Protein 4.1B localizes on unmyelinated axonal membranes in the mouse enteric nervous system

Recent molecular studies on anchoring structures between myelin sheaths by glial cells (oligodendrocytes and Schwann cells (Sc) in the central (CNS) and peripheral nervous system (PNS), respectively) and axons indicated protein-protein interaction for the polarization of paranodes in the axons. The protein 4.1 (4.1) family was originally found in erythrocytes as a component of membrane skeletons, and genetic approaches revealed the precise family members. One of them, 4.1B, has been reported to be localized in paranodes and juxtaparanodes of myelinated axons. In this study, in addition to the myelinated axons, we also present the localization of 4.1B in nerve fibers in the adult mouse enteric nervous system, a subpopulation of mature unmyelinated nerve fibers in PNS. Ultrastructurally, 4.1B localized along the membranes of unmyelinated axons. Such unmyelinated axons were surrounded only by Sc, suggesting that the 4.1B may also have a role in direct Sc-axon interactions and maturation of the axons, as well as myelinating glial cell-axon interactions.     

The transthyretin gene is expressed in human and rodent dorsal root ganglia

The transthyretin (TTR) gene is mainly expressed in the liver and choroid plexus of the brain. Most cases of familial amyloidotic polyneuropathy (FAP) are caused by TTR gene mutations, and characterized by amyloid deposition in the peripheral nervous system. We hypothesized that the TTR gene may be expressed in the peripheral nervous system. We analyzed TTR gene expression in several parts of the human, mouse and rat peripheral nervous systems using RT-PCR. To determine the sites of TTR synthesis in the dorsal root ganglia (DRG), mouse DRG were examined by in situ hybridization, laser capture microdissection and RT-PCR, and immunohistochemistry. TTR mRNA was detected in the DRG and cauda equina of humans and rodents by RT-PCR. TTR mRNA was not detected in the sural nerve, lumbar plexus or sympathetic ganglia in humans, or in the sciatic nerve in rodents. In mouse DRG, TTR mRNA was localized in the peripheral glial cells. No TTR-like immunoreactivity was observed in these tissues except for the perineurium. The TTR gene is probably expressed in the peripheral glial cells of the DRG. TTR synthesis in the DRG may be important for the involvement of the peripheral nervous system in FAP.     

Calretinin in the peripheral nervous system of the adult zebrafish

Calretinin is a calcium-binding protein found widely distributed in the central nervous system and chemosensory cells of the teleosts, but its presence in the peripheral nervous system of fishes is unknown. In this study we used Western blot analysis and immunohistochemistry to investigate the occurrence and distribution of calretinin in the cranial nerve ganglia, dorsal root ganglia, sympathetic ganglia, and enteric nervous system of the adult zebrafish. By Western blotting a unique and specific protein band with an estimated molecular weight of around 30 kDa was detected, and it was identified as calretinin. Immunohistochemistry revealed that calretinin is selectively present in the cytoplasm of the neurons and never in the satellite glial cells. In both sensory and sympathetic ganglia the density of neurons that were immunolabelled, their size and morphology, as well as the intensity of immunostaining developed within the cytoplasm, were heterogeneous. In the enteric nervous system calretinin immunoreactivity was detected in a subset of enteric neurons as well as in a nerve fibre plexus localized inside the muscular layers. The present results demonstrate that in addition to the central nervous system, calretinin is also present in the peripheral nervous system of zebrafish, and contribute to completing the map of the distribution of this protein in the nervous system of teleosts.     

Glial cell line-derived neurotrophic factor family receptors are abnormally expressed in aganglionic bowel of a subpopulation of patients with Hirschsprung's disease

