Changes in pituitary adenylate cyclase-activating Peptide 27-like immunoreactive nervous structures in the porcine descending colon during selected pathological processes

This study reports on changes in the pituitary adenylate cyclase-activating peptide 27-like immunoreactive (PACAP-27-LI) nerve structures of the enteric nervous system (ENS) in the porcine descending colon, caused by chemically induced inflammation, nerve injury, and proliferative enteropathy (PE), which is a "natural" inflammation of the porcine digestive tract. The distribution pattern of PACAP-27-LI structures was studied using the immunofluorescence technique in the circular muscle layer, enteric plexuses (i.e., myenteric plexus (MP), outer submucous plexus (OSP), and inner submucous plexus (ISP)), and in the mucosal layer. Under physiological conditions, PACAP-27-LI perikarya have been shown to constitute 4.04 ± 0.66, 6.66 ± 0.77, and 11.19 ± 0.74 % in the MP, OSP, and ISP, respectively. Changes in PACAP-27 immunoreactivity depended on the pathological factor studied. The numbers of the PACAP-27-LI perikarya amounted to 12.26 ± 1.43, 12.28 ± 0.79, and 21.13 ± 1.19 % in chemically induced colitis, 17.83 ± 0.88, 9.03 ± 1.05, and 20.72 ± 1.35 % during PE and 10.65 ± 0.82, 6.88 ± 1.04, and 14.04 ± 1.09 % after axotomy in MP, OSP, and ISP, respectively. All of the studied processes generally resulted in an increase in the number of PACAP-27-LI nerve fibers in the circular muscle and mucosal layers. The obtained results suggest that PACAP-27-LI nerve structures of ENS may participate in various pathological states within the porcine descending colon, and their functions probably depend on the type of pathological factor.

Neurochemical coding of the enteric nervous system in chagasic patients with megacolon

Neuronal destruction has been considered the hallmark of pathogenic mechanisms in chagasic megacolon. Characterization of neuropeptides in the enteric nervous system from chagasic patients with megacolon could elucidate some aspects of the development of this syndrome. In the present work we demonstrate the changes in expression of neuropeptides and neurochemical markers present in neuronal plexuses from the colons of chagasic patients with megacolon. Sections of frozen tissue samples were immunohistochemically labeled for anticalretinin, cChaT, substance P, VIP, NOS, and NPY. Immunoreactivity was observed using a confocal microscope. Our results demonstrate that in chagasic patients with megacolon, inhibitory motor neurons (VIP and NOS immunoreactive) are preferentially destroyed by Trypanosoma cruzi and/or the inflammatory process. These results suggest a selective destruction of enteric neurons in the colon of chagasic patients with megacolon, pointing to an important discovery in the mechanism of pathogenesis of Chagas' disease.

Chemical coding of submucosal type V neurons in porcine ileum

In this study, we attempted to determine the proportion of type V neurons relative to the putative whole neuron population in the two submucosal plexuses of pigs identified by their neurofilament immunoreactivity. The total neuron number was estimated in cuprolinic blue (CB)/anti-Hu protein (HU) costained wholemounts as the sum of the number of CB+/HU+, CB+/HU- and CB-/HU+ neurons. In the external submucosal plexus (ESP), HU labelled 98.6% and CB 97.3% of neurons. In the internal submucosal plexus, HU labelled 98.3%, whereas CB only marked 92.5% of neurons. Furthermore, we investigated the chemical coding of submucosal type V neurons and searched for submucosal, non-type V neurons displaying the same chemical coding as the myenteric type V neurons described earlier, i.e. the colocalization of calcitonin gene-related peptide (CGRP) and somatostatin (SOM). In order to facilitate immunohistochemical detection of neuroactive peptides, ileal segments were pretreated with colchicine prior to fixation. Type V neurons in the ESP occurred either as single cells displaying one or few prominent dendrite(s) or within aggregates displaying a dendritic tangle. In this plexus, type V neurons amounted to between 0.9 and 1.6% of all CB-stained neurons. ESP type V neurons displayed immunoreactivities for choline acetyl transferase (95.8%) and leucine-enkephalin (73.9%). All type V neurons were negative for neuronal nitric oxide synthase. Fifty-eight percent of ESP CGRP/SOM co-immunoreactive neurons displayed type V morphology, whereas 42% were non-type V neurons. Thus, the chemical coding of ESP type V neurons is in principal similar to that of the myenteric type V neurons described earlier. In the internal submucosal plexus, we found no type V neurons. In this plexus, 0.2% of all neurons counterstained with HU displayed CGRP/SOM coreactivity. As had been observed earlier concerning the myenteric type V neurons, ESP type V neurons were also closely apposed by conspicuous accumulations of boutons reactive for the same markers as the neurons themselves. Although we cannot exclude that axons of CGRP/SOM-reactive enteric, non-type V or extrinsic neurons end synaptically on type V neurons, we suggest that the main synaptic input to type V neurons originates from other type V neurons. This presents an argument for an interneuronal role of type V neurons.

Identification and localization of estrogen receptor alpha- and beta-positive cells in adult male and female mouse intestine at various estrogen levels

Although estrogen is implicated in the regulation of mammalian intestinal function, the presence and the distribution of estrogen receptor (ER)-positive cells in the intestine are still controversial. The present study was designed to localize ERalpha- and ERbeta-expressing cells in female and male mouse intestines immunohistochemically under various estrogen conditions, especially in female mice, ovariectomized as well at various phases of the estrous cycle. Western blot analysis detected both ERalpha (66-kDa band) and ERbeta (56-kDa band). Immunohistochemical staining of paraffin-embedded sections after antigen-retrieval treatment with autoclaving revealed staining for ERalpha in submucosal interstitial cells, and double staining identified these cells as a subtype of intestinal macrophages. The number of these cells varied according to the estrous cycle phase. Administration of 17beta-estradiol to ovariectomized mice resulted in a significant increase in the number of ERalpha-positive macrophages. On the other hand, the nuclei of nerve cells in Auerbach and Meissner plexuses were positive for both ERalpha and ERbeta, but the number of positive nerve cells was not affected by estrogen. Our results indicate that estrogen and estrogenic compounds may exert their actions on the intestine in two ways; one is through interstitial macrophages and the other is through intestinal neurons.

