Vagal afferents innervating the gastrointestinal tract and CCKA‐receptor immunoreactivity

A large body of evidence derived from electrophysiological recording and pharmacological/behavioral experiments suggests the presence of CCKA‐receptors on vagal primary afferent fibers innervating the gastrointestinal tract. With the availability of antibodies specific for the CCKA‐receptor, we wanted to demonstrate its presence and distribution on identified vagal afferent fibers and different types of terminals in the mucosa, myenteric plexus, and external muscle layers of the stomach and duodenum. In the duodenal mucosa, neither a C‐terminal (Ab‐1) nor an N‐terminal (Ab‐2) specific antibody produced any specific staining; in the myenteric plexus, non‐vagal enteric neurons and their processes, but not vagal intraganglionic laminar endings (IGLEs), exhibited CCKAR‐immunoreactivity. Similarly, in the gastric myenteric plexus, a population of enteric neurons and their processes, but not identified vagal IGLEs, were labeled by both antibodies. In both external muscle layers of the stomach, CCKAR‐immunoreactive axons were in close register with labeled vagal afferent intramuscular arrays, but the two labels were not contained in the same varicosities. Ab‐1 immunoreactivity was found in the cell membrane of vagal afferent perikarya in the nodose ganglia and in pancreatic acinar cells. The failure to detect CCKAR‐immunoreactivity in peripheral vagal afferent terminals cannot be due to methodological problems because it was present in enteric neurons in the same sections, and because it did not stain structures resembling IGLEs in material without the potentially masking vagal afferent label. We conclude that CCKA‐receptors on vagal afferent terminals: 1) are below the immunohistochemical detection threshold, 2) exhibit a conformation or affinity state inaccessible to the two antibodies, or 3) are not transported to the peripheral terminals. Anat Rec 266:10–20, 2002. © 2002 Wiley‐Liss, Inc.     

Vagal sensors in the rat duodenal mucosa: distribution and structure as revealed by in vivo DiI-tracing

Results from functional studies point to the importance of chemoreceptive endings in the duodenum innervated by vagal afferents in the regulation of gastrointestinal functions such as gastric emptying and acid secretion, as well as in the process of satiation. In order to visualize the vagal sensory innervation of this gut segment, vagal afferents were selectively labeled in vivo by injecting the lipophilic carbocyanine dye DiI into either the left or the right nodose ganglion of young adult rats. Thick cryostat sections or whole-mounted peels of muscularis externa or submucosa of formalinfixed tissue were analyzed with conventional and/or confocal microscopy. In the mucosa, many DiI-labeled vagal afferent fibers were found with terminal arborizations mainly between the crypts and the villous lamina propria. In both areas, vagal terminal branches came in close contact with the basal lamina, but did not appear to penetrate it so as to make direct contact with epithelial cells. Labeled vagal afferent fibers in the villous and cryptic lamina propria were found to be in intimate anatomical contact with fibrocyte-like cells that may belong to the class of interstitial cells of Cajal, and with small granular cells that might be granulocytes or histiocytes. Although our analysis was not quantitative, and considering that labeling was unilateral and not complete, it appears that the overall density of vagal afferent mucosal innervation was variable; many villi showed no evidence for innervation while other areas had quite dense networks of arborizing terminal fibers in several neighboring villi. Analysis of separate whole-mounted muscularis externa and submucosa peels revealed the presence of large bundles of labeled afferent fibers running within the myenteric plexus along the mesenteric attachment primarily in an aboral direction, with individual fibers turning towards the antimesenteric pole, and either penetrating into the submucosa or forming the characteristic intraganglionic laminar endings (IGLEs). Although the possibility of individual fibers issuing collaterals to myenteric IGLEs and at the same time to mucosal terminals was not demonstrated, it cannot be ruled out. These anatomical findings are discussed in the context of absorptive mechanisms for the different macronutrients and the implication of enteroendocrine cells such as CCK-containing cells that may function as intestinal taste cells.     

