used to examine the polarity of neurons projecting within the myenteric plexus and showed that neurons containing immunoreactivity for nitric oxide synthase (NOS), vasoactive intestinal peptide (VIP), calbindin and 5-HT projected anally, while neurons with substance P (SP)-immunoreactivity projected orally, in both the small and large intestine. Neurons containing neuropeptide Y (NPY)- and calretinin-immunoreactivity projected locally. In the large intestine, GABA-immunoreactive neurons projected both orally and anally, with more axons tending to project anally. Myectomy operations revealed that circular muscle motor neurons containing NOS/VIP/ +/-NPY and calretinin neurons projected anally both in the small and large intestine, while SP-immunoreactive circular muscle motor neurons projected orally. In the large intestine, GABA-IR circular muscle motor neurons projected both orally and anally. This study showed that although some neurons, such as the NOS/VP inhibitory motor neurons and interneurons, SP excitatory motor neurons and 5-HT interneurons had similar projections to those in other species, the projections of other chemical classes of neurons in the mouse intestine differed from those reported in other species.

Inhibitory effect of mitragynine, an alkaloid with analgesic effect from Thai medicinal plant Mitragyna speciosa, on electrically stimulated contraction of isolated guinea-pig ileum through the opioid receptor

Effect of mitragynine, an indole alkaloid isolated from Thai medicinal plant kratom (Mitragyna speciosa), on electrically stimulated contraction was studied in the guinea-pig ileum. Mitragynine (1 nM-3 microM) inhibited the ileum contraction elicited by electrical stimulation, and its pD2 value was 6.91 +/- 0.04 (n = 5). Morphine (1 nM-1 microM) also inhibited the electrically stimulated contraction in a concentration-dependent manner (pD2 7.68 +/- 0.11; n = 5). Mitragynine was 10 fold less potent than morphine. Mitragynine (3-10 microM) did not show any effect on the smooth muscle contraction induced by acetylcholine or histamine. Naloxone (10-300 nM) reversed the inhibitory effect of mitragynine on electrically stimulated contraction. Furthermore, naloxone showed a shift of concentration-response curve of mitragynine to the right. There was no significant difference in the affinity of naloxone (i.e. pA2) in the presence of mitragynine or morphine. Mitragynine (3-10 microM) inhibited the naloxone-precipitated withdrawal contraction following a brief (5 min) exposure of the ileum to morphine. Tetrodotoxin (1 microM) and atropine (1 microM) inhibited the withdrawal contraction. The present results suggest that mitragynine inhibits the electrically stimulated contraction of guinea-pig ileum through the opioid receptor.

Tachykinins in the gut. Part I. Expression, release and motor function

The preprotachykinin-A gene-derived peptides substance P and neurokinin (NK) A are expressed in distinct neural pathways of the mammalian gut. When released from intrinsic enteric or extrinsic primary afferent neurons, tachykinins have the potential to influence both nerve and muscle by way of interaction with three different types of tachykinin receptor, termed NK1, NK2 and NK3 receptors. Most prominent among the effects of tachykinins is their excitatory action on gastrointestinal motor activity, which is seen in virtually all regions and layers of the mammalian gut. This action depends not only on a direct activation of the muscle through NK1 and/or NK2 receptors, but also on stimulation of excitatory enteric motor pathways through NK3 and/or NK1 receptors. In addition, tachykinins can inhibit motor activity by stimulating either inhibitory neuronal pathways or interrupting excitatory relays. A synopsis of the available data indicates that endogenous substance P and NKA interact with other enteric transmitters in the physiological control of gastrointestinal motor activity. Derangement of the regulatory roles of tachykinins may be a factor in the gastrointestinal dysmotility associated with infection, inflammation, stress and pain. In a therapeutic perspective, it would seem conceivable, therefore, that tachykinin agonists and antagonists are adjuncts to the treatment of motor disorders that involve pathological disturbances of the gastrointestinal tachykinin system.

Use of antagonists to define tachykininergic control of intestinal motility in pigs

The involvement of the tachykinins in extrinsic nervous control of motility was studied in isolated, vascularly perfused, porcine ileal segments. Substance P and neurokinin A (10(-8) M) stimulated motility, and nonpeptide NK1 and NK2 receptor antagonists (10(-6) M) abolished this. Electrical stimulation of the mixed extrinsic nerves (8 Hz) had no effect alone or with atropine (10(-6) M) or phentolamine (10(-5) M), but increased motility during coinfusion of both blockers. This effect was abolished by hexamethonium (3 x 10(-5) M), and was reduced by over 80% by the NK1 receptor antagonist. As previously shown, substance P and neurokinin A were released during nerve stimulation, only during blockade of alpha-adrenergic and muscarinic receptors, and the release was abolished by hexamethonium. Capsaicin infusions (10(-5) M) increased substance P and neurokinin A release, and weakly stimulated small intestinal motility, but this was not inhibited by the tachykinin antagonists. Our results suggest that intrinsic tachykinin-producing neurons, controlled by extrinsic, nicotinic, excitatory neural pathways, and extrinsic adrenergic, inhibitory pathways, participate in the regulation of small intestinal motility.

Neurochemical classification of myenteric neurons in the guinea-pig ileum

A strategy has been developed to identify and quantify the different neurochemical populations of myenteric neurons in the guinea-pig ileum using double-labelling fluorescence immunohistochemistry of whole-mount preparations. First, six histochemical markers were used to identify exclusive, non-overlapping populations of nerve cell bodies. They included immunoreactivity for the calcium binding proteins calbindin and calretinin, the neuropeptides vasoactive intestinal polypeptide, substance P and somatostatin, and the amine, 5-hydroxytryptamine. The sizes of these populations of neurons were established directly or indirectly in double-labelling experiments using a marker for all nerve cell bodies. Each of these exclusive populations was further subdivided into classes by other markers, including immunoreactivity for enkephalins and neurofilament protein triplet. The size of each class was then established directly or by calculation. These distinct, neurochemically-identified classes were related to other published work on the histochemistry, electrophysiology and retrograde labelling of enteric neurons and to the simple Dogiel morphological classification. A classification scheme, consistent with previous studies, is proposed. It includes 14 distinct classes of myenteric neurons and accounts for nearly all neurons in the myenteric plexus of the guinea-pig ileum.

Experimental basis for realistic large-scale computer simulation of the enteric nervous system

1. The enteric nervous system is perhaps the most accessible part of the mammalian nervous system in which it is feasible to attempt large scale computer simulation that is based closely on experimentally determined data. Here we summarize the data obtained for simulation of motility reflexes in the guinea-pig small intestine. 2. The chemistry, morphology and connectivity of each type of neuron involved in intrinsic reflexes have been investigated and most classes of neurons are physiologically well characterized. This includes primary sensory neurons, ascending and descending interneurons and motor neurons to circular and longitudinal muscle. 3. The responses of primary sensory neurons and the physiology of synaptic transmission from sensory neurons to interneurons and motor neurons, from interneurons to interneurons and from interneurons to motor neurons have been recorded during reflexes and in some cases the pharmacology of transmission has also been investigated. 4. Computer simulation, in which the activities of up to 30,000 neurons are modelled, produces patterns of activity that closely mimic those recorded in physiological experiments.

Myenteric neurons of the rat descending colon: electrophysiological and correlated morphological properties

Conventional intracellular electrophysiological recordings were made from 502 myenteric neurons of the rat descending colon. Myenteric neurons could be classified into three groups on the basis of distinct electrophysiological properties. The first group of neurons (51% of all neurons) fired tetrodotoxin-sensitive action potentials in response to direct somal depolarization and the majority (98%) of this group generated fast cholinergic excitatory synaptic potentials in response to focal stimulation and were therefore designated S/Type 1 neurons. The second group (40%) of neurons fired tetrodotoxin-insensitive action potentials which were followed by long-lasting membrane afterhyperpolarizations, hence were termed AH neurons. These neurons did not receive fast cholinergic synaptic inputs but ionophoretic application of acetylcholine induced rapid nicotinic cholinoceptor-mediated depolarizations. The final group of neurons (9%), named Type 3 neurons, received fast cholinergic synaptic inputs but could never be made to fire action potentials. Rundown in amplitude of successive fast excitatory synaptic potentials evoked by a short train of presynaptic nerve stimuli was observed in only a small proportion of neurons (8/37; 22%) with the majority of neurons (29/37; 78%) showing no such decrease in amplitude, even at frequencies of stimulation as high as 10 Hz. Superfusion of 5-hydroxytryptamine could induce both an inhibition and a facilitation of cholinergic fast synaptic transmission. Evidence was adduced that these presynaptic inhibitory and facilitatory actions appeared to be mediated via 5-hydroxytryptamine 1A and 5-hydroxytryptamine 4 receptors, respectively. Muscarinic slow excitatory synaptic potentials were not detected (9/9 neurons tested) and non-cholinergic slow excitatory synaptic potentials following repetitive focal presynaptic nerve stimulation were observed in only 39/502 (8%) of all neurons. In those neurons in which a demonstrable change in membrane input resistance was detectable, slow excitatory potentials were accompanied by an increased input resistance. In addition, in a small subset (4%) of S/Type 1 neurons, slow membrane hyperpolarizations accompanied by an increased membrane input resistance were observed following tetanic presynaptic nerve stimulation. Superfusion of 5-hydroxytryptamine induced both membrane depolarizations and hyperpolarizations. Membrane depolarizations were observed in 40% of all neuronal types (34% of S/Type 1 neurons, 58% of AH neurons and 11% of Type 3 neurons) and were accompanied by an increased membrane input resistance and occasionally, in S/Type 1 and AH neurons, by anodal break excitation or spontaneous action potential firing. Membrane hyperpolarizations were observed in S/Type 1 neurons (5%) only and were accompanied, unexpectedly, by an increased membrane input resistance. In those neurons that responded both to application of 5-hydroxytryptamine and tetanic presynaptic nerve stimulation, 5-hydroxytryptamine always mimicked the slow synaptic response indicating that 5-hydroxytryptamine may function as a slow synaptic mediator in some myenteric neurons. Myenteric neurons identified by intracellular injection of the neuronal marker Neurobiotin TM were found to conform to the morphological classification schemes proposed for myenteric neurons of the guinea-pig and porcine intestine, that is, Dogiel Types I and II and Stach Type IV neurons were present. Simultaneous electrophysiological recording and intracellular staining techniques revealed that a correlation existed between the electrophysiological and morphological properties of myenteric neurons of the rat colon, with electrophysiological classified S/Type 1 neurons having Dogiel Type I morphologies (95/108 neurons; 88%) and electrophysiological classified AH neurons having Dogiel Type II morphologies (87/94 neurons; 93%)...