Topography and neurochemistry of the enteric ganglia in the proventriculus of the duck (Anas platyrhynchos)

The topographical distribution of the enteric ganglia has been investigated in the proventriculus of the duck using protein gene product 9.5 (PGP 9.5) immunohistochemistry. Myenteric ganglia were usually located between the outer longitudinal and the inner circular muscle layer. Submucous ganglia were sparsely distributed and seemed to be substituted by ganglia located in the tunica mucosa. The neurochemical profile of proventricular ganglion cells was also investigated using nicotinamide adenine dinucleotide phosphate reduced-diaphorase (NADPH-d)-histochemistry and pituitary adenylate cyclase activating peptide (PACAP)/galanin (Gal) double-labelling immunohistochemistry. The majority of mucosal ganglion cells were shown to contain the NADPH-d enzyme and both the investigated peptides. These findings provide evidence for the presence of a mucosal ganglionated plexus in the glandular stomach of birds. Moreover, the neurochemical characteristics of this plexus suggest that it plays an important role in regulating several mucosal functions and, in particular, the production and the composition of the gastric juice.

Expression of Tie-2 in human peripheral and autonomic nervous system

Tie-2, a tyrosine kinase receptor, is essential for vascular integrity by regulating cellular adhesion between pericytes and endothelial cells. The aim of this study was to identify sites of expression of Tie-2 other than the vasculature. Tie-2 expression was first detected in human colon by Western blotting and reverse-transcription-polymerase chain reaction (RT-PCR) in tissue extracts. The presence of the Tie-2 mRNA and protein was detected by immunohistochemistry and in situ hybridization in cells of the colon myenteric and submucosal plexus, in both neuronal and Schwann cells. Tie-2 protein was also found in the nervous system of the female urogenital tract. In the human sciatic nerve and schwannoma, RT-PCR, Western blotting and immunohistochemistry analysis further confirmed the presence of Tie-2 mRNA and protein in non-autonomic peripheral nervous tissue. In conclusion, using several approaches and tissues we have demonstrated the presence of Tie-2 in human peripheral and autonomic nervous tissue, suggesting a role for Tie-2 in neural tissue. Thus, attempts to disrupt the tumour vessels by manipulation of the Tie-2 system in tumours may result in side-effects in peripheral nerves.

Morphology and distribution of nitric oxide synthase-, neurokinin-1 receptor-, calretinin-, calbindin-, and neurofilament-M-immunoreactive neurons in the myenteric and submucosal plexuses of the rat small intestine

Characterization of the enteric neurons is vital for understanding their physiological role. We have used single and dual label fluorescence and peroxidase-based immunohistochemistry in myenteric and submucosal whole mounts from the rat small intestine to evaluate the morphology and distribution of enteric neurons immunoreactive for the following phenotypic antigens: neuronal nitric oxide synthase (NOS), neurokinin-1 receptor (NK-1R), calretinin (Calr), calbindin (Cal), and neurofilament-M (NF-M). NOS-immunoreactive neurons had Dogiel type I morphology, were abundant in the myenteric plexus compared to the submucosal plexus, and never coexpressed NK-1R immunoreactivity. NK-1R- and Calr-immunoreactive neurons had Dogiel type II morphology and were distributed comparably in both plexuses. NK-1R and Calr-immunoreactivity were coexpressed in many of the same neurons. Calbindin-immunoreactive neurons exhibited four distinct morphologies: small and large Dogiel type II neurons, Dogiel type I neurons, and small elongated neurons. These neurons were significantly fewer in number in the myenteric plexus compared to the submucosal plexus. Neurofilament-M-immunoreactive neurons had three morphologies, Dogiel type II neurons, small Dogiel type II neurons, and a less common subpopulation of small, elongated, multipolar neurons. These neurons were also fewer in number in the myenteric plexus compared to the submucosal plexus. The distribution of these phenotypic markers may assist future work that elucidates the functional activities of these enteric neurons such as control of intestinal motility and adaptation to the entry of gastric contents.

An immunohistochemical study of the organization of ganglia and nerve fibres in the mucosa of the porcine intestine

In order to elucidate the organization of the enteric nervous system in the mucous plexus, wholemounts from six intestinal regions in six pigs were studied by vasoactive intestinal peptide, substance P, nitric oxide synthase and neurofilament proteins immunohistochemistry. The mucous plexus of both large and small intestine contained ganglia and isolated neurons. They were many and comparably larger in the caecum and colon, few in the ileum, and fewer and smaller in the jejunum. The mucous plexus was subdivided into the lamina muscularis mucosae and lamina proprial subplexuses, and based on location the latter was subdivided further in order to clarify their variations with respect to the amount, sizes and shapes of ganglia and neurons, sizes and orientation of nerve strands and immunoreactivities. Ganglia were situated at different topographical levels in the lamina muscularis mucosae subplexus, outer proprial and interglandular proprial meshworks in the lamina proprial subplexus with the majority of ganglia occurring in the outer proprial meshwork. The mucous plexus in the intestine of the pig is thus a ganglionated plexus showing marked segmental variation in the amount of intramucosal ganglia and isolated nerve cells. These new observations, calls for a re-examination of the mucous plexus to elucidate the regulatory mechanisms of importance in mucosal functions and consideration of the mucous plexus in the intestine of the pig to be one of the major ganglionated plexuses.

Increased acid-sensing ion channel ASIC-3 in inflamed human intestine

OBJECTIVES

Acid-sensing ion channels (ASICs) are expressed by rat sensory neurons and may mediate pain associated with tissue acidosis after inflammation or injury. Our aim was to examine the molecular forms and localization of ASICs in human intestine and dorsal root ganglia using immunochemical techniques, and to measure the effects of inflammation and injury.

DESIGN AND METHODS

Inflamed Crohn's disease intestine and injured human dorsal root ganglia, with appropriate controls, were studied by Western blotting and immunohistochemistry, using specific affinity-purified ASIC antibodies.