The neural regulation of the mammalian esophageal motility and its implication for esophageal diseases

In contrast to the tunica muscularis of the stomach, small intestine and large intestine, the external muscle layer of the mammalian esophagus contains not only smooth muscle but also striated muscle fibers. Although the swallowing pattern generator initiates the peristaltic movement via vagal preganglionic neurons that project to the myenteric ganglia in the smooth muscle esophagus, the progressing front of contraction is organized by a local reflex circuit composed by intrinsic neurons similarly to other gastrointestinal tracts. On the other hand, the peristalsis of the striated muscle esophagus is both initiated and organized by the swallowing pattern generator via vagal motor neurons that directly innervate the muscle fibers. The presence of a distinct ganglionated myenteric plexus in the striated muscle portion of the esophagus had been enigmatic and neglected in terms of peristaltic control for a long time. Recently, the regulatory roles of intrinsic neurons in the esophageal striated muscle have been clarified. It was reported that esophageal striated muscle receives dual innervation from both vagal motor fibers originating in the brainstem and varicose intrinsic nerve fibers originating in the myenteric plexus, which is called ‘enteric co-innervation’ of esophageal motor endplates. Moreover, a putative local neural reflex pathway that can control the motility of the striated muscle was identified in the rodent esophagus. This reflex circuit consists of primary afferent neurons and myenteric neurons, which can modulate the release of neurotransmitters from vagal motor neurons in the striated muscle esophagus. The pathogenesis of some esophageal disorders such as achalasia and gastroesophageal reflux disease might be involved in dysfunction of the neural networks including alterations of the myenteric neurons. These evidences indicate the physiological and pathological significance of intrinsic nervous system in the regulation of the esophageal motility. In addition, it is assumed that the components of intrinsic neurons might be therapeutic targets for several esophageal diseases.     

Alpha-synuclein-immunopositive myenteric neurons and vagal preganglionic terminals: Autonomic pathway implicated in Parkinson's disease?

The protein alpha-synuclein is implicated in the development of Parkinson's disease. The molecule forms Lewy body aggregates that are hallmarks of the disease, has been associated with the spread of neuropathology from the peripheral to the CNS, and appears to be involved with the autonomic disorders responsible for the gastrointestinal (GI) symptoms of individuals afflicted with Parkinson's. To characterize the normative expression of alpha-synuclein in the innervation of the GI tract, we examined both the postganglionic neurons and the preganglionic projections by which the disease is postulated to retrogradely invade the CNS. Specifically, in Fischer 344 and Sprague–Dawley rats, immunohistochemistry in conjunction with injections of the tracer Dextran–Texas Red was used to determine, respectively, the expression of alpha-synuclein in the myenteric plexus and in the vagal terminals. Alpha-synuclein is expressed in a subpopulation of myenteric neurons, with the proportion of positive somata increasing from the stomach (3%) through duodenum (proximal, 6%; distal, 13%) to jejunum (22%). Alpha-synuclein is co-expressed with the nitrergic enzyme nitric oxide synthase (NOS) or the cholinergic markers calbindin and calretinin in regionally specific patterns: 90% of forestomach neurons positive for alpha-synuclein express NOS, whereas 92% of corpus-antrum neurons positive for alpha-synuclein express cholinergic markers. Vagal afferent endings in the myenteric plexus and the GI smooth muscle do not express alpha-synuclein, whereas, virtually all vagal preganglionic projections to the gut express alpha-synuclein, both in axons and in terminal varicosities in apposition with myenteric neurons. Vagotomy eliminates most, but not all, alpha-synuclein-positive neurites in the plexus. Some vagal preganglionic efferents expressing alpha-synuclein form varicose terminal rings around myenteric plexus neurons that are also positive for the protein, thus providing a candidate alpha-synuclein-expressing pathway for the retrograde transport of putative Parkinson's pathogens or toxins from the ENS to the CNS.     