Tachykinin receptors mediate atropine-resistant rat duodenal reflex contractions in vivo

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 mumol/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 mumol/kg i.v.) or hexamethonium (28 mumol/kg i.v.). Despite the continuous i.v. infusion of atropine (2 mumol/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 mumol/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 mumol/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 NK1 receptor agonists [Sar9] substance P sulfone and septide or of the NK2 receptor selective agonist, [beta Ala8] 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 [beta Ala8] 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.

Electrophysiological mapping of fast excitatory synaptic inputs to morphologically and chemically characterized myenteric neurons of guinea-pig small intestine

Neurons within the myenteric plexus of the guinea-pig ileum were impaled using conventional intracellular electrodes. Points of stimulation within the surrounding ganglia and connectives which gave rise to fast excitatory synaptic potentials were mapped using a movable monopolar stimulating electrode. Cells were then injected with the intracellular marker, biocytin, and processed for multiple label immunohistochemistry to reveal their morphologies, chemical contents and, hence, their functional classes. Of 65 neurons belonging to the S electrophysiological class, 53 received fast excitatory synaptic inputs from stimulation at sites at least 2 mm away in a directly circumferential direction. These inputs almost certainly arise from stimulation of the circumferentially-directed axons of the Dogiel type II/AH-neurons, which are thought to be intrinsic sensory neurons. The majority of cells which projected anally and were immunoreactive for nitric oxide synthase (19/25), all neurons which ramified in the tertiary plexus and were identified as longitudinal muscle motor neurons (6/6) and all neurons identified as excitatory motor neurons innervating the circular muscle (12/12) received inputs from these circumferentially-directed pathways. However only one of six descending filamentous interneurons impaled received such inputs, suggesting they may be differentially innervated. The conduction velocities of circumferentially-directed axons giving rise to fast excitatory post synaptic potentials were estimated to be 0.41 +/- 0.10 m/s (mean +/- standard deviation, n = 21). The conduction velocities estimated for longitudinally-directed pathways were 0.55 +/- 0.25 m/s (n = 29). Thus, the majority of myenteric neurons receive fast excitatory synaptic input from putative intrinsic sensory neurons which project circumferentially around the intestine.

Dissociation of the ascending excitatory reflex from peristalsis in the guinea-pig small intestine

Localized distension of the intestine evokes an ascending excitatory reflex and a descending inhibitory reflex in the circular muscle layer. The sequential activation of these two reflexes is believed to underlie the motor pattern of peristalsis, which is responsible for the co-ordinated propulsion of intestinal contents. In this study we have shown that the initiation of peristalsis involves mechanisms additional to those mediating the ascending excitatory reflex. A short length of guinea-pig small intestine was mounted in a partitioned organ bath so that the lumen was occluded by the partition, but neuronal continuity was maintained. The anal segment was distended by intraluminal fluid infusion to evoke a peristalsis; in the oral segment, an isotonic transducer was used to record circular muscle contractions due to ascending excitatory reflexes. Stepwise distension of the anal segment with 5 microliters increments at 10 s intervals, or with a large, single-step infusion, elicited both the ascending excitatory reflex and peristalsis, when carried out at 3 min intervals. The threshold volume for the ascending excitatory reflex was smaller than the threshold for peristalsis with either incremental or single-step distensions. The ascending excitatory reflex appeared with a shorter delay than peristalsis. Tetrodotoxin (0.6 microM) or hexamethonium (100 microM) added to the oral compartment abolished the ascending excitatory reflex but not peristalsis. These drugs abolished both the ascending excitatory reflex and peristalsis when added to the anal compartment. When stimuli were delivered at 1 min intervals, peristalsis failed completely after the first trial, but the ascending excitatory reflex persisted, at a slightly reduced amplitude. When the anal segment was distended to just-subthreshold volume, electrical field stimulation (0.25-0.5 ms, 1-5 Hz for 1 s), delivered at 3 min intervals, evoked ascending excitatory responses but not peristalsis. Higher frequency stimulation (10 Hz) consistently evoked both peristalsis and the ascending excitatory responses. When trains of electrical stimulation were repeated at 1 min intervals, peristalsis quickly failed, but the ascending excitatory response persisted, although reduced in amplitude. The initiation of peristalsis can be dissociated from the ascending excitatory reflex by its threshold volume, by the duration of distension or the intensity of electrical stimulation required, and by its susceptibility to fatigue with repeated mechanical or electrical stimuli. This suggests that the ascending excitatory reflex may be part of the mechanism underlying the initiation of peristalsis, but that additional mechanisms must also be involved. Peristalsis should not be regarded as a reflex response but rather as an all-or-nothing motor pattern, triggered by mechanical stimulation, similar to other co-ordinated motor patterns in vertebrates and invertebrates.

Analysis of contributions of acetylcholine and tachykinins to neuro-neuronal transmission in motility reflexes in the guinea-pig ileum

1. The roles of acetylcholine (ACh) and tachykinins in neuro-neuronal transmission during ascending excitatory and descending inhibitory reflexes were studied by recording intracellular reflex responses of the circular muscle to physiological stimuli. Experiments were carried out in opened segments of guinea pig ileum in an organ bath that was partitioned so that three regions could be independently exposed to drugs. 2. Ascending excitatory reflexes evoked by either distension from the serosal side or compression of the mucosa were depressed by 55% and 85%, respectively, in the presence of hexamethonium (200 microM) and by 30% and 45%, respectively, by a desensitizing concentration of the selective NK3 receptor agonist, senktide (1 microM), in the chamber in which reflexes were initiated. Together, hexamethonium and senktide abolished responses to compression. A residual response to distension persisted. This was abolished by hyoscine (1 microM). 3. Hexamethonium (200 microM) abolished ascending reflexes when applied to the region between the stimulus and the recording sites, or to the recording chamber. 4. Descending reflex responses were reduced by 35% by synaptic blockade in the stimulus chamber with physiological saline containing 0.1 mM Ca2+ plus 10 mM Mg2+. Senktide (1 microM) in the stimulus chamber reduced distension reflexes to the same extent as synaptic blockade, whereas hexamethonium (200 microM) and hyoscine (1 microM) depressed responses by less than 20%. Responses to compression were reduced by 40% by senktide alone, while senktide and hexamethonium together reduced responses by 60%, an effect similar to synaptic blockade. Under these conditions, hyoscine in the stimulus chamber restored reflexes evoked by distension, but did not alter those evoked by mucosal compression. 5. Total synaptic blockade in the intermediate chamber, between stimulus and recording sites, reduced descending reflex responses by more than 90%. In contrast, hexamethonium (200 microM) had no effect and hyoscine (1 microM) reduced only the responses to distension (by 30%). Senktide (1 microM) depressed responses to both stimuli by approximately 80%. 6. Application of hexamethonium (200 microM) to the recording chamber depressed descending reflex responses to distension applied in the near stimulation chamber by 15%, but had no effect on responses to compression in the near chamber or to either stimulus applied in the far chamber. 7. Descending reflexes evoked by near chamber stimuli were unaffected by hyoscine (1 microM) or senktide (1 microM) applied to the recording chamber; hyoscine enhanced reflexes evoked by compression in the far chamber by 50%. 8. For the ascending excitatory reflex pathway, it is concluded that transmission from sensory neurones is mediated by ACh acting via both nicotinic and muscarinic receptors, and by tachykinins acting at NK3 receptors. Transmission from ascending interneurones appears to be predominantly via nicotinic receptors. The descending inhibitory pathways are more complex, and while transmission from sensory neurones involves nicotinic, muscarinic and NK3 receptor-dependent components, transmission from descending interneurones to inhibitory motor neurones is neither cholinergic nor due to tachykinins acting via NK3 receptors.