RESULTS

In the Western blot, there was a significant three-fold increase in the mean relative optical density of the ASIC-3 55-kDa band (but not ASIC-1 or ASIC-2) in full-thickness inflamed intestine, as well as in separated muscle and mucosal layers. There was a corresponding trend for an increased immunoreactive density and increased number of ASIC-3-positive neurons in the myenteric and sub-mucous plexus of inflamed intestine. In dorsal root ganglia, immunoreactivity for all ASICs was restricted to a sub-population (about 50%) of small-diameter (nociceptor) sensory neurons, and was generally less intense after injury.

CONCLUSIONS

Increased ASIC-3 in inflamed intestine suggests a role in pain or dysmotility, for which ASICs represent new therapeutic targets.

Calbindin immunoreactivity of enteric neurons in the guinea-pig ileum

Previous studies have identified Dogiel type II neurons with cell bodies in the myenteric plexus of guinea-pig ileum to be intrinsic primary afferent neurons. These neurons also have distinctive electrophysiological characteristics (they are AH neurons) and 82-84% are immunoreactive for calbindin. They are the only calbindin-immunoreactive neurons in the plexus. Neurons with analogous shape and electrophysiology are found in submucosal ganglia, but, with antibodies used in previous studies, they lack calbindin immunoreactivity. An antiserum that is more effective in revealing calbindin in the guinea-pig enteric nervous system has been reported recently. In the present work, we found that this antiserum reveals the same population that was previously identified in myenteric ganglia, and does not reveal any further population of myenteric nerve cells. In submucosal ganglia, 9-10% of nerve cells were calbindin immunoreactive with this antiserum. The submucosal neurons with calbindin immunoreactivity were also immunoreactive for choline acetyltransferase, but not for neuropeptide Y (NPY) or vasoactive intestinal peptide (VIP). Small calbindin-immunoreactive neurons (average profile 130 microm2) were calretinin immunoreactive, whereas the large calbindin-immunoreactive neurons (average profile 330 microm2) had tachykinin (substance P) immunoreactivity. Calbindin immunoreactivity was seen in about 50% of the calretinin neurons and 40% of the tachykinin-immunoreactive submucosal neurons. It is concluded that, in the guinea-pig ileum, only one class of myenteric neuron, the AH/Dogiel type II neuron, is calbindin immunoreactive, but, in the submucosal ganglia, calbindin immunoreactivity occurs in cholinergic, calretinin-immunoreactive, secretomotor/vasodilator neurons and AH/Dogiel type II neurons.

Evidence supporting presence of two pacemakers in rat colon

Intracellular microelectrodes and organ bath techniques were used to study spontaneous cyclic electrical and mechanical activity in the rat colon. Electron microscopy and immunohistochemical studies showed two major populations of interstitial cells of Cajal (ICC): one associated with Auerbach's plexus (ICC-AP) and one with the submuscular plexus (ICC-SMP). The ICC-SMP network partly adhered to the submucosa when removed and was generally strongly damaged after separation of musculature and submucosa. Similarly, longitudinal muscle removal severely damaged AP. Two electrical and mechanical activity patterns were recorded: pattern A, low-frequency (0.5--1.5 cycles/min), high-amplitude oscillations; and pattern B, high-frequency (13--15 cycles/min), low-amplitude oscillations. Pattern A was recorded in preparations with intact AP but absent in those without intact AP. Pattern B was recorded in preparations with intact SMP but was absent in those lacking SMP. With full-thickness strips, the superimposed patterns A and B were recorded in circular muscle. When longitudinal muscle mechanical activity was recorded, only pattern A was present. We conclude that two pacemakers regulate rat colonic cyclic activity: the ICC-SMP network (responsible for cyclic slow waves and small-amplitude contractions) and the ICC-AP network (which may drive the cyclic depolarizations responsible for high-amplitude contractions). This is the first report showing consistent slow wave activity in the rodent colon.

Development of the submucous plexus in the large intestine of the mouse

In the small intestine of both embryonic birds and mammals, neuron precursors aggregrate first at the site of the myenteric plexus, and the submucous plexus develops later. However, in the large intestine of birds, the submucosal region is colonised by neural-crest-derived cells before the myenteric region (Burns and Le Douarin, Development 125:4335-4347, 1998). Using antisera that recognize undifferentiated neural-crest-derived cells (p75NTR) and differentiated neurons (PGP9.5), we examined the colonisation of the murine large intestine by neural-crest-derived cells and the development of the myenteric and submucosal plexuses. At E12.5, when the neural crest cells were migrating through and colonising the hindgut, the hindgut mesenchyme was largely undifferentiated, and a circular muscle layer could not be discerned. Neural-crest-derived cells migrated through, and settled in, the outer half of the mesenchyme. By E14.5, neural-crest-derived cells had colonised the entire hindgut; at this stage the circular muscle layer had started to differentiate. From E14.5 to E16.5, p75NTR- and PGP9.5-positive cells were observed on the serosal side of the circular muscle, in the myenteric region, but not in the submucosal region. Scattered, single neurons were first observed in the submucosal region around E18.5, and groups of neurons forming ganglia were not observed until after birth. The development of the enteric plexuses in the murine large intestine therefore differs from that in the avian large intestine.

Tissue culture of the enteric nervous system from equine ileum

Ileal samples were harvested fresh from euthanized adult horses. The tissues were microdissected to prepare wholemount preparations for immunohistochemistry and for either explant or dissociated culture systems of the enteric nervous system. Explant culture systems were established using whole-mounts of either the submucous plexus or the muscularis externa (including the myenteric plexus). Dissociated cell cultures could only be obtained from the submucous plexus. Culture systems were maintained for up to 5 days. Immunoreactivity for a neuronal marker (Pan-N) and for glial cell markers (GFAP and S100) indicated the presence of both neurons and enteric glia in the tissue culture preparations. This is the first report of equine enteric neurons being grown in tissue culture Further refinements to the techniques will be required before this in vitro model can be used for quantitative analysis.