Intraganglionic laminar endings in the rat esophagus contain purinergic P2X2 and P2X3 receptor immunoreactivity

Intraganglionic laminar endings (IGLEs) represent the most prominent vagal afferent terminal structures throughout the gastrointestinal tract. They are most prominent in the esophagus and stomach, but can be found down to the distal colon. Their role as mechanosensors as proposed on anatomical grounds was recently substantiated in elegant functional experiments. There is evidence that vagal mechanosensors in the esophagus and stomach respond to ATP. Thus, the present study aimed at detecting purinergic receptors on IGLEs. IGLEs in the rat esophagus were identified by immunohistochemistry for calretinin and sections were co-incubated with antibodies directed against P2X₂ or P2X₃ receptors. Also, double label immunocytochemistry for purinergic receptors and calcitonin gene-related peptide as a marker for spinal afferents was performed. Terminal nerve fibers immunoreactive for P2X₂ and P2X₃, respectively, were observed between outer and inner layers of the tunica muscularis, covering myenteric ganglia totally or partly. Both P2X₂ and P2X₃ receptor immunoreactivities were highly co-localized with calretinin positive IGLEs as shown by confocal laser scanning microscopy. Numerous calcitonin gene-related peptide immunostained fibers were found to closely approach and intermingle with P2X immunopositive IGLEs. However, there was never co-staining for either of the purinergic receptors and calcitonin gene-related peptide within the same fibers. P2X₃ but not P2X₂ immunoreactivity was also observed within nerve fiber arborizations in the mucosa of the pharynx. In the nodose ganglion, 8.9±1.1% of P2X₂ and 7.2±1.3% of P2X₃ immunopositive neurons, respectively, co-stained for calretinin. On the other hand, 63.4±4.6% and 60.1±5.3% of calretinin positive cell bodies contained P2X₂ and P2X₃ receptor immunoreactivity, respectively. These results indicate that IGLEs are equipped with both P2X₂ and P2X₃ receptors. Thus, they may act as chemosensors or their mechanosensory properties may be modulated by ATP. It is also suggested that spinal afferents innervating the esophagus are equipped with neither P2X₂ nor P2X₃ purinergic receptors.     

Vagal-enteric interface: vagal activation-induced expression of c-Fos and p-CREB in neurons of the upper gastrointestinal tract and pancreas

Many gastrointestinal and pancreatic functions are under strong modulatory control by the brain via the vagus nerve. To start identifying location and neurochemical phenotype of the enteric neurons receiving functional vagal efferent input, we activated vagal preganglionic neurons either by electrical or chemical stimulation and examined the expression of phosphorylated CREB (c-AMP response element binding protein) and the immediate early gene c-Fos. There was no spontaneous expression of both markers in the pancreas and considerable spontaneous expression of p-CREB but not Fos in the upper GI-tract. Unilateral electrical vagal stimulation-induced p-CREB was found in 40% of neurons in the head of the pancreas. Fos expression was found in 70-90% of neurons in the esophagus and stomach, in 20-30% of myenteric plexus neurons and 5-15% in submucosal neurons of the proximal duodenum. Double-labeling experiments showed that a majority of pancreatic neurons and about 25-35% of neurons in the stomach and duodenum contain NADPH-diaphorase and that many of these receive functional vagal input. Other neurons that can be vagally activated contain gastrin-releasing peptide or calretinin. Chemical stimulation of the dorsal surface of the caudal brainstem with the stable TRH analog RX77368 resulted in selective activation of vagal efferents with expression of Fos in a small number of gastric myenteric plexus neurons. The results demonstrate the suitability of this method to investigate magnitude and local distribution of vagal input to the enteric nervous system as well as specificity of its neurochemically coded pathways. They represent the first step in the identification of function-specific units of parasympathetic vagal outflow.     

