Movement of villi induces endocytosis of NK1 receptors in myenteric neurons from guinea-pig ileum

Agitation of villi evokes reflexes that affect the motility of the guinea-pig small intestine. NK1 receptor endocytosis was used to investigate the possible involvement of tachykinins acting on neuronal NK1 receptors in these reflexes. Segments of guinea-pig ileum were incubated at 37°C in Krebs physiological saline containing 3×10^–6 M nicardipine, with or without agitation of the villi by gas bubbles. Gut segments were fixed after 0–75 min and processed for immunohistochemistry to reveal the NK1 receptors, following which cells were imaged by confocal microscopy. Initially, receptors were located on the surface and in the cytoplasm of myenteric neurons. In gut incubated without movement of the villi, NK1 receptors returned to the cell surface. After 45 and 60 min, NK1 receptors were detected almost exclusively at the cell surface of 83% and 97% (respectively) of nerve cells that were immunoreactive for NK1 receptors and only 12%–13% of the NK1 receptor fluorescence was located in the cytoplasm. Following the return of receptor to the cell surface, agitation of the villi caused a new wave of endocytosis of the NK1 receptors in 70%–80% of the NK1 receptor-immunoreactive neurons. The percentage of the NK1 receptor fluorescence that was in the cytoplasm increased more than 2-fold to 27±2% after 15 min villous agitation. Action potential blockade by tetrodotoxin (3×10^–7 M) prevented the internalisation of the NK1 receptor in response to villous agitation. The degree of internalisation caused by bubbling was similar to that caused by 2×10^–9 M substance P. These results indicate that, when enteric reflex circuits are activated by villous movement, tachykinins are released and cause endocytosis of the NK1 receptor in a subpopulation of myenteric neurons.     

Mucosal stimulation activates secretomotor neurons via long myenteric pathways in guinea pig ileum

This study examined whether mucosal stimulation activates long secretomotor neural reflexes and, if so, how they are organized. The submucosa of in vitro full thickness guinea pig ileal preparations was exposed in the distal portion and intracellular recordings were obtained from electrophysiologically identified secretomotor neurons. Axons in the intact mucosa of the oral segment were stimulated by a large bipolar stimulating electrode. In control preparations, a single stimulus pulse evoked a fast excitatory postsynaptic potential (EPSP) in 86% of neurons located 0.7-1.0 cm anal to the stimulus site. A stimulus train evoked multiple fast EPSPs, but slow EPSPs were not observed. To examine whether mucosal stimulation specifically activated mucosal sensory nerve terminals, the mucosa/submucosa was severed from the underlying layers and repositioned. In these preparations, fast EPSPs could not be elicited in 89% of cells. Superfusion with phorbol dibutyrate enhanced excitability of sensory neurons and pressure-pulse application of serotonin to the mucosa increased the fast EPSPs evoked by mucosal stimulation, providing further evidence that sensory neurons were involved. To determine whether these reflexes projected through the myenteric plexus, this plexus was surgically lesioned between the stimulus site and the impaled neuron. No fast EPSPs were recorded in these preparations following mucosal stimulation whereas lesioning the submucosal plexus had no effect. These results demonstrate that mucosal stimulation triggers a long myenteric pathway that activates submucosal secretomotor neurons. This pathway projects in parallel with motor and vasodilator reflexes, and this common pathway may enable coordination of intestinal secretion, blood flow, and motility.     

Myenteric neurons activate submucosal vasodilator neurons in guinea pig ileum

This study examined whether myenteric neurons activate submucosal vasodilator pathways in in vitro combined submucosal-myenteric plexus preparations from guinea pig ileum. Exposed myenteric ganglia were electrically stimulated, and changes in the outside diameter of submucosal arterioles were monitored in adjoining tissue by videomicroscopy. Stimulation up to 18 mm from the recording site evoked large TTX-sensitive vasodilations in both orad and aborad directions. In double-chamber baths, which isolated the stimulating myenteric chamber from the recording submucosal chamber, hexamethonium or the muscarinic antagonist 4-diphenylacetoxy-N-(2-chloroethyl)-piperdine hydrochloride (4-DAMP) almost completely blocked dilations when superfused in the submucosal chamber. When hexamethonium was placed in the myenteric chamber approximately 50% of responses were hexamethonium sensitive in both orad and aboard orientations. The addition of 4-DAMP or substitution of Ca(2+)-free, 12 mM Mg(2+) solution did not cause further inhibition. These results demonstrate that polysynaptic pathways in the myenteric plexus projecting orad and aborad can activate submucosal vasodilator neurons. These pathways could coordinate intestinal blood flow and motility.     