Hyperpolarization and inhibition of contraction mediated by nitric oxide released from enteric inhibitory neurones in guinea-pig taenia coli

1. Inhibition of nitric oxide synthase by NG-nitro-L-arginine (L-NNA) reduced the neurogenic relaxation of precontracted taenia coli only in the absence of atropine. The membrane hyperpolarization associated with the neurogenic relaxation was also reduced by inhibition of NOS only when atropine was absent. 2. The membrane hyperpolarization associated with the neurogenic relaxation of the taenia coli was inhibited by oxyhaemoglobin only in the absence of atropine. In the presence of atropine, oxyhaemoglobin did not reduce the i.j.p. or nerve evoked relaxation. 3. Inhibition of NOS by L-NNA did not affect the overflow of [3H]-ACh in response to electrical field stimulation (EFS), suggesting that, under the conditions of our experiments, endogenous NO did not modulate release of ACh. Sodium nitroprusside also had no effect on the neurogenic overflow of [3H]-ACh; however, noradrenaline significantly reduced [3H]-ACh overflow. 4. In summary, the postjunctional effects of neurally-released NO are not apparent in guinea-pig taenia coli when atropine is present. This implies muscarinic regulation of NO release or muscarinic regulation of another excitatory substance, such as tachykinin(s), that, when blocked, masks the postjunctional effects of NO. These data, together with previous studies, suggest a possible regulatory role for NO in enteric neurotransmission that may be more prominent in some species or tissues than others.

Regeneration of nerve fibres across a colonic anastomosis in the guinea-pig

Resection and re-anastomosis of the bowel interrupts enteric neuronal pathways. The reestablishment of neuronal connections across a colonic anastomosis was studied using immunohistochemical, retrograde tracing and physiological techniques. In control guinea-pig proximal colon, retrograde labelling with 1,1'-didodecyl-3,3,3,3'-tetramethylindocarbocyanine perchlorate (DiI) revealed that enteric neurons with anally-directed projections are more numerous and have longer axons than orally-projecting neurons. In resected bowel, up to 26 weeks after re-anastomosis, descending neuronal pathways were substantially interrupted. Immunohistochemical labelling of nerve fibres revealed that some enteric nerve fibres did regenerate across narrow regions of the anastomosis, growing preferentially in the oral to anal direction. However, nerve fibres immunoreactive for neurofilament protein triplet were substantially depleted in myenteric ganglia anal to the anastomosis, even after the longest recovery periods, demonstrating that axonal regrowth was limited. This was confirmed in retrograde tracing studies, as no nerve cell bodies oral to an anastomosis were labelled when DiI was placed on myenteric ganglia just anal to the anastomosis. Physiological studies confirmed that regrowth of nerve fibres across the anastomosis occurred and that it was asymmetric, as electrical stimulation led to aboral conduction across the anastomosis more reliably than oral conduction, as measured by circular muscle contraction. After resection and re-anastomosis of the colon, the disruption of neuronal pathways in the enteric nervous system was observed, with limited and preferential re-establishment of aborally-directed long connections.

Differentiation of cholinergic cells in the rat gut during pre- and postnatal life

In the present work we studied the distribution and number of cholinergic neurons in the rat stomach, ileum and colon starting from prenatal life up to the adult animal. Cryo-cut sections of the three regions were incubated in the presence of the primary choline acetyltransferase (ChAT)-antibody and the immunoreaction was observed under an epifluorescence microscope and photographed. Our results demonstrate that cholinergic neurons are already present during prenatal life in the stomach and ileum, that several steps characterize cholinergic cell differentiation during postnatal life with a consistent delay in the appearance of ChAT-immunoreactivity (IR) in the submucous plexus compared to the myenteric plexus, and that the complete development is accomplished with weaning. In the colon the total number of ChAT-IR cells does not change from the suckling period to adulthood; a significantly larger number of ChAT-IR cells is found in the ileum of 5-day-old rats than in that of adult rats.

Tachykinins activate nonselective cation currents in canine colonic myocytes

The mechanism of tachykinin-induced excitation was studied in isolated colonic muscle cells and intact muscle strips. In whole cell voltage-clamp studies performed at 33 degrees C, neurokinin A (NKA) and substance P (SP) reduced L-type Ca2+ current. NKA and SP activated a cationic current that reversed near 0 mV. This current (INKA or ISP, respectively) had properties similar to the acetylcholine (ACh)-activated nonselective cation conductance (IACh), activated by muscarinic stimulation in other gastrointestinal smooth muscle cells. INKA and ISP were decreased when external Na+ was reduced. In contrast to IACh, INKA and ISP were not facilitated by increases in internal Ca2+, but little or no current was activated by these peptides when extracellular Ca2+ was low. INKA (10(-7) M) and ISP (10(-5) M) were blocked by Cd2+ (5 x 10(-4) M), quinine (10(-3) M), and the tachykinin-receptor antagonist [D-Pro2,D-Trp7,9]SP (10(-5) M). Current clamp recordings and intracellular recordings of intact tissues showed that NKA and SP depolarized the cell membrane, which is consistent with the activation of a nonselective cation conductance. These data suggest that a primary mechanism of the tachykinins is to activate a nonselective cation conductance that leads to depolarization. The increase in Ca2+ entry due to tachykinin stimulation appears to be secondary to the activation of the nonselective cation conductance.

Neuronal tachykinin NK2 receptors mediate release of non-adrenergic non-cholinergic inhibitory transmitters in the circular muscle of guinea-pig colon

The aims of this study were: (i) verify the usefulness of the recently described non-peptide antagonist, SR 142801, for blocking tachykinin NK3 receptors in the circular muscle of the guinea-pig colon and (ii) after occlusion of NK3 receptors by SR 142801, test the hypothesis that tachykinins may activate non-adrenergic non-cholinergic inhibitory neurons via non-NK3 receptors. In sucrose gap, we found that SR 142801 (0.1 microM) time-dependently inhibited the senktide-induced atropine (1 microM)-sensitive depolarization, action potentials and contractions of circular muscle of guinea-pig colon without affecting the cholinergic excitatory junction potential and contraction produced by single pulse electrical field stimulation. Likewise, SR 142801 (0.1 microM) time-dependently inhibited the senktide-induced non-adrenergic non-cholinergic hyperpolarization and relaxation of the circular muscle, without affecting the non-adrenergic non-cholinergic inhibitory junction potentials and relaxation produced by single pulse electrical field stimulation. Therefore, SR 142801 is a suitable tool to occlude neuronal NK3 receptors in guinea-pig colon. In the presence of SR 142801 (0.1 microM), atropine (1 microM), guanethidine (3 microM), indomethacin (3 microM) and nifedipine (1 microM) superfusion with neurokinin A (0.3 microM) produced depolarization on which a series of inhibitory junction potentials were superimposed. The incidence, number and amplitude of the inhibitory junction potentials evoked by neurokinin A was partly reduced by pretreatment with either apamin (0.1 microM) or L-nitroarginine (30 microM) and was totally blocked by pretreatment with apamin plus L-nitroarginine or by tetrodotoxin (1 microM). None of these treatments affected the depolarization and contraction produced by neurokinin A. The NK1 receptor selective antagonist, GR 82,334 (3 microM), did not affect the responses to neurokinin A, which were abolished by the NK2 receptor-selective antagonist GR 94,800 (0.1 microM). Substance P (0.3 microM) produced a large depolarization of the membrane but was poorly effective in producing superimposed inhibitory junction potentials. The NK1 receptor-selective agonist [Sar9]substance P sulfone (0.3 microM) produced large depolarization without inducing superimposed inhibitory junction potentials, while the NK2 receptor-selective synthetic agonist [beta-Ala8]neurokinin A(4-10) (0.3 microM) produced depolarization and superimposed inhibitory junction potentials. We conclude that neurokinin A, in addition to direct excitation and contraction of circular muscle activates, via neuronal NK2 receptors, inhibitory non-adrenergic non-cholinergic motorneurons. Thus, neuronal NK2 receptors should be considered as targets for endogenous tachykinins in enteric circuitries leading to descending relaxation in guinea-pig colon.

Role of tachykinins as excitatory mediators of NANC contraction in the circular muscle of rat small intestine

1. The aim of this study was to assess the role of tachykinins, acting via NK1 and NK2 receptors, in mediating nonadrenergic noncholinergic (NANC) contractions produced by electrical field stimulation (EFS) in the circular muscle of the rat small intestine. 2. In the presence of atropine (1 microM), guanethidine (3 microM), indomethacin (10 microM), apamin (0.3 microM) and L-nitroarginine (L-NOARG, 100 microM) and after in vitro capsaicin (10 microM for 15 min) pretreatment, EFS (0.25 ms pulse width, 100 V, 1-30 Hz for 5 s) produced a frequency-dependent NANC contraction of mucosa-free circular muscle strips from the rat proximal duodenum and terminal ileum. In the duodenum, the NANC contraction was preceded by a transient NANC relaxation. All responses to EFS were abolished by 1 microM tetrodotoxin. 3. The NK1 receptor selective antagonist, SR 140,333 (0.1 microM for 60 min) and the NK2 receptor selective antagonist, MEN 10,627 (0.1 microM for 60 min), both produced a partial inhibition of the contractile response to EFS. The co-administration of SR 140,333 and MEN 10,627 produced a profound inhibition of the response to EFS in the duodenum, larger than that produced by each antagonist alone; a fraction (about 25% of the response at 30 Hz) of the NANC contraction of the duodenum persisted in the presence of the two antagonists. This residual response was however abolished after co-administration of the NK1 and NK2 receptor antagonists, GR 94,800 (1 microM) and GR 82,334 (10 microM). The co-administration of SR 140,333 and MEN 10,627 nearly abolished the NANC contraction to EFS in the ileum. 4. Nifedipine (1 microM) induced a profound depression of the NANC contraction to EFS in both duodenal and ileal strips. A fraction of the response to EFS (about 25 and 5-10% of the response at 30 Hz in the duodenum and ileum, respectively) was nifedipine-resistant. SR 140,333 (0.1 microM) had little effect on the nifedipine-resistant response to EFS in the duodenum although it reduced by about 50% the response in the ileum. MEN 10,627 (0.1 microM) produced a partial inhibitory effect of the nifedipine-resistant response in both regions. The co-administration of SR 140,333 and MEN 10,627 nearly abolished the nifedipine-resistant response in the ileum while a small fraction (about 20% of control) of the response persisted in the duodenum.