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. Accepted: 20 April 1998     

豚鼠胃肠壁内神经丛的磷酸醋、醋类和神经递质代谢有关的酶组织化学观察

本文报道用光镜半定量和显微光度计定量分析研究了豚鼠胃肠壁内神经丛神经元的几种酶的组织化学反应。结果表明,神经元的碱性磷酸酶(AlP)、酸性磷酸酶(AcP)、5′-核苷酸酶(5′-Nase)、硫胺素焦磷酸酶(TPPase)、非特异性酯酶(NsE)和胆碱乙酰转移酶(ChAT)反应强弱明显不等。消化道不同节段或不同部位神经元的单胺氧化酶(MAO)、氨基肽酸(AP)和乙酰胆碱酯酶(AChE)反应虽有差别,但却显阳性反应,同一神经节内各神经元的反应比较近似。胃肠各段壁内神经丛中50～66%神经元呈ChAT强阳性反应,这些细胞可能为胆碱能神经元。整个消化道粘膜下丛与肠肌丛神经元相比,除NsE外,另几种酶均有高度显著差异。粘膜下丛神经元AcP和AP反应较强,肠肌丛神经元AlP、5′-Nase、TPPase、MAO、ChAT和AChE反应较强,胃壁内神经丛不如肠道的发达。尤其是胃粘膜下丛只见少数单个散在的神经元,它们的各种酶组织化学反应均较弱。各段肠中,以十二指肠和近端结肠壁内神经丛神经元的各种酶组织化学反应较强。上述结果表明,消化道不同部位以及同一部位不同类型的神经元在代谢和功能上有明显的差别。     

Vagal Fibers Form Associations With Interstitial Cells of Cajal During Fetal Development

Vagal intramuscular arrays (IMAs) have been shown to form complexes with intramuscular interstitial cells of Cajal (ICC). We tested the hypothesis that associations between vagal nerve endings and ICC arise in fetal development. Intraganglionic laminar endings (IGLEs) and IMAs were identified by applying 1,1’‐dioctadecyl‐3,3,3′,3′‐tetramethylindocarbocyanineperchlorate (DiI) to vagal nerve trunks and myenteric plexus (MP) and intramuscular (IM) ICC were immunolabeled with antibodies to c‐Kit in fetal and early postnatal mice (E16‐P7). At E16, c‐Kit immunoreactive cells were abundant in the primordial smooth muscle, with early ICC networks discernable by E18 and ongoing organization at P1 and P7. The distribution of vagal endings was found to change during the course of development, with significantly more putative IGLEs in the prenatal compared to the postnatal period and less IMAs in the prenatal compared to postnatal period. Associations of ICC with both IGLEs and IMAs were detected as early as E16 and were maintained into postnatal life. These findings suggest that vagal fibers begin to associate with ICC during prenatal development. Future studies will be needed to determine the mechanisms through which vagal endings and ICC interact. Anat Rec, 298:1780–1785, 2015. © 2015 Wiley Periodicals, Inc.     

Antibodies to fragments of provasoactive intestinal peptide reveal subpopulations of vasoactive intestinal peptide containing neurons in the rat gut

The cellular origin of peptides derived from preprovasoactive intestinal peptide has been studied in rat stomach and ileum. Antisera specific for the C-terminal regions of the N-terminal flanking peptide (preprovasoactive intestinal peptide 22-80), bridging peptide (preprovasoactive intestinal peptide 111-124), C-terminal flanking peptide (preprovasoactive intestinal peptide 156-170) and vasoactive intestinal peptide were used in immunohistochemical studies on sections and whole mounts. All four antisera stained nerve fibres and cell bodies in the stomach and intestine. However, there were distinct differences in the pattern of colocalization of peptides derived from provasoactive intestinal peptide. In the sub-mucous plexus of the ileum virtually 100% of neurons reacting with vasoactive intestinal peptide antibodies also reacted with antibodies to the other three peptides. In contrast, in the stomach, while all vasoactive intestinal peptide-immunoreactive neurons of the myenteric plexus contained C-terminal flanking peptide- and bridging peptide-like immunoreactivity, only 50% of these cells reacted with the antiserum to N-terminal flanking peptide. The data indicate that in a population of neurons in the myenteric plexus of the rat stomach, preprovasoactive intestinal peptide is processed in such a way that the antigenic determinant of the N-terminal flanking peptide is not produced. In a second population of enteric neurons in the stomach, and in the intestine, it appears that processing of preprovasoactive intestinal peptide results in the production of peptides reacting with antibodies to vasoactive intestinal peptide, the flanking and bridging peptides.     