Local inhibitory reflexes excited by mucosal application of nutrient amino acids in guinea pig jejunum

The motility of the gut depends on the chemicals contained in the lumen, but the stimuli that modify motility and their relationship to enteric neural pathways are unclear. This study examined local inhibitory reflexes activated by various chemical stimulants applied to the mucosa to characterize effective physiological stimuli and the pathways they excite. Segments of the jejunum were dissected to allow access to the circular muscle on one-half of the preparation while leaving the mucosa intact on the circumferentially adjacent half. Chemicals were transiently applied to the mucosa, and responses were recorded intracellularly in nearby circular muscle cells. The amino acids l-phenylalanine, l-alanine, or l-tryptophan (all 1 mM) evoked inhibitory junction potentials (IJPs; latency 150-300 ms, amplitude 3-8 mV, each n > 6) that were blocked by TTX and partially blocked by antagonists of P2X receptors and/or a combination of antagonists at 5-HT(3) and 5-HT(4) receptors. The putative mediators 5-HT (10 microM), ATP (1 mM), and CCK-8 (1-10 microM) elicited IJPs mediated via 5-HT(3), P2X, and CCK-B receptors, respectively. Responses were only partially reduced by the effective antagonists. IJPs evoked by electrically stimulating the mucosa were unaffected by antagonists that reduced chemically evoked responses. Both chemically and electrically evoked IJPs were resistant to nicotinic, NK(1), NK(3), alpha-amino-3-hydroxy-5-methylisoxazole-4-propionic acid, N-methyl-d-aspartate, or CGRP receptor blockade. We conclude that mucosal stimulation by amino acids activates local neural pathways whose pharmacology depends on the nature of the stimulus. Transmitters involved at some synapses in these pathways remain to be identified.     

Interleukin-1beta activates specific populations of enteric neurons and enteric glia in the guinea pig ileum and colon

Fos expression was used to assess whether the proinflammatory cytokine interleukin-1beta (IL-1beta) activated specific, chemically coded neuronal populations in isolated preparations of guinea pig ileum and colon. Whether the effects of IL-1beta were mediated through a prostaglandin pathway and whether IL-1beta induced the expression of cyclooxygenase (COX)-2 was also examined. Single- and double-labeling immunohistochemistry was used after treatment of isolated tissues with IL-1beta (0.1-10 ng/ml). IL-1beta induced Fos expression in enteric neurons and also in enteric glia in the ileum and colon. For enteric neurons, activation was concentration-dependent and sensitive to indomethacin, in both the myenteric and submucosal plexuses in both regions of the gut. The maximum proportion of activated neurons differed between the ileal (approximately 15%) and colonic (approximately 42%) myenteric and ileal (approximately 60%) and colonic (approximately 75%) submucosal plexuses. The majority of neurons activated in the myenteric plexus of the ileum expressed nitric oxide synthase (NOS) or enkephalin immunoreactivity. In the colon, activated myenteric neurons expressed NOS. In the submucosal plexus of both regions of the gut, the majority of activated neurons were vasoactive intestinal polypeptide (VIP) immunoreactive. After treatment with IL-1beta, COX-2 immunoreactivity was detected in the wall of the gut in both neurons and nonneuronal cells. In conclusion, we have found that the proinflammatory cytokine IL-1beta specifically activates certain neurochemically defined neural pathways and that these changes may lead to disturbances in motility observed in the inflamed bowel.     