Hirschsprung's disease (HSCR), a congenital disease, is characterized by the absence of ganglion cells in the ganglion plexuses of the caudal most gut. In the aganglionic colon, the plexus remnants are replaced by aggregates of glial cells and hypertrophied nerve fibers. Signaling of glial cell line-derived neurotrophic factor (GDNF)-GFRAs-receptor tyrosine kinase (RET) is crucial for the development and maintenance of ganglion cells. Mutations of genes such as GDNF and RET lead to the perturbation of this signaling pathway, which causes HSCR. To understand the role of GFRAs in ganglion cells and the pathogenesis of HSCR, we intended to determine the specific cell lineages in the enteric nervous system that normally express GFRAs but are affected in HSCR. We studied colon biopsy specimens from 13 patients with HSCR (aged 1 day to 38 months) and 6 age-matched patients without HSCR as normal controls. RT-PCR, in situ hybridization, and immunohistochemistry were performed to examine the expression and cellular distributions of GFRAs in resected bowel segments of normal infants and those with HSCR. In normal infants and normoganglionic colon of patients with HSCR, the expression of GFRA1 was restricted to the glial cells and neurones of the ganglion plexuses. GFRAs expression was found to be markedly reduced in the aganglionic colons of 3 infants with HSCR but was unaffected in the aganglionic colons of 10 other infants with HSCR. Residual GFRA expression was restricted to enteric glial cells in the plexus remnants of the aganglionic colons. Hypertrophied nerve fibers were not found to express GFRA1. We provide the first evidence that abnormal expression of GFRAs in the enteric nervous system may be involved in the pathogenesis of HSCR in a subpopulation of patients.     

The development of avian enteric nervous system: distribution of artemin immunoreactivity

Among the factors that control neural crest cell precursors within the enteric nervous system, the ligands of the glial cell line-derived neurotrophic factor family (GFL) seem to be the most influential. Artemin, a member of the GFLs, was previously described only in the oesophagus and stomach of mouse embryos. In this study, the presence and distribution of artemin is reported in duck embryos and adults. Artemin immunoreactivity was apparent in the intestinal tract at embryonic day 7 (d7), firstly in the myenteric plexus and then in the submucous plexus. Later, artemin immunoreactive nerve fibres were also seen in the longitudinal muscle plexus, the circular muscle plexus, the plexus of the muscularis mucosa and in the mucosal plexus. Furthermore, at d7, weak labeling of artemin was detected in neurons and glial cells in the oesophagus, gastric region and duodenum. Subsequently, artemin was also detected in all other intestinal segments. Moreover, during development of the gut in the domestic duck, artemin immunoreactivity decreased in neuronal cell bodies, whilst it increased in neuronal fibres and glial cells. These findings suggest an involvement of artemin in the development and biology of the gut of the domestic duck.     

Enterisches Nervensystem und interstitielle Cajal-Zellen

Intestinal innervation disorders are part of the broad etiological spectrum of chronic constipation and need to be specifically addressed in differential diagnosis. The enteric nervous system constitutes the largest peripheral nervous system of its own ("brain in the gut"), and is involved in the mediation of intestinal motility. Morphologically different nerve cell types aggregate into intramural plexus layers and release a multitude of neurotransmitters. Malformations or lesions of the enteric nervous system may lead to a severely prolonged intestinal transit time resulting in chronic constipation resistant to conservative treatment. In contrast to the early manifestation of aganglionosis, non-aganglionic or acquired alterations to the intramural nerve plexus often remain unrecognised up to adulthood. Histopathological diagnosis is carried out by enzyme or immunohistochemical staining, either on sections or whole mount preparations, allowing an optimal visualization of the nerve plexus architecture. To diagnose hypoganglionosis, enteric ganglionitis or alterations in interstitial cells of Cajal, full-thickness biopsies are required. Interstitial cells of Cajal contribute significantly to the mediation of intestinal motility by generating "slow wave" activity. In adult patients with slow-transit constipation and megacolon, the intramuscular networks of the interstitial cells of Cajal show a significantly reduced density.     