The nervous system of the chicken proventriculus: an immunocytochemical and ultrastructural study

The proventriculus constitutes the glandular region of the chicken stomach. This organ is innervated by two parasympathetic networks, the myenteric and submucous plexus, and here we present a systematic study of this system by immunohistochemistry and electron microscopy. All the neurons and fibres were positive for the neural markers, protein gene product 9.5 and the amidating enzymes. Immunoreactivities for the constitutive neuronal isoform of the enzyme nitric oxide synthase and the vasoactive intestinal peptide were present in neuronal bodies suggesting an intrinsic origin for the similarly immunoreactive fibres found in the proventriculus. On the other hand, immunoreactivity to gastric inhibitory peptide was only found in varicose fibres making contact with the blood vessels and the glandular epithelium, but never in the neuronal somas, suggesting that this substance may be provided by an extrinsic nervous system whose neuronal bodies are located elsewhere. Electron microscopy revealed frequent neuromuscular and neuroepithelial connections in the muscle layers, the wall of the blood vessels and the epithelium. In addition, synapsis-like structures were identified in the proximity of cells belonging to the diffuse endocrine system, providing a new example of neuroendocrine contacts. No positivity was found for antibodies against other neural substances including somatostatin, peptide histidine-isoleucine, peptide tyrosine-tyrosine, neuropeptide tyrosine, bombesin, met-enkephalin, serotonin, substance P, galanin, calcitonin gene-related peptide and S-100 protein.

Expression of the GDNF receptors ret and GFRalpha1 in the developing avian enteric nervous system

The formation of the enteric nervous system (ENS) from neural crest-derived cell precursors requires the growth factor glial cell line-derived neurotrophic factor (GDNF) and the receptors Ret and GDNF family receptor alpha 1 (GFRalpha1). We investigated the location(s), the timing, and the extent to which these GDNF receptors appear in the population of crest-derived precursors that form the avian ENS using immunohistochemistry and in situ hybridization. Sections and whole mounts of embryonic chick gastrointestinal tract were costained with antibodies to the receptors and to HNK-1, a marker for crest-derived cells. Neural crest-derived precursors migrate through the primitive esophagus to colonize the gizzard where an extensive cellular network forms. Ret-immunoreactivity (ir) was found in a network of cells in the gizzard at embryonic day (E)3.5. As development proceeded, Ret-immunoreactive cells appeared at progressively more caudal positions and were present in the colon at E7.5. Costaining with Ret and HNK-1 was performed to determine the number of Ret-immunoreactive cells in the crest-derived population. Ret appeared in some HNK-1 cells in the esophagus and gizzard at embryonic day (E)3.5. During development, the number of crest cells with Ret increased in the ganglia of the gizzard and small intestine. GFRalpha1-ir was also found in HNK-1 cells in the esophagus at E3.5 but did not appear in the gizzard until E4.5. Surprisingly, the colonizing vanguard of crest-derived cells lacked both Ret- and GFRalpha-ir. Between E4.5 and E6.5, the fraction of HNK-1-positive cells expressing GFRalpha1 increased considerably in the foregut. Ret and GFRalpha1 were coexpressed in many cells at E6.5, and the number of such cells increased as development progressed. In the adult, GFRalpha1 and Ret were found in the neuropil of enteric ganglia. We conclude that the population of cells expressing the receptors increases during development and persists in the adult, findings that support a neurotrophic role for GDNF in the formation and maintenance of the avian ENS.

Choline acetyltransferase immunoreactivity of putative intrinsic primary afferent neurons in the rat ileum

The colocalisation of choline acetyltransferase (ChAT) with markers of putative intrinsic primary afferent neurons was determined in whole-mount preparations of the myenteric and submucosal plexuses of the rat ileum. In the myenteric plexus, prepared for the simultaneous localisation of ChAT and nitric oxide synthase (NOS), all nerve cells were immunoreactive (IR) for ChAT or NOS, but seldom for both; only 1.6 +/- 1.8% of ChAT-IR neurons displayed NOS-IR and, conversely, 2.8 +/- 3.3% of NOS-IR neurons were ChAT-IR. In preparations double labelled for NOS-IR and the general nerve cell marker, neuron-specific enolase, 24% of all nerve cells were immunoreactive for NOS, indicating that about 75% of all nerve cells have ChAT-IR. All putative intrinsic primary afferent neurons in the myenteric plexus, identified by immunoreactivity for the neurokinin 1 (NK1) receptor and the neurokinin 3 (NK3) receptor, were ChAT-IR. Conversely, of the ChAT-IR nerve cells, about 45% were putative intrinsic primary afferent neurons (this represents 34% of all nerve cells). The cell bodies of putative intrinsic primary afferent neurons had Dogiel type II morphology and were also immunoreactive for calbindin. All, or nearly all, nerve cells in the submucosal plexus were immunoreactive for ChAT. About 46% of all submucosal nerve cells were immunoreactive for both neuropeptide Y (NPY) and calbindin; 91.8 +/- 10.5% of NPY/calbindin cells were also ChAT-IR and 99.1 +/- 0.7% were NK3 receptor-IR. Of the nerve cells with immunoreactivity for ChAT, 44.3 +/- 3.8% were NPY-IR, indicating that about 55% of submucosal nerve cells had ChAT but not NPY-IR. Only small proportions of the ChAT-IR, non-NPY, nerve cells had NK3 receptor or calbindin-IR. It is concluded that about 45% of submucosal nerve cells are ChAT/calbindin/NPY/VIP/NK3 receptor-IR and are likely to be secretomotor neurons. Most of the remaining submucosal nerve cells are immunoreactive for ChAT, but their functions were not deduced. They may include the cell bodies of intrinsic primary afferent neurons.

Immunocytochemical evidence of plasticity in the nervous structures of the rat lower lip

In this immunocytochemical study we investigated the distribution of nervous structures in the lower lip of adult rats. The region is characterized by a rich cutaneous and mucosal sensory innervation originating from terminal branches of the trigeminal system. Lower lip innervation was investigated by detection of the general neuronal marker protein gene product 9.5 (PGP 9.5) and the growth-associated protein 43 (GAP-43), a neurochemical marker of neuronal plasticity. The entire neural network of both cutaneous and mucosal aspects was stained by the antibody to PGP 9.5. In particular, nerve fibers were observed in the submucosal and the subepithelial plexuses. Thin immunoreactive fibers were observed within the epithelial layers ending as free fibers or as fibers associated with immunopositive Merkel cells. Well-identified anatomical structures receiving sensory or autonomic innervation were also surrounded by PGP 9.5-ir nerve fibers, in particular, hair follicles, vibrissae, glands, and blood vessels. GAP-43-immunostained nerve fibers were observed in all these structures; however, they were generally less numerous than the PGP 9.5-immunoreactive elements. An equal amount of PGP 9.5 and GAP-43 immunoreactivity occurred, in contrast, in the subepidermal and the submucosal plexuses, or in the epidermis and the mucosal epithelium. The present results show that GAP-43 is normally expressed in the mature trigeminal sensory system of the rat. Skin and oral mucosa are characterized by continuous remodeling that may also involve the sensory nervous apparatus. Continuous neural remodeling, regeneration and sprouting may be the reason for the observed expression of GAP-43.