Chemical coding of neurons expressing δ- and κ-opioid receptor and type I vanilloid receptor immunoreactivities in the porcine ileum

Opioid drugs have profound antidiarrheal and constipating actions in the intestinal tract and are effective in mitigating abdominal pain. Mediators of intestinal inflammation and allergy produce increased mucosal secretion, altered bowel motility and pain due to their ability to evoke enteric secretomotor reflexes through primary afferent neurons. In this study, the distribution of delta- and kappa-opioid receptor (DOR and KOR, respectively) immunoreactivities in chemically identified neurons of the porcine ileum was compared with that of the capsaicin-sensitive type 1 vanilloid receptor (VR1). DOR and VR1 immunoreactivities were observed to be highly localized in choline acetyltransferase (ChAT)- and calcitonin gene-related peptide (CGRP)-positive neurons and nerve fibers of the submucosal and myenteric plexuses and both receptors exhibited frequent colocalization. In the inner submucosal plexus, they also were colocalized in substance P (SP)-positive neurons. Neurons in the outer submucosal plexus expressed DOR immunoreactivity alone or in combination with VR1. KOR-immunoreactive neurons were found only in the myenteric plexus; these cells coexpressed immunoreactivity to ChAT, CGRP, vasoactive intestinal peptide (VIP) or nitric oxide synthase (NOS). In addition, some KOR-positive neurons coexpressed immunoreactivities to DOR and VR1. Based on their neurochemical coding, opioid and vanilloid receptor-immunoreactive neurons in the submucosal and myenteric plexuses may include primary afferents and constitute novel therapeutic targets for the palliation of painful intestinal inflammatory, hypersensitivity and dysmotility states.     

Immunohistochemical analysis of substance P-containing neurons in rat small intestine

The neuropeptide substance P (SP) is involved in the regulation of epithelial secretion and motility in the rat small intestine. The morphology, chemical profiles and proportion of SP-containing enteric neurons in this tissue have been examined by immunohistochemical analysis of whole-mount preparations obtained from colchicine-treated rats. In the submucosal plexus of the duodenum, jejunum and ileum, the proportion of SP-positive neurons is 53%, 51% and 49%, respectively. All SP-positive submucosal neurons are positive for neurofilament 200 (NF-200) and calretinin. Immunoreactivity for calcitonin gene-related peptide (CGRP) is detectable in 55% of the SP-positive submucosal neurons. Some SP-positive submucosal neurons have two or more long processes emerging from an oval or round cell body, a characteristic of the Dogiel type II neuron (type II neuron; a putative intrinsic primary afferent neuron). About one-third of the neurons in the myenteric plexus are positive for SP and a majority of them are NF-200/calretinin-positive type II neurons. Immunoreactivity for the SP receptor neurokinin-1 receptor (NK1R) has been detected mainly in the submucosal and myenteric NF-200-positive neurons, which are expected to contain SP. These neurons possibly stimulate each other via SP release. Most of the submucosal and myenteric neurons, including type II neurons, show immunoreactive for the prostaglandin E2 receptor EP3 receptor (EP3R). Thus, SP/NF-200/calretinin/NK1R/EP3R is the common chemical profile of type II neurons in the rat small intestine. The proportion of SP-immunopositive submucosal neurons (49%–53%) is higher in the rat small intestine than in the colon (≤11%) and around 50% are positive for CGRP.     

Cholecystokinin activates specific enteric neurons in the rat small intestine

Cholecystokinin (CCK) is a peptide hormone released from the I-cells of the upper small intestine. CCK evokes a variety of physiological responses, such as stimulation of pancreatic secretion, reduction of food intake and inhibition of gastric emptying. Previously, we reported that CCK activates enteric neurons in the rat. However the specific subpopulations of enteric neurons activated by CCK have not been identified. In the work reported here, we utilized immunohistochemical detection of nuclear Fos, a marker for neuronal activation, and selected phenotypic markers to identify some of the neuronal subpopulations activated by CCK. The phenotypic markers that we examined were: nitric oxide synthase (NOS), neurokinin-1 receptor (NK-1R), calbindin (Cal), Calretinin (Calr), and neurofilament-M (NF-M). We found that in the myenteric plexus of the rat duodenum and jejunum, CCK activated NOS immunoreactive neurons. In the submucosal plexus of duodenum and jejunum, CCK activated Cal, Calr and NF-M immunoreactive neurons. CCK failed to activate NK-1R immunoreactive neurons in either plexus. Our results indicate that CCK activates distinct enteric neurons in the rat upper small intestine. Furthermore the fact that NOS immunoreactive neurons were activated suggests that CCK modulates the activity of inhibitory motor neurons in the myenteric plexus. Expression of Fos immunoreactivity in Calr and Cal immunoreactive neurons is consistent with a role for CCK in modulation of intrinsic sensory and/or secretomotor neuronal activity in the submucosal plexus.     