The morphology and projections of retrogradely labeled myenteric neurons in the human intestine

BACKGROUND & AIMS

Myenteric ganglia in the human gastrointestinal tract contain a mixture of many different types of nerve cells that cannot be distinguished by their location. The aim of this study was to characterize different functional types of cells by using retrograde labeling in vitro to identify neurons according to their targets.

METHODS

The retrograde label 1,1'-didodecyl 3,3,3',3'-indocarbocyanine perchlorate (Dil) was applied to different target layers of human small or large intestine. After 3-5 days in organotypic culture, myenteric neurons projecting to the Dil application site were visualized and mapped using fluorescence microscopy.

RESULTS

Myenteric motor neurons projecting to the external muscle layer were typically unipolar cells with lamellar dendrites (Dogiel type I) and had short projections up to 16 mm long. In contrast, presumed interneurons with Dogiel type I morphology were shown to project up to 68 mm aborally or up to 38 mm orally. Multipolar Dogiel type II neurons with smooth cell bodies were labeled most frequently from the submucous plexus. No myenteric neurons were labeled by Dil applied to the mucosa.

CONCLUSIONS

Myenteric neurons labeled from each target had characteristic size, morphology, polarity, and length of projections, indicating that there is a high degree of organization in the human enteric nervous system.

Cellular sites of expression of the neurokinin-1 receptor in the rat gastrointestinal tract

In the digestive system, substance P is an excitatory transmitter to muscle, a putative excitatory neuro-neuronal transmitter, a vasodilator, and a mediator in inflammatory processes. Many of the biological effects of substance P are mediated by a high-affinity interaction with the tachykinin receptor neurokinin-1. The aim of the present study was to identify the sites of expression of this receptor in the rat stomach and intestine by immunohistochemistry with a polyclonal antiserum raised to the intracellular C-terminal portion of the rat neurokinin-1 receptor. Neurokinin-1 receptor immunoreactivity is present in a large population of enteric neurons. The relative density of these neurons along the gut is colon > ileum >> stomach. In the intestine, stained neurons have a smooth cell body with processes that can be followed within and between plexuses, and make close approaches to other neuronal cells, but do not appear to project outside the plexuses, suggesting that they are interneurons. In the stomach, neurokinin-1 receptor-immunoreactive neurons are infrequent and have a poorly defined and irregular shape. Neurokinin-1 receptor immunoreactivity is also localized to numerous non-neuronal cells in the inner portion of the circular muscle layer of the small intestine, which have the appearance of small dark smooth muscle cells or interstitial cells of Cajal. These cells are postulated to form a "stretch-sensitive" system with the deep muscular plexus and thus constitute an important site of regulation of muscle activity. Double labeling immunofluorescence was used to simultaneously localize neurokinin-1 receptor and substance P/tachykinin immunoreactivities. These experiments demonstrate that in the enteric plexuses, substance P/tachykinin-immunoreactive varicose fibers encircle the cell bodies of most neurokinin-1 receptor-containing neurons, and in the inner portion of the circular muscle layer of the small intestine they lie close to neurokinin-1 receptor-immunoreactive non-neuronal cells. In addition, some enteric neurons express both neurokinin-1 receptor and substance P/tachykinin immunoreactivities. The present study provides strong evidence that the neurokinin-1 receptor is the tachykinin receptor mediating the actions of substance P on enteric neurons and smooth muscle.

Ultrastructural studies of the myenteric plexus and smooth muscle in organotypic cultures of the guinea-pig small intestine

External muscle and myenteric plexus from the small intestine of adult guinea-pigs were maintained in vitro for 3 or 6 days. Myenteric neurons and smooth muscle cells from such organotypic cultures were examined at the electron-microscopic level. An intact basal lamina was found around the myenteric ganglia and internodal strands. Neuronal membranes, nuclei and subcellular organelles appeared to be well preserved in cultured tissues and ribosomes were abundant. Dogiel type-II neurons were distinguishable by their elongated electron-dense mitochondria, numerous lysosomes and high densities of ribosomes. Vesiculated nerve profiles contained combinations of differently shaped vesicles. Synaptic membrane specializations were found between vesiculated nerve profiles and nerve processes and cell bodies. The majority of nerve fibres were well preserved in the myenteric ganglia, in internodal strands and in bundles running between circular muscle cells. No detectable changes were found in the ultrastructure of the somata and processes of glial cells. Longitudinal and circular muscle cells from cultured tissue had clearly defined membranes with some close associations with neighbouring muscle cells. Caveolae occurred in rows that ran parallel to the long axis of the muscle cells. These results indicate that the ultrastructural features of enteric neurons and smooth muscle of the guinea-pig small intestine are well preserved in organotypic culture.

Ultrastructural examination of the targets of serotonin-immunoreactive descending interneurons in the guinea pig small intestine

Serotonin neurons are descending interneurons in the myenteric plexus of the guinea pig small intestine. Preembedding single- and double-label immunocytochemistries at the ultrastructural level were used to identify the targets of these serotonin interneurons. Serial ultrathin sections were taken through a myenteric ganglion that had been processed for serotonin immunocytochemistry. The ganglion contained the cell bodies of 69 neurons, including 2 serotonin neurons and 6 neurons with the ultrastructural features of Dogiel type II cells. For each cell body in the ganglion, the number of serotonin inputs (synapses and close contacts) was determined. About 59% of the cell bodies did not receive any serotonin inputs. The most abundant serotonin terminals were related to two targets: other serotonin descending interneurons and a population of neurons with Dogiel type I morphology, but whose neurochemistry and function is unknown. The serotonin inputs to the serotonin cell bodies were located predominantly on the lamellar dendrites. Each of the Dogiel type II neurons received 3 or fewer serotonin inputs, and none of the serotonin inputs to Dogiel type II neurons formed a synapse. Overall, about 40% of the serotonin inputs formed synapses. The serotonin inputs to neurons that received many serotonin inputs were more likely to show synaptic specializations than serotonin inputs to neurons that received few serotonin inputs. Inhibitory motor neurons contain nitric oxide synthase (NOS). At the light microscope level, serotonin nerve fibers do not form dense pericellular baskets around NOS cell bodies. To determine whether there are serotonin inputs to NOS neurons, serial ultrathin sections were taken through a myenteric ganglion that had been processed for preembedding double-label immunocytochemistry, in which the NOS neurons were labeled with peroxidase-diaminobenzidine and the serotonin neurons with silver-intensified 1 nm gold. Only 1 out of 9 NOS cells examined in serial section received more than 5 serotonin inputs. The results suggest that, in the guinea pig small intestine, the serotonin descending interneurons are not an essential element of the descending inhibitory reflex.

Evidence that tachykinin NK1 and NK2 receptors mediate non-adrenergic non-cholinergic excitation and contraction in the circular muscle of guinea-pig duodenum

1. In the presence of atropine (1 microM), guanethidine (3 microM), indomethacin (3 microM), apamin (0.1 microM) and L-nitroarginine (L-NOARG, 30 microM), electrical field simulation (EFS) produced a nonadrenergic, noncholinergic (NANC) excitatory junctional potential (e.j.p.), action potentials and contraction of the circular muscle of the guinea-pig proximal duodenum, recorded by the single sucrose gap technique. 2. The selective tachykinin (TK) NK1 receptor antagonist, GR 82,334 (30 nM-3 microM) produced a concentration-dependent inhibition of the EFS-evoked NANC e.j.p. and contraction. Similarly, the selective NK2 receptor antagonists, MEN 10,627 (30 nM-3 microM) and GR 94,800 (100 nM-10 microM), both produced a concentration-dependent inhibition of the EFS-evoked NANC e.j.p. and contraction. GR 82,334 inhibited the electrical and mechanical NANC responses to EFS in an almost parallel manner, while MEN 10,627 and GR 94,800 were more effective in inhibiting the mechanical than the electrical response to EFS. 3. Activation of the NK1 or NK2 receptor by the selective agonists, [Sar9]substance P (SP) sulphone and [beta Ala8]neurokinin A (NKA) (4-10), respectively (0.3 microM each), produced depolarization, action potentials and contractions. GR 82,334 selectively inhibited the responses to [Sar9]SP sulphone, without affecting the responses to [beta Ala8]NKA (4-10). MEN 10,627 and GR 94,800 inhibited or abolished the responses to [beta Ala8]NKA (4-10), without affecting the responses to [Sar9]SP sulphone. 4. Nifedipine (1 microM) abolished the action potentials and contraction produced either by EFS or by the TK receptor agonists [Sar9]SP sulphone or [beta Ala8]NKA (4-10). 5. In the presence of nifedipine, the NANC e.j.p. produced by EFS was biphasic: in the majority of strips tested (21 out of 29) an early fast phase of depolarization was followed by a second slow component. The combined administration of GR 82,334 and GR 94,800 (3 microM each) reduced both components, the slow phase being inhibited to a greater extent than the fast phase. 6. The P2 purinoreceptor antagonist, suramin (100 microM) reduced the fast phase of the e.j.p. produced by EFS in the presence of nifedipine, without affecting the slow phase. The combined administration of suramin, GR 82,334 and GR 94,800 produced a nearly complete blockade of the e.j.p. produced by EFS in the presence of nifedipine. 7. When tested in the absence of apamin and L-NOARG, EFS induced a NANC inhibitory junction potential (i.j.p.) followed by an e.j.p., and the selective P2Y receptor agonist, adenosine-5'-O-(2-thiodiphosphate) (ADP beta S, 10 microM), produced membrane hyperpolarization. After addition of apamin and L-NOARG, the ij.p. was blocked, and EFS produced a pure NANC e.j.p.; ADPPS produced depolarization, action potentials and contraction.8. Suramin (100 microM) blocked the depolarization, action potentials and contractions produced by ADP beta S in the presence of apamin and L-NOARG, without affecting the responses produced by the NK1receptor agonist, [Sar9}SP sulphone.9. We conclude that NK1 and NK2 receptors cooperate in producing NANC excitation and contraction of the circular muscle in the guinea-pig proximal duodenum. Activation of either TK receptor produces membrane depolarization and both receptors contribute to generate action potentials which are essential for producing muscle contraction, via nifedipine-sensitive calcium channels. It appears that endogenous ATP chiefly acts as an inhibitory transmitter but, after blockade of NANC inhibitory mechanism(s),ATP may act as a fast signalling excitatory transmitter.