Light and electron microscopic studies of pituitary adenylate cyclase-activating peptide (PACAP)--immunoreactive neurons in the enteric nervous system of rat small and large intestine

Pituitary adenylate cyclase-activating peptide (PACAP)-immunoreactive (IR) neurons in the myenteric and submucosal plexus of the rat small and large intestine were examined by immunostaining with purified polyclonal antiserum against PACAP (1-15), using both light and electron microscopy. Many PACAP-IR neuronal cell bodies and fibers were found in the myenteric and submucosal plexus. Many of the PACAP-IR fibers originated from the cell bodies of the myenteric and submucosal ganglia. The ganglia were also innervated by PACAP-IR fibers. PACAP-IR fibers penetrated both the circular and longitudinal muscle layers, confirming the previous observations indicating that PACAP neurons act as motor neurons. Ultrastructural study demonstrated that PACAP-IR nerve terminals formed synaptic contacts with PACAP-IR nerve cell bodies or dendritic processes. This observation suggests that PACAP-IR neurons innervate other PACAP-IR neurons, and that PACAP neurons work as interneurons in the enteric nervous system. PACAP-IR nerve cells received not only PACAP-positive nerve terminal input also PACAP-negative nerve terminal input. It also suggests that PACAP neurons are regulated not only by PACAP-IR enteric neurons, but also by neurons originating elsewhere. Our observations support the view that PACAP-IR neurons are involved in the control of gut motility.

Adenylyl cyclase co-distribution with the CaBPs, calbindin-D28 and calretinin, varies with cell type: assessment with the fluorescent dye, BODIPY forskolin, in enteric ganglia

The aims of the present study were: (1) to evaluate BODIPY forskolin as a suitable fluorescent marker for membrane adenylyl cyclase (AC) in living enteric neurons of the guinea-pig ileum; (2) to test the hypothesis that AC is distributed in several subpopulations of enteric neurons; (3) to test the hypothesis that the distribution of AC in the myenteric plexus is not unique to AH/Type 2 neurons. BODIPY forskolin was used to assess the co-distribution of AC in ganglion cells expressing the specific calcium-binding proteins (CaBPs), calretinin, calbindin-D28, and s-100. Cultured cells or tissues were incubated with 10 microM BODIPY forskolin for 30 min and fluorescent labeling was monitored by using laser scanning confocal microscopy. BODIPY forskolin stained the cell soma, neurites, and nerve varicosities of Dogiel Type I or II neurons. About 99% of myenteric and 27% of submucous ganglia contained labeled neurons. About 14% of myenteric and 3% of submucous glia with immunoreactivity for s-100 protein displayed BODIPY forskolin fluorescence. BODIPY forskolin differentially labeled myenteric neurons immunoreactive for calbindin-D28 (80%) and calretinin (17%). The majority (63%) of BODIPY forskolin-labeled myenteric neurons displayed no immunoreactivity for either CaBP. In submucous ganglia, the dye labeled 44.6% of calretinin-immunoreactive neurons, representing 21% of all labeled neurons; it also labeled varicose nerve fibers running along blood vessels. AC thus exists in myenteric Dogiel type II/AH neurons, enteric cholinergic S/Type 1 neurons, and other unidentified non-cholinergic S/Type 1 neurons. Our data also support the hypothesis that AC is expressed in distinct functional subpopulations of AH and S neurons in enteric ganglia, and show that BODIPY forskolin is a suitable marker for AC in immunofluorescence co-distribution studies involving living cells or tissues.

Distributional pattern and targets of GABA-containing neurons in the porcine small and large intestine

In the rat and guinea-pig enteric nervous system, gamma-aminobutyric acid (GABA) has been shown to act as a neurotransmitter in interneurons innervating both excitatory and inhibitory motor neurons, thus modulating peristalsis and acid secretion. The present study reports on the distribution of GABA-containing neurons in the porcine intestine by the use of immunocytochemistry. Duodenal, jejunal, ileal and distal colonic segments were exposed in vitro to exogenous GABA (10(-8) M) prior to fixation and immunocytochemical staining to supplement endogenous stores of GABA. In contrast to the guinea-pig intestine, where GABA-immunoreactive (IR) nerve cell bodies were common in myenteric ganglia but very rare in the submucosa, in the pig intestine the nerve cell bodies expressing GABA-immunoreactivity were found predominantly in the ganglia and nerve strands of the inner submucous plexus, while a small number were also found in the myenteric plexus. Most of the neurons were small-sized and had a multidendritic uniaxonal appearance. Their varicose axonal processes protruded within the same ganglion to other nerve cells, including GABA-IR ones, or ran into connecting nerve strands towards neighbouring ganglia. Some of the bigger GABA-IR neurons in the myenteric plexus, however, displayed either a lamellar multidendritic uniaxonal or a bipolar appearance. The density of GABA-IR neurons in the inner submucous plexus varied from duodenum to colon, being highest in ileum and lowest in duodenum. Double-immunolabelling of GABA with substance P revealed that approximately 40% of the GABA-IR neurons in the inner submucous plexus of the ileum also stained for substance P. Our results suggest that in the porcine enteric nervous system, GABA-containing neurons are primarily involved in the modulation of secretory processes rather than in the modulation of peristalsis.