Characterisation of calcitonin gene-related peptide-immunoreactive neurons in the myenteric plexus of rat colon

A mechanical or chemical stimulus applied to the intestinal mucosa induces motility reflexes in the rat colon. Enteric neurons containing calcitonin gene-related peptide (CGRP) have been suggested as intrinsic primary afferent neurons responsible for mediating such reflexes. In the present study, immunohistochemistry was performed on whole-mount stretch preparations to investigate chemical profiles, morphological characteristics and projections of CGRP-containing neurons in the myenteric plexus of the rat colon. CGRP-positive neuronal cell bodies were detected in preparations incubated with colchicine-containing medium, whereas CGRP-positive nerve fibres were found in colchicine-untreated preparations. These neurons had large oval or round cell bodies that were also immunoreactive for the calcium-binding protein calretinin and neurofilament 200. Myenteric neurons positive for both calretinin and neurofilament 200 had several long processes that emerged from the cell body, consistent with Dogiel type II morphology. Application of the neural tracer DiI to the intestinal mucosa revealed that DiI-labelled myenteric neurons each had an oval or round cell body immunoreactive for calretinin. Thus, CGRP-containing myenteric neurons are Dogiel type II neurons and are immunoreactive for calretinin and neurofilament 200 in the rat colon. These neurons probably project to the intestinal mucosa. This study was supported by a Waseda University Grant for Special Research Projects (2008A-889).     

Immunohistochemical characteristics of submucosal Dogiel type II neurons in rat colon

Secretory and motility reflexes are evoked by physiological stimuli in the isolated rat distal colon, which is therefore expected to contain intrinsic primary afferent (sensory) neurons. Dogiel type II neurons (putative intrinsic primary afferent neurons) exhibit several long processes emerging from large oval or round cell bodies. This study has examined the immunohistochemical characteristics of type II neurons in the submucosal plexus of rat distal colons by using whole-mount preparations. Neuronal cell bodies positive for both substance P (SP) and calretinin have been observed in colchicine-treated rats. Neurofilament 200 immunostaining has confirmed the type II morphology of SP-positive neurons. Moreover, all submucosal type II neurons identified by neurofilament 200 immunoreactivity are positive for calretinin. Calcitonin gene-related peptide (CGRP)-positive neurons in the submucosal plexus are distinct from type II neurons because they are negative for calretinin and have smaller cell bodies than the SP-positive submucosal type II neurons. Most (73%) of the submucosal neurons including type II neurons exhibit immunoreactivity for the neurokinin-1 receptor (NK1R), a receptor for SP, on the surface of cell bodies. Immunoreactivity for the EP3 receptor (EP3R), a receptor for prostaglandin E2, has been detected in 51% of submucosal neurons including type II neurons. Thus, submucosal type II neurons in the rat distal colon are immunopositive for SP/calretinin but immunonegative for CGRP. SP released from submucosal type II neurons probably acts via NK1Rs on type II and non-type II submucosal neurons to mediate intrinsic reflexes. EP3R-positive submucosal type II neurons may be potential targets of prostaglandin E2.     