Characterization of the peptidergic afferent innervation of the stomach in the rat, mouse and guinea-pig

Retrograde tracing of the fluorescent marker, True Blue, has been used together with immunohistochemistry employing antibodies to substance P, calcitonin gene-related peptide, somatostatin, vasoactive intestinal polypeptide and morphine-modulating peptide to study the afferent innervation of the stomach in rat, mouse and guinea-pig. Up to 85% of spinal afferents to the stomach in all three species contained immunoreactive calcitonin gene-related peptide, and up to 50% contained substance P. In all three species less than 10% of vagal afferents to the stomach reacted with antibodies to calcitonin gene-related peptide, or substance P. Cacitonin gene-related peptide-immunoreactive fibres were found in the myenteric plexus, circular muscle and around submucosal blood vessels in the stomach. In the rat, removal of the coeliac ganglion, splanchnic nerve section, or capsaicin treatment virtually abolished calcitonin gene-related peptide immunoreactivity in the stomach. Capsaicin and splanchnic section also abolished the staining of immunoreactive calcitonin gene-related peptide fibres in the coeliac ganglion. The same treatments abolished substance P staining of fibres around submucosal blood vessels, but in the myenteric plexus and circular smooth muscle there were still abundant immunoreactive fibres, presumably arising from intrinsic cell bodies. No somatostatin-containing visceral afferents could be found, although somatostatin was localized to cell bodies in rat dorsal root ganglia. Immunoreactive vasoactive intestinal polypeptide-containing dorsal root ganglia neurons were not found; although antibodies to morphine-modulatory peptide revealed immunoreactive nerve cell bodies, we were unable to exclude the possibility that this result is attributable to cross reactivity with calcitonin gene-related peptide. These results provide direct evidence that calcitonin gene-related peptide is a marker for a major subset of visceral primary afferent neurons and suggest that this population of spinal afferents makes a major contribution to the total gastric content of calcitonin gene-related peptide.     

猪食管神经支配的神经化学研究——一氧化氮类及肽类成分在平滑肌中的分布(英文)

采用免疫荧光组织化学技术及迷走神经切断术,探讨猪食管一氧化氮类及肽类神经支配的神经化学特性。在光学显微镜下可观察到肌间神经丛及粘膜下神经丛中有部分神经元呈nNOS、VIP、GAL、NPY、PACAP、L-ENK、SP、5-HT及CB免疫阳性,但未见CGRP及SOM阳性神经元。nNOS及CB免疫阳性产物主要分布于不同的神经元胞体内。将PGP9.5作为神经元胞体的标记物,并采用免疫荧光免疫组织化学双重染色方法,分别观察了PGP9.5与nNOS、VIP、SP的双标情况。结果如下:(1)nNOS免疫阳性神经元约占PGP9.5标记神经元总数的63%,而VIP免疫阳性神经元约占36%,SP免疫阳性神经元约占28%;(2)神经节内神经元的平均数量呈现吻尾方向的递增趋势,且食管腹段神经丛内神经节数量明显高于食管其他部位;(3)食管肌层内VIP/GAL/NPY免疫阳性纤维分布最广,其中部分阳性纤维同时呈nNOS或PACAP免疫阳性;SP和/或L-ENK免疫阳性纤维在粘膜肌层的分布明显多于平滑肌层。CGRP阳性纤维非常少见,这一点不同于对其他动物的观察结果;(4)经一侧迷走神经切断后,肌间神经丛内PACAP及5-HT免疫阳性纤维明显减少,提示这些纤维可能来源于迷走神经;而平滑肌中VIP/GAL/NPY和/或nNOS免疫阳性纤维数量未发现明显变化,可能为内源性来源。     

Somatostatin immunopositive neurons in the small intestine of the bullfrog (Rana catesbeiana).