Different subpopulations of cholinergic and nitrergic myenteric neurones project to mucosa and circular muscle of the guinea-pig gastric fundus

Since the stomach lacks a well-developed ganglionated submucous plexus, the somata of enteric neurones innervating the muscle or the mucosa have to be localised within the myenteric plexus. The aim of this study was to determine the projection pathways and the neurochemical coding of myenteric neurones innervating these different targets in the gastric fundus. Myenteric cell bodies projecting to the mucosa or the circular muscle were retrogradely labelled by mucosa or muscle application of the fluorescent tracer DiI and subsequently characterised by their immunoreactivity for choline acetyltransferase (ChAT), nitric oxide synthase (NOS), substance P (SP) and/or neuropeptide Y (NPY). On average 143+/-91 and 89+/-49 myenteric neurones were labelled from the mucosa and the circular muscle, respectively. DiI-labelled neurones were either ChAT- or NOS-positive. DiI-labelled ChAT-positive neurones were mainly ascending and outnumbered NOS-positive neurones, which were mainly descending (79.3+/-6.2% vs 20.7+/-6.2% for mucosa neurones; 69.3+/-11.1% vs 30.7+/-11.1% for muscle neurones). Three ChAT-positive subpopulations (ChAT/-, ChAT/SP, ChAT/NPY) and two NOS-positive subpopulations (NOS/-, NOS/NPY) were found. ChAT/SP neurones projected mainly to the circular muscle (36.1+/-11.9% of the cholinergic muscle neurones; mucosa projection: 8.0+/-2.1%), whereas ChAT/NPY neurones projected mainly to the mucosa (38.1+/-9. 2% of the cholinergic mucosa neurones; muscle projection: 5.7+/-2. 4%). NOS/- cells projected predominantly to the muscle. This study demonstrates polarised pathways in the myenteric plexus consisting of ascending ChAT and descending NOS cells that innervate the circular muscle and the mucosa of the gastric fundus. The ChAT/SP neurones might function as circular muscle motor neurones, whereas ChAT/NPY neurones might represent secretomotor neurones.

The organisation of the enteric nervous system in the submucous and mucous layers of the small intestine of the pig studied by VIP and neurofilament protein immunohistochemistry

The arrangement of the enteric ganglia and nerve fibre plexuses was examined in the submucous and mucous layers and around Peyer's patches of the porcine small intestine to clarify their organisation. Immunohistochemistry of vasoactive intestinal peptide (VIP) and neurofilament proteins in wholemounts, chopped or paraffin sections was used to locate the neural elements. The ganglia of the internal and external submucous plexuses were situated at 2 different topographic locations, being clearly demarcated by the submucosal vascular arcades and differing in neuronal composition. The internal submucous plexus was the only contributor to the plexus surrounding the follicles of Peyer's patches as a continuous mesh of 3 ganglionated nerve subplexuses. VIP-immunoreactive fibres from this mesh innervated the dome. The mucosal plexus, which was subdivided into 4 subunits--the outer proprial, inner proprial, pericryptal and villous plexuses--contained a few solitary neuronal perikarya. Labelling for neurofilament proteins revealed Dogiel types II, IV and VI neurons. The observations reveal several new features in the enteric nervous system of the pig and clarify its nomenclature.

Cathepsin D in intestinal ganglion cells. A potential aid to diagnosis in suspected Hirschsprung's disease

There is still a need for a better method of detecting immature ganglion cells in paraffin sections of colorectal luminal biopsies in cases suspected of Hirschsprung's disease. The lysosomal aspartic proteinase cathepsin D has been immunolocalized to various cell types, including ganglion cells. We investigated its expression in intestinal ganglion cells to determine whether it could be used as an aid in the detection of immature ganglion cells in rectal biopsies from children suspected of having Hirschsprung's disease. Routinely processed tissues of eight adult intestines resected for gunshot wounds and six ganglioneuromas (for mature ganglion cells), of six colons resected for neonatal necrotizing enterocolitis (for immature ganglion cells), and of 11 cases of suspected and three cases of known Hirschsprung's disease were immunostained with a polyclonal antibody to cathepsin D using the avidin-biotin-peroxidase method. In all cases, all ganglion cell bodies present showed intense granular cytoplasmic reactivity for cathepsin D. The granules crowded the cytoplasm and formed a collarette around the nucleus. In the submucosa, the only other immunoreactive cells were histiocytes, but they could be distinguished from ganglion cells by their characteristic nuclear features and their occurrence singly and unassociated with nerves. The three resection specimens with Hirschsprung's disease showed a clear transition between the ganglionic and the aganglionic segments. We conclude that cathepsin D is a promising marker of immature ganglion cells in cases suspected of Hirschsprung's disease.

Ultrastructural localisation of substance P, vasoactive intestinal peptide and somatostatin immunoreactivities in the submucous plexus of guinea pig ileum

The submucous neurons, especially those related to the lymphatic vessels, together with their associated synapses, were studied ultrastructurally with respect to their immunoreactivities for 3 types of neuropeptides, namely substance P (SP), vasoactive intestinal peptide (VIP) and somatostatin (SOM). With the antibodies directed against the 3 types of neuropeptides, a variable number of submucous neurons including those contacting the lymphatic vessels were immunostained. Based on the immunoreactivities and synaptic relations with the submucous neurons contacting the lymphatic vessels, at least 4 types of synaptic relations with the submucous neurons contacting the lymphatic vessels, at least 4 types of synaptic configurations were observed: immunopositive terminals with positive neurons, immunopositive terminals with negative neurons, immunonegative terminals with positive neurons and immunonegative terminals with negative neurons. All 4 types of synaptic configurations were observed in SP and VIP-immunostained specimens, with the exception of type 3 which was not encountered in samples immunoreacted for SOM. When the proportions of all 4 types of peptidergic immunopositive terminals contacting the lymphatic vessel-associated neurons were totalled, the value exceeded 100%, suggesting the coexistence of 2 or more neuropeptides in the same terminals. Furthermore, some immunoreactive axon terminals made direct synaptic contacts with positive neurons suggesting the formation of the so-called 'peptide neuron chain'. It is speculated from this study that the submucous neurons receive multiple peptidergic inputs. The various synaptic contacts would imply a complicated reflex pathway in the submucous plexus.

Detection of 5-HT3R-A, a 5-HT3 receptor subunit, in submucosal and myenteric ganglia of rat small intestine using in situ hybridization

Physiological and radioligand binding studies have demonstrated the existence of 5-HT3 receptors in the enteric nervous system. In order to determine if the cloned 5-HT3 receptor subunit, 5-HT3R-A, was expressed in the enteric nervous system of rats, we have performed in situ hybridization with 33P-labeled cRNA antisense probes on sections of rat small intestine. Hybridization was detected in both submucosal and myenteric ganglia of the duodenum, jejunum, and ileum.