Identification of the populations of enteric neurons that have NK1 tachykinin receptors in the guinea-pig small intestine

Simultaneous immunofluorescence labelling was used to investigate the patterns of colocalisation of the NK1 tachykinin receptor with other neuronal markers, and hence determine the functional classes of neuron that bear the NK1 receptor in the guinea-pig ileum. In the myenteric plexus, 85% of NK1 receptor-immunoreactive (NK1r-IR) nerve cells had nitric oxide synthase (NOS) immunoreactivity and the remaining 15% were immunoreactive for choline acetyltransferase (ChAT). Of the latter group, about 50% were immunoreactive for both neuropeptide Y (NPY) and somatostatin (SOM), and had the morphologies of secretomotor neurons. Many of the remaining ChAT neurons were immunoreactive for calbindin or tachykinins (TK), but not both. These calbindin immunoreactive neurons had Dogiel type II morphology. No NK1r-IR nerve cells in the myenteric plexus had serotonin or calretinin immunoreactivity. In the submucosal ganglia, 84% of NK1r-IR nerve cells had neuropeptide Y immunoreactivity and 16% were immunoreactive for TK. It is concluded that NK1r-IR occurs in five classes of neuron; namely, in the majority of NOS-immunoreactive inhibitory motor neurons, in ChAT/TK-immunoreactive excitatory neurons to the circular muscle, in all ChAT/NPY/SOM-immunoreactive secretomotor neurons, in a small proportion of ChAT/calbindin myenteric neurons, and in about 50% of ChAT/TK submucosal neurons.     

CCK-A receptor activation induces fos expression in myenteric neurons of rat small intestine

Cholecystokinin (CCK), a hormone secreted from endocrine cells of the small intestine, participates in the control of motility and secretion in the gastrointestinal tract, and in the control of food intake. At least some of the effects of CCK on intestinal function appear to be mediated via activation of intrinsic neurons in the myenteric plexus. However, the distribution of CCK-responsive enteric neurons within the rat small intestine is not known. Neither has the role of CCK-A receptors in the activation of rat myenteric neurons been investigated. Therefore, to determine the distribution of CCK-responsive neurons in the small intestinal myenteric plexus we utilized immunohistochemical detection of Fos, the protein product of the immediate early gene c-fos, to identify neurons that were activated by exogenous CCK. We also monitored Fos expression in the dorsal hindbrain, and examined CCK-induced Fos expression in the presence or absence of a receptor antagonist for the type-A CCK receptor. We found that CCK significantly increased Fos expression in the hindbrain and in myenteric neurons of the duodenum and jejunum, but not the ileum. Neuronal Fos responsiveness in both brain and myenteric neurons was mediated by CCK-A receptors, as CCK-induced Fos expression was eliminated in rats pretreated with a CCK-A receptor antagonist. We conclude that CCK activates small intestinal myenteric neurons, via CCK-A receptors. Activation of these intrinsic intestinal neurons may participate in reflexes and behaviors that are mediated by CCK.     

Occurrence,distribution and neurochemical features of small intestinal neurons projecting to the cranial mesenteric ganglion in the pig

The small intestine of the pig has been investigated for its topographical distribution of enteric neurons projecting to the cranial mesenteric ganglion, by using Fast Blue or Fluorogold as a retrogradely transported neuronal tracer. Contrary to the situation in small laboratory animals such as rat and guinea-pig, the intestinofugally projecting neurons in the porcine small intestine were not restricted to the myenteric plexus, but were observed in greater numbers in ganglia of the outer submucous plexus. The inner submucous plexus was devoid of labelled neurons. Retrogradely labelled neurons were mostly found, either singly or in small aggregates, in ganglia located within a narrow border on either side of the mesenteric attachment. For both nerve networks, their number increased from duodenum to ileum. All the retrogradely labelled neurons exhibited a multidendritic uniaxonal appearance. Some of them displayed type-III morphology and stained for serotonin. This study indicates that, in the pig, not only the myenteric plexus but also one submucous nerve network is involved in the afferent component of intestino-sympathico-intestinal reflex pathways. The finding that some of the morphologically defined type-III neurons participate in these reflexes is in accord with the earlier proposal that type-III neurons are supposed to fulfill an interneuronal role, whether intra- or extramurally.     