Neurochemical coding of enteric neurons in the guinea pig stomach

The aim of this study was to investigate the neurochemical coding of myenteric neurons in the guinea pig gastric corpus by using immunohistochemical methods. Antibodies and antisera against calbindin (CALB), calretinin (CALRET), choline acetyltransferase (ChAT), calcitonin gene-related peptide (CGRP), dopamine beta-hydroxylase (DBH), beta-endorphin (ENK), neuropeptide Y (NPY), neuron-specific enolase (NSE), nitric oxide synthase (NOS), protein gene product 9.5 (PGP), parvalbumin (PARV), serotonin (5-HT), somatostatin (SOM), substance P (SP), tyrosine hydroxylase (TH), and vasoactive intestinal peptide (VIP) were used. Double- and triple-labeling studies revealed colocalization of certain transmitters and enabled the identification of distinct subpopulations of gastric enteric neurons. NPY/VIP/NOS/ENK were present in 28% of all neurons, whereas 11% had NPY/VIP/DBH/ChAT; NOS-only neurons made up 2% of the population. The combination SP/ChAT/ENK occurred in 21% of the population, whereas SP/ChAT/ENK/CALRET and SP/CHAT/SOM/ +/- CALRET was identified in 5% and 6% of all cells, respectively. 5-HT-containing neurons comprised 2% of all cells and could be further classified by the presence of additional antigens as 5-HT/SP/(ChAT) or 5-HT/VIP/(ChAT). Approximately 21% of all neurons contained only ChAT with no additional antigen present and are referred to as ChAT/-. Gastric myenteric ganglion cells were not immunoreactive for CALB, PARV, CGRP, or TH. The results of this study indicate that gastric myenteric neurons can be characterized on the basis of different chemical coding. Neurochemical coding of corpus myenteric neurons revealed some similarities and significant differences in comparison with other regions of the gut. These differences might reflect adaptation of enteric nerves according to regional specialization and the distinct functions of the proximal stomach as a gastric reservoir.

Prejunctional M1 and postjunctional M3 muscarinic receptors in the circular muscle of the guinea-pig ileum

The effects of subtype-selective muscarinic receptor antagonists on electrically evoked release of acetylcholine and muscle contraction were compared in circular muscle preparations of the guinea-pig ileum. Incubation of the preparation with [3H]choline resulted in the formation of [3H]acetylcholine. Electrical stimulation caused the release of [3H]acetylcholine which was abolished by tetrodotoxin and omission of calcium from the medium. 5-Hydroxytryptamine (10 microM) and the nicotinic agonist 1,1-dimethyl-4-phenyl-piperazinium (300 microM) did not change acetylcholine release. The muscarinic antagonists pirenzepine (M1 selective), AF-DX 116 (M2 selective) and hexahydrosiladifenidol (M3 selective) caused concentration-dependent increases in the evoked release of acetylcholine, and inhibitions of the circular muscle contraction. The postjunctional affinity constants (pA2 values) obtained for hexahydrosiladifenidol (8.06), pirenzepine (6.95) and AF-DX 116 (6.60) identified the muscular receptor as an M3 subtype. Pirenzepine was more potent in facilitating the evoked release than hexahydrosiladifenidol and AF-DX 116. These findings suggest that the release of acetylcholine in the circular muscle is inhibited by M1 muscarinic autoreceptors whereas muscle contraction is mediated by M3 receptors.

Plurichemical transmission and chemical coding of neurons in the digestive tract

The enteric nervous system contains neurons with well-defined functions. However, when neurons of the same function are examined in different regions or species, they are found to show subtle differences in their pharmacologies of transmission and different chemical coding. Individual enteric neurons use more than one transmitter, i.e., transmission is plurichemical. For example, enteric inhibitory neurons have three or more primary transmitters, including nitric oxide, vasoactive intestinal peptide, and possibly adenosine triphosphate and pituitary adenylyl cyclase activating peptide. Primary transmitters are highly conserved, although their relative roles vary considerably between gut regions. Multiple substances, including transmitters and their synthesizing enzymes and nontransmitters (such as neurofilament proteins), provide neurons with a chemical coding through which their functions and projections can be identified. Although equivalent neurons in different regions have the same primary transmitters, other chemical markers differ substantially. Caution must be taken in extrapolating pharmacological and neurochemical observations between species or even between regions in the one species. On the other hand, careful interregion and interspecies comparisons lead to an understanding of the features of enteric neurons that are highly conserved and can be used in valid extrapolation.

Mathematic modelling of the enteric nervous network. 5. Excitation propagation in a planar neural network

A mathematical model of the enteric nervous system (Auerbach's plexus) as a planar neural network has been developed, based on the actual morphological data of its organization. The network is composed of excitatory (cholinergic) and inhibitory (adrenergic) neurones interconnected by polysynaptic channels, formed of the geometrically non-uniform unmyelinated nerve axons. The synaptic zones are modelled as a three-compartment open pharmacokinetics system, i.e., presynaptic terminal, synaptic cleft and postsynaptic membrane where the pharmacokinetic mechanisms of electrochemical coupling are considered. All the chemical reactions of transformation of acetylcholine and adrenaline within them are described by first order Michaelis-Menten kinetics. The propagation of the electrical impulse along the pathways and in the vicinity of the nerve terminal is described by the modified Hodgkin-Huxley equations. The results of numerical simulation of the propagation of excitation within the neuronal chain, inhibitory feedback circuit, and a planar neuronal network under normal physiological conditions and after treatment with cholinergic/adrenergic agonists and antagonists are presented. The model predicts the dose-dependent influence of pharmacological agents on the neural network function.

Sensitization of the contractile system of canine colonic smooth muscle by agonists and phorbol ester

1. Sensitization of the contractile system in response to combinations of excitatory agonists acetylcholine (ACh), methacholine, histamine and neurokinin A (NKA) was investigated in colonic circular smooth muscle of dog, NKA (1 nM) potentiated the contractile response to 1 microM ACh, but did not increase the fura-2 fluorescence ratio (R340/380). Contraction in response to low concentrations of either methacholine or histamine was potentiated significantly by 0.1 microM 4-phorbol 12,13-dibutyrate (PDBu), suggesting that activation of protein kinase C can potentiate contraction at threshold concentrations of agonists. 2. Variability in the sensitivity of the contractile system to Ca2+ was demonstrated over a range of agonist concentrations. KCl, ACh, histamine and NKA each produced a concentration-dependent increase in the amplitude of phasic contractions and R340/380. However, ACh, histamine and NKA each induced maximal increases in R340/380 at concentrations less than that needed to induce maximum force. 3. In depolarized muscles, NKA (50 nM) and PDBu (1 microM) each increased the magnitude of tonic contraction with no change or a decrease in both R340/380 and myosin light chain phosphorylation. In alpha-toxin-permeabilized fibres, 0.1 microM PDBu and 1 microM NKA shifted the Ca(2+)-force response to the left. Ca(2+)-induced contractions were also potentiated by 100 microM GTP-gamma-S or 1 microM NKA plus 10 microM GTP. Potentiation of contraction by NKA and GTP was antagonized by 10 microM GDP-beta-S. 4. The results suggest that endogenous agonists acting via G-proteins sensitize the contractile element of colonic smooth muscle in part by activation of protein kinase C. In some cases, sensitization may be secondary to increased myosin phosphorylation (ACh), but in other cases it appears to be independent of increased myosin light chain phosphorylation (NKA and PDBu). Therefore regulatory mechanisms in addition to myosin phosphorylation contribute to the apparent sensitization of the contractile system to Ca2+.