Abnormalities of smooth muscle, basal laminae, and nerves in the aganglionic segments of the bowel of lethal spotted mutant mice

The terminal portion of the bowel of the lethal spotted mutant mouse (ls/ls) lacks an enteric nervous system due to the failure of neural crest precursors to colonize this region during embryonic life. As a result, the mouse develops congenital megacolon. We have postulated that the defect occurs because the microenvironment of the aganglionic segment is segmentally abnormal and does not permit the migration and/or survival of the enteric neural or glial precursors in the affected zone. We have examined the terminal segment of adult ls/ls and control mice by light and electron microscopy to determine if the defect is associated with identifiable structural abnormalities that persist to maturity. A striking abnormality is an overgrowth of the muscularis mucosa in the adult ls/ls mouse, particularly in the outer longitudinal layer. Electron microscopy also reveals an extensive thickening of the basal lamina around smooth muscle cells. In addition, nerves that are derived from fibers that are extrinsic to this area are abnormal. Large bundles of nerve fibers, some of which contain myelinated axons, large-caliber unmyelinated axons, and abundant collagen, are prominent in the intermuscular region of the aganglionic segments and often reach into the submucosa. The supporting cells of the unmyelinated and myelinated nerves in the aganglionic segment have voluminous perineural cytoplasm typical of immature Schwann cells. They also exhibit intermediate filaments in their cytoplasm. Otherwise they have the typical morphology of peripheral Schwann cells, rather than enteric glia, including individual ensheathment of axons and a surrounding basal lamina. We suggest that the extracellular matrix and/or cells of mesenchymal origin of the terminal bowel of the ls/ls mouse may prevent the ingrowth of the normal precursors of the glia as well as neurons of the enteric nervous system, but may permit or even encourage the ingrowth of abnormal numbers of extrinsic axons.     

Familial amyloidotic polyneuropathy type 1 in Kumamoto, Japan: a clinicopathologic, histochemical, immunohistochemical, and ultrastructural study

Seventeen autopsy and five biopsy cases of familial amyloidotic polyneuropathy were examined clinicopathologically, histochemically, immunohistochemically, and ultrastructurally. In the autopsy cases, amyloid deposits were predominant in the peripheral nerve tissues, autonomic nervous system, choroid plexus, cardiovascular system, and kidneys. Amyloid involvements in the anterior and posterior roots of the spinal cord, spinal ganglia, thyroid, and gastrointestinal tract were also frequent. In the cardiac conduction system, amyloid deposition was prominent in the sinoatrial node and in limbs of the intraventricular bundle. In the sural nerve biopsy, besides amyloid deposits, degenerative changes of nerve fibers and Schwann cells were detected ultrastructurally, and the morphometric analysis showed a marked reduction in the number of myelinated fibers which correlated with the clinical stage. Amyloid deposits were resistant to pretreatment with potassium permanganate in Congo red staining, and transthyretin was confirmed immunohistochemically as a major component of amyloid deposits, along with the presence of serum amyloid P-component. Besides the amyloid deposits, transthyretin was proven in the liver cells, epithelial cells of the choroid plexus, and pancreatic islet A cells, suggesting that the transthyretin produced by these cells is secreted, transferred into tissues, and deposited in situ as the major component of amyloid in this disorder.     

Distribution of Podoplanin-Expressing Cells in the Mouse Nervous Systems

Podoplanin is a mucin-type glycoprotein which was first identified in podocytes. Recently, podoplanin has been successively reported as a marker for brain and peripheral nerve tumors, however, the distribution of podoplanin-expressing cells in normal nerves has not been fully investigated. This study aims to examine the podoplanin-expressing cell distribution in the mouse head and nervous systems. An immunohistochemical study showed that the podoplanin-positive areas in the mouse peripheral nerve and spinal cord are perineurial fibroblasts, satellite cells in the dorsal root ganglion, glia cells in the ventral and dorsal horns, and schwann cells in the ventral and dorsal roots; in the cranial meninges the dura mater, arachnoid, and pia mater; in the eye the optic nerve, retinal pigment epithelium, chorioidea, sclera, iris, lens epithelium, corneal epithelium, and conjunctival epithelium. In the mouse brain choroid plexus and ependyma were podoplanin-positive, and there were podoplanin-expressing brain parenchymal cells in the nuclei and cortex. The podoplanin-expressing cells were astrocyte marker GFAP-positive and there were no differences in the double positive cell distribution of several portions in the brain parenchyma except for the fornix. The results suggest that podoplanin may play a common role in nervous system support cells and eye constituents.     