Catecholamine innervation of the intestine of flying foxes (Pteropus spp.): a substantial supply from enteric neurons

The distribution of catecholamines in the small and large intestine of flying foxes (Pteropus spp.) was investigated using glyoxylic-acid-induced fluorescence and immunohistochemical staining of tyrosine hydroxylase and dopamine-beta-hydroxylase. Dense networks of varicose axons stained by each of these methods supplied blood vessels, the mucosa and both submucous and myenteric ganglia, but were scarce in the circular and longitudinal muscle. The majority (> 90%) of submucous neuronal perikarya contained both enzymes and most of these also exhibited catecholamine fluorescence. Somata of similar staining characteristics were less common in the myenteric plexus, where single cells were found in only the minority of ganglia. All of the stained submucosal somata and mucosal axons contained vasoactive intestinal peptide, whereas catecholamine-containing axons that supplied the ganglia, external muscle and blood vessels did not. It is concluded that (1) there is dense catecholamine innervation of most tissues in the flying-fox intestine, similar to many other mammals, (2) mucosal axons originate from enteric catecholamine neurons, not found in other mammals, and (3) axons supplying the blood vessels and enteric ganglia are probably of sympathetic origin and can be distinguished from the intrinsic catecholamine-containing axons by their lack of vasoactive intestinal peptide. The roles and interactions of these two types of catecholamine innervation in the control of secretion and motility remain to be identified.

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.

Severe constipation with diffuse intestinal myenteric hyperganglionosis

The authors report a case of neuronal intestinal dysplasia in a 6-year-old girl. The disease is characterized by hyperplastic ganglia throughout the large and small intestine, associated with severe constipation. To better understand the pathophysiology of this disease the authors investigated the histopathologic, ultrastructural, and immunohistochemical characteristics of the intestinal tissue in this case. The hyperganglionosis was associated with immunohistochemical findings of intact expression of the neuropeptides controlling the peristaltic reflex, through lower expression of calcitonin-gene related peptide. With the recent progress in our understanding of the neural regulation of gastrointestinal function, it may now be possible to begin to understand the complex pathophysiological mechanisms underlying gastrointestinal motility disorders.

Routine use of the nitric oxide stain in the differential diagnosis of Hirschsprung's disease

Hirschsprung's disease (HD) is defined as a congenital absence of ganglion cells in the distal bowel. Functionally, there is a loss of enteric neuromuscular inhibition. Inhibitory intestinal innervation includes extrinsic nonadrenergic, noncholinergic (NANC) nerves. Nitric oxide (NO) is proposed to be a NANC neurotransmitter. Sites of NO synthesis can be localized using a NO-dependent nicotinamide adenine dinucleotide phosphate (NADPH) diaphorase histochemical assay. We present a study of the distribution of NO neural elements in patients with HD. Routine hematoxylin-eosin (HE) histology as well as histochemical localization of NO synthase activity was carried out on fixed laminae and sectioned tissue of infant colon. NO synthase positive nerve cells and fibers were found throughout the wall of the proximal ganglionated colon. In the myenteric plexus disposition of these nerves parallels the known NANC innervation. "Aganglionic" distal colon displayed disrupted ganglia and increased nerve fibers. Selective preservation of NO synthesizing neurons was also seen. Punctate labeling of an apparent nonneuronal origin was also noted on the surface of arterioles. NO stain simplifies the pathological diagnosis of HD. The presence of NO positive nerve cells in HD suggests that aganglionosis is a misnomer. The lack of characteristic HE findings in other forms of neuronal intestinal dysplasia indicates the need for routine simple, more sensitive neural staining of colonic biopsies in selected infants with constipation.

Secondary effects of prolonged intestinal obstruction on the enteric nervous system in the rat

Motility disturbances following prolonged intestinal obstruction have been attributed to secondary effects. This study aimed to demonstrate the effects of incomplete obstruction on the enteric nervous system (ENS) of a rat model. Surgical placement of a nonstrangulating ligature encircling the distal bowel was performed in 41 freshly weaned rats. Anesthetic protocol included Ketamine, ether, or Xylazine (an alpha 2-adrenergic agonist). Histological evaluation was by ganglion cell morphology, histochemical staining for acetylcholinesterase (AChE) and tyrosine hydroxylase (TOH) immunocytochemistry. Forty-one freshly weaned LE rats were divided into controls (8), sham procedures (8), intestinal obstruction (16), and a group of rats with colonic biopsy performed prior to and following experimental obstruction (9). The rats were sacrificed at periods varying between 14 and 45 days post experimental obstruction (median survival, 27 days). Histological changes included elongation of ganglion cells and a decrease in the number per 5-mm slide in obstructed animals. No other obstruction specific differences were detected. A significant (P < .01) increase in AChE in the submucous plexus was recorded in Xylazine-anesthetized animals. No obstruction-specific effects could be demonstrated in the ENS, suggesting that prolonged obstruction without ischemia does not result in any significant alterations in the ENS. Pharmacological stimulation of the alpha 2-adrenergic receptor appeared to result in an increase in AChE. This mechanism may help to explain a possible role for the adrenergic system in the increased AChE levels in affected bowel in patients with Hirschsprung's disease.

Nerve growth factor receptor immunoreactivity in Meissner and Pacinian corpuscles of the human digital skin

The presence of nerve growth factor receptors (NGFr) in sensory nerve corpuscles of human digital skin, primarily Meissner and Pacinian corpuscles, was investigated immunohistochemically using two monoclonal antibodies directed against human-NGFr. To ensure the localization of NGFr immunoreactivity (IR) alternative sections to that processed for NGFr detection were assayed for neurofilament protein (NFP) and S-100 protein which selectively label the axon and the periaxonic specialized cells (lamellar cells of Meissner's corpuscles; inner-core cells of Pacinian corpuscles), respectively. Occurrence of NGFr IR was observed in both types of sensory corpuscles. In Meissner's corpuscles NGFr-IR was found in the lamellar cells, whereas in the Pacinian corpuscles the lamellae of the inner core, outer core, and capsule displayed NGFr IR. Moreover, a positive IR was observed in the central axon of some Pacinian corpuscles. However, remarkable differences were encountered among Pacinian corpuscles in the pattern of NGFr IR distribution. Present results demonstrate the presence of NGFr IR in sensory nerve corpuscles of the human digital skin, suggesting that NGFr could be involved in the concentration of NGF and in the conveying of this molecule from the cutaneous sources to the cell body of NGF-dependent primary sensory neurons. However, the mechanisms involved in this process remain to be clarified.