Specialization of tachykinin NK1 and NK2 receptors in producing fast and slow atropine-resistant neurotransmission to the circular muscle of the guinea-pig colon

We studied the relative contribution of tachykinin NK1 and NK2 receptors in producing nonadrenergic noncholinergic excitation of the circular muscle of the guinea-pig proximal colon in response to electrical field stimulation. All experiments were performed in the presence of atropine, guanethidine, indomethacin, apamin and L-nitroarginine. In organ bath experiments, electrical stimulation produced a tetrodotoxin-sensitive frequency-dependent contraction. The NK1 receptor antagonists, FK 888 (1-10 microM) and GR 82,334 (0.3-3 microM) markedly reduced but did not abolish the nonadrenergic noncholinergic response. The NK2 receptor antagonist, GR 94,800 (0.3-3 microM) was partly effective at 3 microM. The combined administration of FK 888 (10 microM) and GR 94,800 (3 microM) or GR 82,334 and GR 94,800 abolished the nonadrenergic noncholinergic contraction. The response to a prolonged period of stimulation (3 Hz for 5 min) was evenly depressed by FK 888 or GR 82,334, while GR 94,800 was more effective in inhibiting the late (87% inhibition) than the peak response (25% inhibition). In the presence of nifedipine (1 microM) a marked inhibition of the nonadrenergic noncholinergic contraction was observed and a time lag was evident between stimulus application and onset of contraction, which showed slow onset and offset kinetics. The nifedipine-resistant nonadrenergic noncholinergic contraction was unaffected by FK 888 or GR 82,334 but was suppressed by GR 94,800. Submaximally effective (1-3 nM) concentrations of substance P and neurokinin A produced distinct patterns of contraction: the response to substance P was fast and declined rapidly toward baseline; the response to neurokinin A was slow and sustained. In the presence of nifedipine, the response to substance P was greatly depressed and became slower in onset; nifedipine did not affect the contraction to neurokinin A but slowed its time-course. In sucrose gap experiments, either a short (10 Hz for 1 s) or a prolonged period of electrical stimulation (3 Hz for 3 min) evoked membrane depolarization, action potentials and contraction: in response to the "prolonged" stimulation, distinct phasic and tonic component of contraction were observed. Nifedipine abolished action potentials and the phasic contraction produced by a short period of stimulation, reduced by about 50% the maximal contraction developed during the prolonged stimulation without affecting the amplitude of the tonic response. In the presence of nifedipine, GR 82,334 (3 microM) blocked the membrane depolarization but did not affect contraction; GR 94,800 (0.1 microM) did not affect depolarization but abolished contraction.(ABSTRACT TRUNCATED AT 400 WORDS)

Characterization of alkaline phosphatase-reactive neurons in the guinea-pig small intestine

Endogenous alkaline phosphatase activity has been localized histochemically on the surface of enteric neurons of the guinea-pig small intestine by both light and electron microscopy. The enzyme activity was associated with some myenteric neurons that had Dogiel type I morphology, and the histochemical reaction products typically formed a honeycomb-like structure on labelled cell bodies. No Dogiel type II neurons in the myenteric plexus or submucous neurons showed alkaline phosphatase reactivity. Nerve fibres reactive for alkaline phosphatase were present in the myenteric plexus and ran in bundles in the circular muscle and deep muscular plexus. In addition, reactive varicose axons supplied the submucous plexus and non-ganglionated plexus of the mucosa. The results of interruption of the enteric neuronal pathways demonstrated that alkaline phosphatase-reactive myenteric neurons project anally to other myenteric ganglia, to the circular muscle and to the submucous plexus. Sequential enzyme histochemistry showed that virtually all alkaline phosphatase-reactive neurons also contained nitric oxide synthase, revealed by NADPH-diaphorase reactivity. It was estimated that 14-18% of all myenteric neurons showed alkaline phosphatase reactivity. About one-third of nitric oxide synthase-containing myenteric neurons, however, did not contain alkaline phosphatase activity. At the ultrastructural level, alkaline phosphatase activity was associated specifically with the plasma membranes of nerve cell bodies, axons and dendrites of some myenteric neurons. Reactive nerve fibres made close appositions with non-reactive submucous neurons and, within myenteric ganglia, predominantly with other alkaline phosphatase-reactive neurons. In addition to its presence in neurons, alkaline phosphatase reactivity was also present in some endothelial cells in blood vessels in the submucosa and in capillary pericytes. It is concluded, on the basis of the projections and neurochemistry, that in the guinea-pig small intestine alkaline phosphatase activity is associated with nitric oxide synthase-containing neurons which include inhibitory motor neurons to the circular muscle, and anally-directed interneurons to other myenteric and submucous neurons.

All calbindin-immunoreactive myenteric neurons project to the mucosa of the guinea-pig small intestine

The projections of Dogiel type II myenteric neurons to the mucosa of the guinea-pig ileum were quantified by combining retrograde transport of DiI, in vitro, with immunohistochemistry. After DiI application to the mucosa over an area of 1.5 x 10 mm2, virtually all (> 97%) calbindin-immunoreactive Dogiel type II neurons in the myenteric plexus underneath the mucosal DiI application site were labelled, indicating that essentially all of these neurons project to the mucosa. From cell counts, on average 5 calbindin-immunoreactive neurons project to each villus, and each calbindin-immunoreactive neuron supplies on average 10 villi. Since Dogiel type II neurons that were not immunoreactive for calbindin (19% of all labelled nerve cells) also projected to the mucosa, it is likely that all Dogiel type II neurons, which are putative sensory neurons of the gut, project to the mucosa.

Local neural control of intestinal motility: nerve circuits deduced for the guinea-pig small intestine

1. Propulsion of digesta along the intestine appears to occur by the action of a series of local reflexes which cause contraction oral to the digesta and relaxation of circular muscle on the anal side. 2. There is now substantial evidence available about the identities of the enteric neurons that mediate these reflexes. 3. The motor neurons and interneurons of the reflex pathways lie within the myenteric plexus. These neurons can be classified electrophysiologically as S-neurons and have distinctive projections and neurochemistries. 4. The sensory neurons may lie in the myenteric plexus, but there is some evidence for sensory neurons in the submucous plexus. A contribution from extrinsic sensory neurons to local motility reflexes cannot be ruled out. Intrinsic sensory neurons are probably AH-neurons and are large multi-axonal cells.

Tachykinin NK1 and NK2 receptor antagonists and atropine-resistant ascending excitatory reflex to the circular muscle of the guinea-pig ileum

1. The aim of this study was to investigate the effect of various antagonists, selective for the tachykinin NK1 or NK2 receptor, on the atropine-resistant ascending excitatory reflex (AER) to the circular muscle of the guinea-pig ileum elicited by radial stretch (balloon distension) or electrical field stimulation. 2. Submaximal and maximal atropine- (1 microM) resistant AER elicited by balloon distension averaged about 40-50% and 70-90% of maximal circular spasm to 80 mM KCl, respectively. The NK1 receptor antagonist, (+/)-CP 96,345 (1 microM) inhibited both maximal and submaximal AER. FK 888 (1-3 microM) inhibited submaximal AER only. RP 67,580 (1 microM) was ineffective. The NK2 receptor antagonist, GR 94,800, inhibited both maximal and submaximal AER at all concentrations tested (0.1-3.0 microM), while SR 48,968 was effective only at 1.0 microM. The NK2 receptor antagonists, MEN 10,376 and MEN 10,573 inhibited both submaximal and maximal AER at 10 and 1.0 microM, respectively. 3. In other experiments, an NK1 receptor antagonist, (+/-)-CP 96,345 or FK 888 (1.0 microM in each case) was administered first and the effect of GR 94,800 (1.0 microM) on the residual AER response was determined; or GR 94,800 was administered first and the effect of (+/-)-CP 96,345 or FK 888 was determined. The results of these experiments indicated an additive effect produced by the combined treatment with NK1 and NK2 receptor antagonists. 4. Electrical field stimulation (10 Hz for 0.5 s, 10-20 V, 0.15-0.3 ms pulse width) with electrodes placed at 1.4-1.8 cm anal to the recording site, produced ascending contractions which were almost abolished by 10 MicroM hexamethonium (electrically-evoked AER). In the presence of apamin (0.1 MicroM) and N0-nitro-L-arginine (30 MicroM) these contractions were reproducible over 10 consecutive stimulation cycles.GR 94,800 (1 MicroM) and FK 888 (1 MicroM) both produced a partial inhibition of the electrically-evoked AER and their combined administration produced an inhibitory effect which was larger than that induced by each antagonist alone.5. FK 888 (1-3 MicroM), GR 94,800 (1-3 MicroM), MEN 10,573 (1 MicroM) and MEN 10,376 (10 MicroM) did not significantly affect the atropine-sensitive twitch contractions produced by electrical field stimulation of the guinea-pig ileum longitudinal muscle-myenteric plexus preparation, which were abolished by 10-30 MicroM procaine, 1 MicroM tetrodotoxin or 1 MicroM atropine. (+/-)-CP 96,345 (1 MicroM) and SR 48,968 (1 ILM)produced 12% and 27% inhibition of cholinergic twitches in the longitudinal muscle of the ileum,respectively.6. We conclude that both NK1 and NK2 receptors mediate the atropine-resistant AER to the circular muscle of the ileum. NK2 receptor activation plays a more important role than NK1 receptor activation in the AER evoked by radial stretch. Since a consistent fraction of the distension- and electrically evoked atropine-resistant AER persists in the presence of combined NK1 and NK2 receptor blockade,the existence of a third excitatory transmitter to the circular muscle of the ileum, in addition to acetylcholine and tachykinins, is suggested.