Neurochemical identification of enteric neurons expressing P2X(3) receptors in the guinea-pig ileum

It was hypothesised that P2X(3) receptors, predominantly labelling spinal and cranial sensory ganglionic neurons, are also expressed in intrinsic sensory enteric neurons, although direct evidence is lacking. The aim of this study was to localise P2X(3) receptors in the enteric nervous system of the guinea-pig ileum, and to neurochemically identify the P2X(3)-expressing neurons. In the submucous plexus, cholinergic neurons expressing calretinin (CRT), were immunostained for P2X(3). These neurons made up about 12% of the submucous neurons. In the myenteric plexus, approximately 36% of the neurons expressed P2X(3). Half of the latter neurons were immunoreactive for CRT, whereas about 20% were immunoreactive for nitric oxide synthase (NOS). Based on earlier neurochemical analysis of enteric neurons in the guinea-pig, the myenteric neurons exhibiting P2X(3)/CRT immunoreactivity were identified as longitudinal muscle motor neurons, and those expressing P2X(3)/NOS immunoreactivity as short inhibitory circular muscle motor neurons. In both plexuses, no colocalisation was observed between P2X(3) and calbindin, a marker for intrinsic sensory neurons. Multiple staining with antisera raised against somatostatin, neuropeptide Y, substance P or neurofilament protein did not reveal any costaining. It can be concluded that in the guinea-pig ileum, intrinsic sensory neurons do not express P2X(3) receptors. However, this does not negate the possibility that extrinsic sensory nerves expressing P2X(3) are involved in a purinergic mechanosensory transduction pathway as demonstrated in other organs.     

Calcitonin gene-related peptide-containing neurons supplying the rat digestive system: differential distribution and expression pattern.

In the enteric nervous system, calcitonin gene-related peptide (CGRP) immunoreactivity is localized to a substantial number of capsaicin-sensitive afferent fibers and to intrinsic neurons and processes. CGRP immunoreactivity detected by immunohistochemistry represents the expression of two distinct genes, the calcitonin/alpha-CGRP and the beta-CGRP genes, which have different tissue distributions. In the present study, we used (1) in situ hybridization histochemistry and ribonucleic acid (RNA) blot hybridization with RNA probes complementary to the divergent sequences of alpha- and beta-CGRP messenger RNAs (mRNAs) to differentiate which CGRP gene was expressed in enteric and afferent neurons; and (2) axonal transport approaches in combination with CGRP immunohistochemistry to define the location of CGRP-containing afferent neurons supplying the digestive system. In situ hybridization histochemistry with [35S]-labeled RNA probes indicated that in the gastrointestinal tract beta-CGRP mRNA, but not alpha-CGRP mRNA, was expressed in enteric neurons confined to the myenteric and submucous plexuses of the small and large intestine. In dorsal root and vagal sensory ganglia, mRNAs for alpha-CGRP and beta-CGRP were both present in a vast population of neurons, with an overlapping pattern, even though the alpha-CGRP signal appeared more intense. RNA blot hybridization analysis showed a single band of hybridization at 1.2 Kb with the beta-CGRP RNA probe in RNA extracts from muscle layer-myenteric plexus and submucosal layer preparations of the ileum, and from dorsal root ganglia; it also showed a single band at 1.3 Kb with the alpha-CGRP RNA probe in extracts from dorsal root ganglia, but not from the intestine. These findings further support the differential expression of alpha- and beta-CGRP mRNAs. Retrograde transport of fast blue or fluorogold coupled with CGRP immunohistochemistry demonstrated that the vast majority of CGRP-containing afferent neurons supplying the stomach, proximal duodenum, and pancreas were located in dorsal root ganglia at the middle and lower thoracic and at the upper lumbar levels, and represented a major component of the afferent innervation of these viscera (up to 89%). Approximately 50% of CGRP-immunoreactive afferent neurons also expressed tachykinin (TK) immunoreactivity, as shown by triple labeling. Only a minor component of the afferent innervation of the stomach, duodenum, and pancreas derived from vagal CGRP-containing neurons (less than 8%). A large portion of these neurons (an average of 62%) also contained TK immunoreactivity.(ABSTRACT TRUNCATED AT 400 WORDS)     

Localization of receptors for calcitonin-gene-related peptide to intraganglionic laminar endings of the mouse esophagus: peripheral interaction between vagal and spinal afferents?