Localisation of endothelin like immunoreactivity in adult and developing human gut

The distribution of immunoreactivity for the potent vasoconstrictor endothelin-1 was studied in adult and developing human gut using antisera to endothelin-1 (1-21) and the C terminus of big endothelin-1. The coexistence of these peptides with other neuropeptides was investigated using comparative immunocytochemistry. Endothelin-1 like immunoreactivity was detected in extracts of adult (range 20-60 fmol/g wet weight) and fetal (33 fmol/g) gastrointestinal tract and was shown by chromatography to be the predominant isoform of endothelin present in both. It was localised by immunocytochemistry to ganglion cells in the submucous and myenteric plexuses and to scattered nerves, whereas big endothelin-1 like immunoreactivity was found in the submucous plexus only. Colocalisation studies showed immunoreactivity for both endothelin-1 and vasoactive intestinal peptide in the same ganglion cells of the submucous plexus. Although endothelin-1 immunoreactivity was not detected by immunocytochemistry in the fetal human gut until the 32nd week of gestation, big endothelin-1 was found as early as 11 weeks in the developing neural structures and epithelial cells. The latter were shown to be endocrine cells by their immunoreactivity for chromogranin. Our results indicate that endothelin is a neuropeptide found in adult human gut which shows transient expression in endocrine cells during development.

[Presence of calretinin in neurons of the human intestine]

Calcium-binding proteins are present in different neuron populations in the Central Nervous System. As concerns the Enteric Nervous System, only a few studies have been performed. In the present work we investigated immunohistochemically the localization of Calretinin in neurons of the human intestinal wall. Our results showed the presence of stained cell bodies and fibers with antibodies against Calretinin in the Auerbach plexus. Since most of the enteric neurons are characterized by a slow phase after hyperpolarization caused by Ca2+ dependent K+ channels, the role of Calretinin could be to modulate this particular electrophysiological behaviour.

Complementary immunohistochemical distribution of the neurofilament triplet and novel intermediate filament proteins in the autonomic and sensory nervous system of the guinea-pig

We have previously established that immunoreactivity for the triplet of polypeptides that comprise the class IV intermediate filament proteins (NFP-triplet) is localized in specific subpopulations of neurons in guinea-pig sensory and autonomic ganglia. Antibodies to novel neurofilament proteins, including a polyclonal antibody to a 57 kDa neuronal intermediate filament polypeptide (NIF57kD) and a monoclonal antibody (CH1) to a 150 kDa intermediate filament, or associated, protein were used in combination with antibodies to the NFP-triplet for double-labelling immunohistochemistry. The results show that different subpopulations of neurons in the guinea-pig dorsal root ganglia, coeliac ganglion and enteric ganglia can be distinguished by their complementary immunoreactivity for these proteins. In dorsal root ganglia, larger neurons are intensely immunoreactive for the NFP-triplet while immunoreactivity with CH1 and NIF57kD antibodies is restricted to the small to medium-sized neurons. In the coeliac ganglion, two regionally defined subpopulations of neurons can be distinguished by their immunoreactivity for either the NFP-triplet or NIF57kD, whereas CH1 labels all neurons with equal intensity. Three classes of morphologically distinct myenteric neuron subpopulations are also distinguished by their immunoreactivity for either the NFP-triplet, NIF57kD or CH1 antibodies. Two classes of submucous neurons are labelled both with CH1 and NIF57kD antibodies but show faint or no immunoreactivity for the NFP-triplet. It is concluded that intermediate filament protein immunoreactivity marks different subpopulations of neurons, which suggests that these proteins may have specific roles in neuronal function.

The innervation of the gastrointestinal tract of a chelonian reptile, Pseudemys scripta elegans. I. Structure and topography of the enteric nerve plexuses using neuron-specific enolase immunohistochemistry

The general morphological features of the intramural enteric nervous system of a chelonian species, i.e. the red-eared turtle, Pseudemys scripta elegans, has been studied in whole-mounts and cryosections by means of neuron-specific enolase immunohistochemistry. A clear visualization of both neuronal cell bodies and nerve fibres allows the recognition of a myenteric plexus as well as a submucous plexus in several gut regions, namely the stomach, midgut and hindgut. The highest innervation density was found in the midgut portion. In contrast to other lower vertebrates, such as amphibians and other reptilian groups, the present study clearly demonstrates the occurrence of neuronal cell bodies in the submucous plexus of all regions investigated. The neurons stained for neuron-specific enolase harboured smooth-contoured perikarya from which one or more processes emerge, as demonstrated for the mammalian enteric nervous system.

Effect of diabetes in the BB Wistar rat on the peptidergic component of the enteric innervation

Whole mount preparations of the small intestine from Wistar, normoglycemic 90-day diabetic BB, hyperglycemic 90-day diabetic BB and age-matched nondiabetic BB rats were immunostained to determine the extent of the peptidergic innervation. The neuropeptides examined were vasoactive intestinal peptide, neuropeptide Y, substance P. calcitonin gene-related peptide, galanin and somatostatin. The extent of the peptidergic innervation in the submucous and myenteric plexuses from the control Wistar, nondiabetic BB and normoglycemic diabetic BB rats was identical. In the submucous plexus of the hyperglycemic diabetic BB rats there was a marked reduction in the number of somatostatin-immunoreactive neurons and nerve fibres. Substance P and calcitonin gene-related peptide which are colocalized in a proportion of the somatostatin neurons were unaffected. In the myenteric plexus of the hyperglycemic diabetic BB rats the number and intensity of staining of the galanin-immunoreactive nerve fibers was markedly increased. Galanin has not been observed to colocalize with any of the other neuropeptides examined.