Electrophysiological and morphological classification of myenteric neurons in the proximal colon of the guinea-pig

Intracellular recordings were made from myenteric neurons in the proximal colon of the guinea-pig. The electrical behaviour of the neurons in response to intracellular depolarizing current pulses, and to internodal strand stimulation, was recorded. The intracellular electrode contained the intracellular marker biocytin which was injected into impaled neurons for subsequent histochemistry. Proximal colon myenteric neurons displayed electrophysiological properties similar to myenteric neurons in the small intestine, and were classified as either AH- or S-neurons. AH-neurons were characterized by the presence of a slow afterhyperpolarization following an action potential. Internodal strand stimulation evoked slow excitatory synaptic potentials in five out of six AH-neurons tested, but did not evoke fast excitatory synaptic potentials in 26 AH-neurons tested. S-neurons lacked a slow afterhyperpolarization, but internodal strand stimulation evoked fast excitatory synaptic potentials in all 113 neurons and slow excitatory synaptic potentials in seven out of 17 tested. A subpopulation of AH-neurons displayed a rhythmic oscillation in membrane potential which could be triggered by an action potential. S-neurons could be subdivided into those that fired tonically and those that fired phasically in response to long depolarizing current pulses. About 80% of the AH-neurons were immunoreactive for calbindin, as were 10% of S-neurons. A further 17% of S-neurons, but no AH neurons, were calretinin immunoreactive. Morphological analysis of filled neurons revealed eight distinct classes. Neurons electrophysiologically classified as AH typically had a large, oval soma and several long tapering processes. Processes of AH-neurons branched into many adjacent ganglia. Almost all S-neurons were uniaxonal and many axons ended in an expansion bulb in the myenteric plexus. S-neurons typically had broad, lamellar processes, or short, spiny processes. Roughly equal proportions of S-neurons had oral or anal projection. However, almost all S-neurons that were immunoreactive for calbindin or calretinin projected orally. The results indicate that myenteric neurons in the proximal colon of the guinea-pig are electrophysiologically similar to myenteric neurons in the small intestine, but there are a greater number of morphological and chemical categories.

Localization of nitric oxide synthase in canine ileocolonic and pyloric sphincters

The distribution of neurons containing NAD-PH-diaphorase (NADPH-d) activity and nitric oxide synthase-like immunoreactivity (NOS-LI) in the canine pyloric and ileocolonic sphincters was studied. Cells within the myenteric and submucosal ganglia were positive for NADPH-d. These cells generally had the morphology of Dogiel type-I enteric neurons, however, there was some diversity in the morphology of NADPH-d-positive neurons in the myenteric plexus of the pylorus. Intramuscular ganglia were observed in both sphincters, and NADPH-d was found in a sub-population of neurons within these ganglia. Dual staining with an antiserum raised against nitric oxide synthase (NOS) demonstrated that almost all cells with NOS-LI were also NADPH-d positive. Varicose fibers within ganglia and within the circular and longitudinal muscle layers also possed NOS-LI and NADPH-d activity. Dual staining with anti-VIP antibodies showed that some of the NADPH-d-positive cells in the myenteric and submucosal ganglia also contained VIP-LI, but all VIP-LI-positive cells did not express NADPH-d activity. These data are consistent with recent physiological studies suggesting that nitric oxide serves as an inhibitory neurotransmitter in the pyloric and ileocolonic sphincters. The data also suggest that VIP is expressed in a sub-population of NADPH-d-positive neurons and may therefore act as a co-transmitter in enteric inhibitory neurotransmission to these specialized muscular regions.

Accommodation mediated by enteric inhibitory reflexes in the isolated guinea-pig small intestine

1. The aim of the present study was to investigate whether the guinea-pig small intestine shows accommodation to infused fluid, similarly to other regions of the gastrointestinal tract. Tetrodotoxin, papaverine and transmitter antagonists were used to establish the existence of reflex pathways and the nature of the neurotransmitters involved. 2. Compliance, measured as the change in volume of infused fluid divided by the intraluminal pressure change, was reduced by tetrodotoxin (0.6 microM), indicating that there is an overall neurally mediated relaxation of the circular muscle in response to low rates of distension. Papaverine (10 microM) did not have any significant effect on compliance at the low rates of distension, suggesting that the circular muscle is fully relaxed. 3. At each rate of distension, 400 microM N omega-nitro-L-arginine methyl ester (L-NAME, a nitric oxide synthase inhibitor) significantly decreased the compliance of the intestinal wall, indicating that the circular muscle was relaxed by a nitric oxide-mediated mechanism. Apamin (0.5 microM), which blocks a component of inhibitory transmission, did not have a significant effect. 4. In control preparations, the intestinal wall was less compliant when distended by fluid at a fast rate, compared with the lower rates of distension. This was not due to changes in passive components of the intestinal wall or a myogenic response to rapid stretch. 5. When the intestine was distended rapidly, 1 microM hyoscine and 100 microM hexamethonium increased intestinal compliance. However, they had no detectable effect on compliance with low rates of distension.(ABSTRACT TRUNCATED AT 250 WORDS)

Effect of longitudinal muscle-myenteric plexus removal and indomethacin on the response to tachykinin NK-2 and NK-3 receptor agonists in the circular muscle of the guinea-pig ileum

1. The effect of removal of the longitudinal muscle-myenteric plexus (LM-MP) and/or indomethacin (10 microM) on the response to the tachykinin NK-2 receptor selective agonist, [beta Ala8]NKA(4-10), or to the NK-3 receptor selective agonist, senktide, was investigated by measuring mechanical activity (isotonic recording) of circular muscle (ring preparation) of the guinea-pig ileum. 2. Indomethacin (10 microM) increased the percentage of ileal rings displaying spontaneous activity, either intact or LM-MP-free. The response to senktide (10 nM and 1 microM) was lower in LM-MP-free than in intact ileal rings, either in the absence or presence of indomethacin. The response to a low concentration (10 nM) of [beta Ala8] NKA (4-10) was enhanced in LM-MP-free rings and by indomethacin. 3. In intact ileal rings, the response to senktide was unaffected by atropine (3 microM) alone or by the tachykinin NK-2 receptor antagonist MEN 10,376 (10 microM) alone while it was reduced by the combined administration of the two antagonists. The response to senktide was greatly reduced by tetrodotoxin (TTX, 1 microM). Senktide-induced contractions (10 nM) were also reduced by the blocker of N-type voltage-sensitive calcium channels, omega-contoxin (CTX, 0.1 microM). 4. In about 30% of preparations tested, an inhibitory response (decrease in spontaneous activity) to 10 nM senktide, was disclosed in CTX-treated intact ileal rings. This inhibitory effect was TTX-sensitive. 5. In LM-MP-free ileal rings, the response to senktide was abolished or reduced by atropine and MEN 10,376, alone or in combination, and was also reduced or abolished by TTX and CTX. 6. The response to [beta Ala8]NKA (4-10) was inhibited by MEN 10,376, in both intact and LM-MP-free ileal rings while it was unaffected by atropine, TTX or CTX. 7. These results indicate that indomethacin pretreatment induces a regular background activity for studying the motor response to tachykinins in the circular muscle of the ileum, probably by blocking the formation of relaxant prostanoids. A further increase in sensitivity to direct smooth muscle stimulation (NK-2 receptor agonist) can be obtained by removal of the LM-MP. The response to NK-3 receptor stimulation is diminished but not abolished by removal of the LM-MP, suggesting that NK-3 receptors are located on neuronal bodies of myenteric neurons, but possibly also at other sites (possibly, nerve terminals).(ABSTRACT TRUNCATED AT 400 WORDS)

Role of 5-HT3 receptors in peristaltic reflex elicited by stroking the mucosa in the canine jejunum

1. The role played by the 5-HT3 receptor, a serotonin subtype receptor, in peristaltic reflexes was studied in dogs first given ketamine, then anaesthetized with urethane (1.0 g kg-1, I.V.) and alpha-chloralose (100 mg kg-1, I.V.). The jejunal loop was partitioned into two segments with respect to blood supply. Drugs were infused intra-arterially into each segment. 2. Stroking of the mucosa of the aboral and oral segments elicited an ascending contraction and a descending relaxation, respectively. 3. The ascending contraction was concentration-dependently inhibited by treatment of the aboral segment with the 5-HT3 receptor antagonists ICS 205-930 and ondansetron (1.4 pmol min-1 to 14 nmol min-1 for both). The maximal inhibition was 49.5 and 69.3%, respectively. The response was not affected by treatment of the oral segment with these drugs. The descending relaxation was inhibited by 51.4 and 60.8%, respectively, by treatment of the oral segment with ICS 205-930 and ondansetron (1.4 nmol min-1 for both). 4. The ascending contraction was markedly inhibited by treatment of either segment with hexamethonium (140 nmol min-1). The response was abolished by treating both segments with hexamethonium and by treating the oral segment with atropine (14 nmol min-1). 5. These results suggest firstly that, in the canine jejunum, enteric neurons with 5-HT3 receptors play a role as sensory neurons or interneurons in the ascending excitatory and the descending inhibitory pathways of the peristaltic reflex elicited by stroking the mucosa, and secondly, that the ascending limb is composed of cholinergic interneurons and motoneurons.

Neuronal nitric oxide in the gut

Motility of the gastrointestinal tract is directly controlled by enteric inhibitory and excitatory motor neurons that innervate the layers of smooth muscle. Inhibitory motor neurons mediate receptive and accommodative relaxations and control the opening of sphincters, thus playing an important role in normal gut motility. Recent studies have demonstrated that nitric oxide (NO) is an important neurotransmitter released by inhibitory motor neurons in animal and human gut. Antagonists of nitric oxide synthase (NOS), the synthetic enzyme for NO, reduce the effectiveness of transmission from inhibitory motor neurons. Exogenous NO mimics inhibitory nerve activation, and a variety of compounds that affect the availability of endogenously produced NO modulate relaxations of gastrointestinal smooth muscle. It is clear, however, that NO is unlikely to be the only transmitter released by enteric inhibitory motor neurons: several other substances such as vasoactive intestinal polypeptide (VIP), or related peptides, and adenosine triphosphate (ATP) are also likely to contribute to nerve-mediated inhibition. The identification of NO as a major inhibitory neurotransmitter to gastrointestinal smooth muscle fills an important gap in our understanding of the physiological control of motility and opens up a wide range of new experimental possibilities. It may eventually lead to the development of new drugs for motility disorders. It should be noted, however, that NO is important in the brain, in cardiovascular control, in blood cell function and in many other organ systems, suggesting that it may be difficult to achieve specific pharmacological intervention targeted on inhibitory neurotransmission in the gut, without undesirable side effects.