Somatostatin immunopositive neurons in the small intestine of the bullfrog (Rana catesbeiana) were studied using immunohistochemistry and surgical denervation of the mesenteric nerve. Immunopositive nerve elements were distributed throughout the small intestine, including nerve fibers in the myenteric plexus, circular muscle layer, submucosal layer, and mucosa. Somatostatin immunopositive nerve cell bodies occurred in the myenteric plexus but not in the submucosal layer. These cell bodies were surrounded by immunopositive nerve fibers forming basket-like terminals, and thus some of these cells may be interneurons. After denervation of the mesenteric nerve, adrenaline immunopositive nerve fibers disappeared almost completely from the small intestine, but no changes occurred in the distribution of somatostatin immunopositive neurons. Neurons in the coeliac ganglion projecting into the small intestine were adrenaline immunopositive but somatostatin immunonegative. The results indicate that somatostatin immunopositive neurons in the small intestine of the bullfrog are primarily intrinsic in origin.     

The neurochemistry and innervation patterns of extrinsic sensory and sympathetic nerves in the myenteric plexus of the C57Bl6 mouse jejunum

In vitro anterograde tracing of axons in mesenteric nerve trunks using biotinamide in combination with immunohistochemical labelling was used to characterize the extrinsic nerve projections in the myenteric plexus of the mouse jejunum. Anterogradely-labelled spinal sensory fibres innervating the enteric nervous system were identified by their immunoreactivity for calcitonin gene-related peptide (CGRP), while sympathetic noradrenergic fibres were detected with tyrosine hydroxylase (TH), using confocal microscopy. The presence of these markers has been previously described in the spinal sensory and sympathetic fibres. Labelled extrinsic nerve fibres in the myenteric plexus were identified apposing enteric neurons that were immunoreactive for either calretinin (CalR), calbindin (CalB) or nitric oxide synthase (NOS). Of the total anterogradely labelled axons in the myenteric plexus, 20% were CGRP-immunoreactive. Labelled CGRP-immunoreactive varicosities were closely apposed to CalR-immunoreactive myenteric cells, many of which were Dogiel type I (40%; interneurons) or type II (20%; intrinsic sensory) neurons. Labelled CGRP-immunoreactive varicosities were also observed in close appositions to CalB-immunoreactive myenteric cell bodies, of which a small subset had type II morphology (18%; intrinsic sensory neurons). A further 43% of all biotinamide-filled fibres were immunoreactive for TH and these fibres were apposed to CalR-immunoreactive cell bodies (small-sized; excitatory motor neurons) and NOS-immunoreactive cell bodies (either type I or small neurons; inhibitory motor neurons and interneurons) in the myenteric plexus. The results provide a neurochemical and neuroanatomical basis for connections between dorsal root afferent neurons and myenteric neurons and suggest an anatomical substrate for the well-known modulation of enteric circuits from sympathetic nerves. No anterogradely-labelled fibres were stained for NOS-immunoreactivity, despite more than 60% of dorsal root ganglion (DRG) neurons retrogradely labelled from the jejunum showing NOS-immunoreactivity. This was due to a substantial, time-dependent, and apparently selective, loss of NOS from extrinsic axons under in vitro conditions. Lastly, a small population of non-immunoreactive biotinamide-filled fibres (<1%) gave rise to dense terminal structures around individual myenteric cell bodies lacking CalR, CalB or NOS. These specialized endings may represent vagal fibres or a subset of spinal sensory neurons that do not contain CGRP.     