The calcitonin-gene-related peptide (CGRP) receptor is a heterodimer of calcitonin-receptor-like receptor (CLR) and receptor-activity-modifying protein 1 (RAMP1). Despite the importance of CGRP in regulating gastrointestinal functions, nothing is known about the distribution and function of CLR/RAMP1 in the esophagus, where up to 90 % of spinal afferent neurons contain CGRP. We detected CLR/RAMP1 in the mouse esophagus using immunofluorescence and confocal laser scanning microscopy and examined their relationship with neuronal elements of the myenteric plexus. Immunoreactivity for CLR and RAMP1 colocalized with VGLUT2-positive intraganglionic laminar endings (IGLEs), which were contacted by CGRP-positive varicose axons presumably of spinal afferent origin, typically at sites of CRL/RAMP1 immunoreactivity. This provides an anatomical basis for interaction between spinal afferent fibers and IGLEs. Immunoreactive CLR and RAMP1 also colocalized in myenteric neurons. Thus, CGRP-containing spinal afferents may interact with both vagal IGLEs and myenteric neurons in the mouse esophagus, possibly modulating motility reflexes and inflammatory hypersensitivity.     

Calcitonin gene-related peptide-like immunoreactivity in the human small intestine.

Calcitonin-gene-related-peptide (CGRP)-like immunoreactivity was localized in nerve fibres, neuronal somata and in mucosal endocrine cells of the human small intestine. Immunoreactive enteric neurons were more numerous in the submucous plexuses than in the myenteric plexus. Morphologically, they predominantly had the appearance of type II neurons. The majority of the CGRP-like immunoreactive nerve fibres ran within the ganglionic nerve plexuses. Only a small proportion could be observed in the lamina propria, the lamina muscularis mucosae, or the circular and longitudinal outer smooth muscle layer. These findings suggest that within the wall of the human small intestine neuronal CGRP of either extrinsic or intrinsic origin exerts its effect chiefly on other enteric neurons, and might be indirectly involved in the regulatory functions of the human small intestine.     

Neurochemical classification of enteric neurons in the guinea-pig distal colon

Previous studies have identified the chemistries, shapes, projections and electrophysiological characteristics of several populations of neurons in the distal colon of the guinea-pig but it is unknown how these characteristics correlate to define the classes of neurons present. We have used double-label immunohistochemical techniques to identify neurochemically distinct subgroups of enteric neurons in this region. On the basis of colocalisation of neurochemical markers and knowledge gained from previous studies of neural projections, 17 classes of neurons were identified. The myenteric plexus contained the cell bodies of 13 distinct types of neurons. Four classes of descending interneurons and three classes of ascending interneurons were identified, together with inhibitory and excitatory motor neurons to both the circular and longitudinal muscle layers. Dogiel type II neurons, which are presumed to be intrinsic primary afferent neurons, were located in myenteric and submucosal ganglia; they were all immunoreactive for choline acetyltransferase and often calbindin and tachykinins. Three classes of secretomotor neurons with cell bodies in submucosal ganglia were defined. Two of these classes were immunoreactive for choline acetyltransferase and the other class was immunoreactive for both vasoactive intestinal peptide and nitric oxide synthase. Some of the secretomotor neurons probably also have a vasomotor function. The neural subtypes defined in the present study are similar in many respects to those found in the small intestine, although differences are evident, especially in populations of interneurons. These differences presumably reflect the differing physiological roles of the two intestinal regions.     

Patch clamp recording from enteric neurons in situ

The study of enteric neurons is key to understanding intestinal motility anGutn of therapeutic strategies for dealing with neurogenic disorders. However, enteric neurons have historically been inaccessible to patch-clamp recording. We report here the first technique that allows patch-clamp recording of neurons from the intact myenteric plexus of the mouse duodenum. The mucosa, submucosa and circular muscles are removed, exposing the myenteric plexus on the longitudinal muscle. Proteolytic treatment of exposed ganglia combined with gentle cell-surface cleaning allows gigaseal formation. Compared with previous studies using intracellular microelectrode recordings or cultured myenteric neurons, this technique provides an opportunity to explore properties of single or multiple ion channels in myenteric neurons in their native environment. The protocol-from the tissue preparation to patch-clamp recording-can be completed in ～4 h.