Simultaneous intracellular recordings from enteric neurons reveal that myenteric AH neurons transmit via slow excitatory postsynaptic potentials

Simultaneous intracellular electrical recordings were made from pairs of neurons separated circumferentially by 100-200 microns of the myenteric plexus of the guinea-pig ileum in vitro. The recording electrodes were filled with the dye neurobiotin which was injected into impaled nerve cells, and later revealed histochemically. Intracellular current pulses were used to evoke action potentials via the recording electrode in one type of myenteric neuron, in most cases an AH neuron, while a second electrode was used to record from a simultaneously impaled S neuron or AH neuron. AH neurons are thought to be primary sensory neurons, whereas S neurons are interneurons and motor neurons. Ninety pairs of neurons were adequately tested for interaction. From these, 17 S neurons and three AH neurons that responded to AH neuron stimulation were detected. In each case, the response was a slow depolarization that was seen only in response to a train of stimuli at 10 Hz. The slow depolarizations were enhanced by passing depolarizing current and diminished by hyperpolarization. Responses were also diminished by lowering external Ca.2+ and elevating Mg2+. In all cases in which intracellular recording indicated communication between neurons, morphological evidence of connection was seen. In no case was there communication without connection, but in four instances, morphological connections appeared to exist, although no physiological evidence of communication was obtained.

Structure of the tertiary component of the myenteric plexus in the guinea-pig small intestine

The tertiary component of the myenteric plexus consists of interlacing fine nerve fibre bundles that run between its principal ganglia and connecting nerve strands. It was revealed by zinc iodide-osmium impregnation and substance P immunohistochemistry at the light-microscope level. The plexus was situated against the inner face of the longitudinal muscle and was present along the length of the small intestine at a density that did not vary markedly from proximal to distal. Nerve bundles did not appear to be present in the longitudinal muscle as judged by light microscopy, although numerous fibre bundles were encountered within the circular muscle layer. At the ultrastructural level, nerve fibre bundles of the tertiary plexus were found in grooves formed by the innermost layer of longitudinal smooth muscle cells. In the distal parts of the small intestine, some of these nerve fibre bundles occasionally penetrated the longitudinal muscle coat. Vesiculated profiles in nerve fibre bundles of the tertiary plexus contained variable proportions of small clear and large granular vesicles; they often approached to within 50-200 nm of the longitudinal smooth muscle cells. Fibroblast-like cells lay between strands of the tertiary plexus and the circular muscle but were never intercalated between nerve fibre varicosities and the longitudinal muscle. These anatomical relationships are consistent with the tertiary plexus being the major site of neurotransmission to the longitudinal muscle of the guinea-pig small intestine.

Regulation of neural responses in the canine pyloric sphincter by opioids

1. Regulation of excitatory and inhibitory junction potentials (e.j.ps and i.j.ps) by opioid peptides was studied in isolated muscle strips from the pyloric sphincter of the dog. 2. Methionine enkephalin (MetEnk; 10(-10) to 10(-6) M) and [D-Ala2, D-Leu5] enkephalin (DADLE; 10(-11) to 10(-7) M), a delta-specific opioid agonist, inhibited i.j.ps and e.j.ps recorded from cells in the myenteric and submucosal regions of the circular muscle layer. These compounds had no effect on resting potential or slow wave activity suggesting that the effects on junction potentials were not due to direct effects on smooth muscle cells. 3. MetEnk and DADLE caused similar effects on junction potentials in preparations in which the myenteric plexus was removed, suggesting that opioids inhibit pre-junctional effects on nerve fibres within the muscularis externa. 4. Inhibition of junction potentials by MetEnk and DADLE was blocked by approximately the same extent by naloxone (10(-6) M) and ICI 174,864 (10(-6) M), a delta-specific antagonist. 5. MetEnk and DADLE blocked a portion of the i.j.p. that was sensitive to arginine analogues; after treatment with N omega-nitro-L-arginine methyl ester (L-NAME, 10(-4) M), MetEnk and DADLE had no further effect on i.j.ps. These data suggest that opioids regulate nitric oxide-dependent neurotransmission. 6. Naloxone (10(-6) M) alone had no effect on i.j.ps elicited by short trains of electrical field stimuli. 7. I.j.p. amplitude was reduced after a period of conditioning stimulation (2 min, 30 Hz, 30 V). Naloxone blocked the post-stimulation inhibition. Repetitive stimulation at high frequencies (30 Hz) resulted in sustained hyperpolarization. Naloxone increased the amplitude of the hyperpolarization responses elicited by high frequency stimulation.8. These results show that e.j.ps and i.j.ps in the canine pylorus are inhibited by opioids. A portion of the inhibitory effects appears to be mediated via delta receptors.9. Although pyloric muscles are richly innervated by nerves containing opioid peptides, brief trains of stimuli do not appear to release concentrations of opioids that are effective in regulating junction potentials. Higher frequency stimulation (or longer durations of stimulation) appear to be necessary to release concentrations of opioids that are effective in modulating the amplitude of junction potentials.

Total numbers of neurons in myenteric ganglia of the guinea-pig small intestine

Two techniques that are thought to stain all of the neurons in the myenteric ganglia of the intestine are NADH diaphorase histochemistry and immunohistochemistry using a "nerve cell body" antiserum. However, this assumption has never been directly verified. In the present study myenteric ganglia of the guinea-pig ileum were prepared as whole-mounts and stained with either of these techniques. All nerve cells that could be identified in the whole-mounts were counted. The whole-mounts were then embedded flat in resin and serially sectioned at 1 micron. Nerve cells were identified and counted from the serial sections, and the data compared to those obtained from the whole-mounts. NADH diaphorase histochemistry did not reveal all the neurons at incubation times that gave selective staining. In contrast, "nerve cell body" antiserum stained the entire neuronal population. To determine the total number of nerve cell bodies/ganglion and the proportion of nerve cell bodies with calbindin immunoreactivity, whole-mounts that had been processed for calbindin immunohistochemistry were serially sectioned and reconstructed. The total number of neurons per myenteric ganglion was 105 +/- 10 (SE). Calbindin-immunoreactive neurons comprised about 20% of the myenteric neurons, which is considerably less than previous estimates, because previously the total population has been underestimated. The spatial density of myenteric neurons in the undistended ileum of the guinea-pig is 17,300 nerve cells/cm2.

Analysis of a nonpeptide antagonist for substance P on myenteric neurons of guinea-pig small intestine

CP-96,345 [(2S,3S)-cis-2-(diphenylmethyl)-N-[(2-methoxyphenyl)-methyl]- 1-azabicyclo[2.2.2.]octan-3-amine], a novel nonpeptide antagonist of the substance P receptor, was evaluated for blocking action at substance P receptors on myenteric neurons of guinea-pig small intestine. Intracellular electrophysiological recording was used to determine actions of the drug on excitatory responses to substance P, on slow and fast excitatory postsynaptic potentials and action potential initiation and propagation in the neurons. CP-96,345 suppressed responses to substance P. It also suppressed spike initiation and propagation in the neuronal processes, as well as in the somal membranes. The effects of the drug on substance P responses could not be attributed to an action at substance P receptors. The mechanism of action appeared to be a nonselective local anesthetic effect on initiation and propagation of action potentials.

Projections of nitric oxide synthesizing neurons in the guinea-pig colon

The neuronal form of the enzyme nitric oxide synthase, which is an obligatory constituent of neurons that utilise nitric oxide as a transmitter, was revealed histochemically in this study by its ability to transfer a proton from reduced nicotinamide adenine dinucleotide phosphate to nitro-blue tetrazolium. In the guinea-pig colon, nitric oxide synthase was located in numerous irregularly-shaped myenteric neurons with single axons. In the submucosa, a small number of neurons had strong enzyme activity, whereas many were weakly stained. Nerve fibres were found in the longitudinal muscle, circular muscle, muscularis mucosae and ganglia of the two plexuses. No nerve fibres were found in the lamina propria of the mucosa. The same distribution of nerve cells and fibres was revealed using immunohistochemistry for nitric oxide synthase. Lesion studies showed that the axons of myenteric neurons all projected anally. Myenteric cells were the source of nerve fibres in the circular muscle and in more anally located myenteric ganglia. The sparse innervation of submucous ganglia was intrinsic to the submucous plexus. It is suggested that nitric oxide synthase is one of the transmitters of inhibitory neurons to the muscle and is also utilized by descending interneurons of the myenteric plexus.

Projections and chemical coding of neurons with immunoreactivity for nitric oxide synthase in the guinea-pig small intestine

The distribution of nitric oxide synthase (NOS) immunoreactivity was investigated in the guinea-pig small intestine. There were many immunoreactive nerve cell bodies in the myenteric plexus but very few in submucous ganglia. NOS immunoreactivity was not found in non-neuronal cells except for rare mucosal endocrine cells. Abundant immunoreactive nerve fibres in both myenteric and submucous ganglia, and in the circular muscle, arose from myenteric nerve cells whose axons projected anally along the intestine. NOS immunoreactivity coexisted with VIP-immunoreactivity, but not with substance P immunoreactivity. We conclude that nitric oxide synthase is located in a sub-population of enteric neurons, amongst which are inhibitory motor neurons that supply the circular muscle layer.