Distribution and projections of nerves with enkephalin-like immunoreactivity in the guinea-pig small intestine

Whole mounts of guinea-pig small intestine were used to examine the distribution of neurons with enkephalin-like immunoreactivity and the effects of microsurgical lesions on these neurons. The enkephalin neurons are intrinsic to the intestine. Cell bodies are found in the myenteric ganglia; processes are in the myenteric plexus, circular muscle (including deep muscular plexus) and submucosa, but not in the mucosa. The cell bodies have one prominent process and several short processes, the latter occasionally are seen to give rise in turn to fine, faint processes. The prominent processes provide fibres to the circular muscle and deep muscular plexus beneath and just anal (up to about 2 mm) to the cell bodies. Fibres in the submucous ganglia come from the overlying myenteric plexus. Orally-directed processes (possibly dendrites) of myenteric cell bodies provide the varicose fibres in the myenteric ganglia. These processes are 3.5-4 mm long. The enkephalin neurons represent a population of enteric neurons, with a distinct distribution and projections, which does not correspond to any of the other populations of enteric neurons that have been studied.     

The origins,pathways and terminations of neurons with VIP-like immunoreactivity in the guinea-pig small intestine

We have analyzed changes in the distributions of terminals with vasoactive intestinal polypeptide (VIP)-like immunoreactivity, and accumulations in severed processes, that occur after lesions of intrinsic and extrinsic nerve pathways of the guinea-pig small intestine. The observations indicate that enteric vasoactive intestinal polypeptide immunoreactive neurons have the following projections. Nerve cell bodies in the myenteric plexus provide varicose processes to the underlying circular muscle; the majority of these pathways, if they extend at all in the anal or oral directions, do so for distances of less than 1 mm. Nerve cell bodies of the myenteric plexus also project anally to provide terminals to other myenteric ganglia. The lengths of the majority of these projections are between 2 and 10 mm, with an average length of about 6 mm. Processes of myenteric neurons also run anally in the myenteric plexus and then penetrate the circular muscle to provide varicose processes in the submucous ganglia at distances of up to 15 mm, the average length being 9–12 mm. In addition, there is an intestinofugal projection of myenteric neurons whose processes end around nerve cell bodies of the coeliac ganglia. A similar projection from the colon supplies the inferior mesenteric ganglia. The nerve cell bodies in submucous ganglia give rise to a subepithelial network of fibres in the mucosa and also supply terminals to submucous arterioles.It is concluded that vasoactive intestinal polypeptide is contained in neurons of a number of intrinsic nerve pathways, influencing motility, blood flow and mucosal transport. The myenteric neurons that project to prevertebral sympathetic ganglia may be involved in intestino-intestinal reflexes.     

Expression and possible role of IGF-IR in the mouse gastric myenteric plexus and smooth muscles

Insulin-like growth factor-I (IGF-I) and its receptor (IGF-IR) have tremendous trophic effects on the central, peripheral and enteric neurons. The loss of IGF-IR contributes to the development of diabetic gastroparesis. However, the nature and the function of the IGF-IR⁺ cells in the gastric myenteric plexus remain unclear. In this study, anti-ChAT, anti-S100β or anti-c-KIT antibodies were used to co-label IGF-IR⁺ cells and neurons, glial cells or interstitial cells of Cajal (ICCs), respectively. We also generated type 1 diabetic mice (DM) to explore the influence of impaired IGF-I/IGF-IR in the myenteric neurons. Results showed that IGF-IR was expressed in the epithelium, smooth muscles and myenteric plexi of the mouse stomach. Most of the IGF-IR⁺ cells in the myenteric plexi were ChAT⁺ cholinergic neurons, but not enteric glial cells and there were more IGF-IR⁺ neurons and fibers in the gastric antrum than in the corpus. The IGF-IR⁺/ChAT⁺ neurons and ICCs were closely juxtaposed, but distinctly distributed in the myenteric plexus, indicating a possible role for the IGF-IR⁺/ChAT⁺ neurons in the mediation of gastric motility through ICCs. Moreover, the decrease of IGF-IR and cholinergic neurons in the myenteric plexi and smooth muscles of DM mice suggested that IGF-I/IGF-IR signaling might play a role in neuron survival and neurite outgrowth, as well as stem cell factor (SCF) production, which is required for the development of ICCs. Our results provide insights into the effects of IGF-I/IGF-IR signaling on the development of gastrointestinal motility disorders.     

Distribution of enteric nerve cell bodies and axons showing immunoreactivity for vasoactive intestinal polypeptide in the guinea-pig intestine

Immunoreactivity for vasoactive intestinal polypeptide has been localized in neurons in the guinea-pig ileum, colon and stomach. In the ileum, 2.5% of the nerve cell bodies of the myenteric plexus and 45% of those of the submucous plexus showed vasoactive intestinal polypeptide-like immunoreactivity. Varicose axons containing vasoactive intestinal polypeptide ramified amongst the nerve cell bodies of both plexuses and in some cases formed rings of varicosities around non-reactive nerve cells. Axons were traced from the myenteric plexus to the circular muscle and deep muscular plexus. There were numerous positive axons running in fine strands within the circular muscle, parallel to the muscle bundles. Axons containing vasoactive intestinal polypeptide were associated with mucosal blood vessels, but few supplied the vascular network of the submucosa; some immunoreactive axons also contributed to the periglandular plexus of the mucosa. There were no changes in the distribution of axons in the ileum after extrinsic denervation.The results are discussed in relation to the possible functional roles of neurons that contain vasoactive intestinal polypeptide in the intestine: the distribution of such nerve cells in the myenteric plexus and of axons in the circular muscle and sphincters is consistent with this polypeptide being a transmitter of enteric inhibitory neurons; it is also possible that vasoactive intestinal polypeptide is the enteric vasodilator transmitter.     

Immunocytochemical analysis of potential neurotransmitters present in the myenteric plexus and muscular layers of the corpus of the guinea pig stomach

Recent electrophysiological studies of neurons of the myenteric plexus of the corpus of the guinea pig stomach have revealed that slow synaptic events are extremely rare. In contrast, they are commonly encountered in similar investigations of myenteric ganglia of the guinea pig small intestine. The current immunocytochemical analysis of the myenteric plexus and innervation of the muscularis externa of the corpus of the guinea pig stomach was undertaken in order to determine whether putative neurotransmitters capable of mediating slow synaptic events are present in gastric ganglia. A major difference between the small intestine and the stomach was found in the innervation of the musculature. Whereas the longitudinal muscle layer of the small intestine contains very few nerve fibers and is innervated mainly at its interface with the myenteric plexus, the longitudinal muscle of the corpus of the stomach contained as many varicose substance P (SP)-, vasocative intestinal polypeptide (VIP)-, and neuropeptide Y (NPY)-immunoreactive axons as the circular muscle layer. These putative neurotransmitters were also present in the ganglia of the myenteric plexus, where varicose SP-, VIP-, and NPY-immunoreactive fibers encircled nonimmunoreactive neurons. Varicose 5-hydroxytryptamine (5-HT)-immunoreactive terminal axons were essentially limited to the myenteric plexus and were found both in ganglia and in interganglionic connectives, where they were particularly numerous; 5-HT-immunoreactive neurons appeared to be more abundant in the stomach than in the small intestine. Tyrosine hydroxylase (TH)- and calcitonin-gene-related-peptide (CGRP)-immunoreactive axons were also more common in the myenteric plexus than in the musculature, but of these, only the TH-immunoreactive neurites tended, like those of the other putative transmitters, to encircle neurons in myenteric ganglia. Evidence was obtained that, as in the small intestine, at least some of the SP-, VIP-, NPY-, and 5-HT-immunoreactive fibers in the stomach are derived from intrinsic gastric myenteric neurons. In contrast, unlike the small intestine, gastric myenteric ganglia appeared to lack intrinsic CGRP-immunoreactive neurons; therefore, the CGRP-immunoreactive gastric axons are probably of extrinsic origin.(ABSTRACT TRUNCATED AT 400 WORDS)