先天性巨结肠病肠壁NOS阳性神经元光镜和电镜观察

目的：探讨NOS阳性神经元与先天性巨结肠病病因及病理机制的关系。方法：对扩张段和移行段肠壁分别作全层铺片,NADPH－d酶组织化学染色,光镜和扫描电镜下观察NOS阳性神经结构。结果：扩张肠段光镜下肠肌丛神经节和神经元均较大,节内神经元染色深数量多,沿神经节周边及神经纤维发出处排列。扫描电镜下神经元胞体较大,排列较密,发出的神经纤维较多,在各个方向上相互连接。沿肌纤维排列的神经元之间有较多的横向连接纤维,肠肌丝社会元还通过穿行于环行肌层的神经纤维和粘膜下层神经元相连接,移行段光镜下节内神经元胞浆染色较淡,深浅不一,神经节和神经元均较小,发现的纤维细且染色较淡,扫描电镜下神经元胞形较小,且大小不等,密较较小,神经元间的纤维联系及神经纤维攀附于肌纤维表面的现象均较少,神经元和神经纤维呈沿纵行肌长轴线性分布。结论：先天性巨结肠病的发生及发展可与NOS阳性神经元在肠壁的分布与代谢异常有关关。     

Expression of bcl-2 in enteric neurons in normal human bowel and Hirschsprung disease

OBJECTIVE: The bcl-2 protein has the functional role of blocking apoptosis, ie, programmed cell death. This protein is widely expressed in the developing central and peripheral nervous systems. The purpose of this study was to map bcl-2 expression in the human enteric nervous system, as this has not previously been done. METHODS: Rectal specimens were obtained at autopsy of 13 fetuses at 13 to 31 weeks of gestation. Normal colon was also obtained from 5 children and 2 adults, and, in addition, ganglionic and aganglionic bowel resected in 11 patients with Hirschsprung disease was examined. Specimens were fixed in formalin, embedded in paraffin, and analyzed with immunohistochemical methods, using antibodies raised against bcl-2 and neuron-specific enolase (NSE). RESULTS: The bcl-2 protein was expressed in myenteric and submucous ganglion cells in fetuses, children, and adults. Nerve fibers of the enteric plexuses that were bcl-2 immunoreactive were few compared with the number of NSE-immunoreactive nerve fibers. In aganglionic bowel no bcl-2-or NSE-immunoreactive ganglion cells were revealed. Results of NSE immunohistochemistry showed clearly stained hypertrophic nerve bundles, known to be of extrinsic origin, which were only weakly bcl-2 immunoreactive. CONCLUSION: Expression of bcl-2 in enteric ganglion cells of the myenteric and submucous plexuses is displayed in the fetus and during childhood and is also retained in adult bowel. Immunohistochemical analysis of bcl-2 provides a good marker for identification of ganglion cells in Hirschsprung disease and may also be valuable for the diagnosis of disorders characterized by hypoganglionosis or hyperganglionosis.     

Trisomy 16鼠结肠和人先天性巨结肠蛋白基因产物9.5的表达

目的：研究Ｄｏｗｎ’ｓ 综合征动物模型ｔｒｉｓｏｍｙ １６ 结肠神经系发育和先天性巨结肠（ＨＤ） 病变肠管蛋白基因产物９－５（ｐｒｏｔｅｉｎ ｇｅｎｅ ｐｒｏｄｕｃｔ９ ．５ ,ＰＧＰ９－５） 的神经表达。方法：Ｔｒｉｓｏｍｙ １６ 鼠培育;细胞遗传学分析;Ｔｒｉｓｏｍｙ １６ 鼠结肠和ＨＤＰＧＰ９－５ 免疫组织化学。结果：（１）Ｔｒｉｓｏｍｙ １６ 鼠结肠神经系发育异常,肌间神经丛发育迟缓,粘膜下神经丛缺失,结肠末端有５ ｍｍ 的无神经节区,但结肠系膜神经发育良好;（２）ＨＤ狭窄段肠管ＰＧＰ９－５ 阳性神经纤维大量增生,神经节细胞缺如。结论：（１）Ｔｒｉｓｏｍｙ １６ 鼠具有稳定的遗传学特征,可能伴先天性巨结肠。（２） 由于ＨＤ 狭窄段肠管神经节细胞缺失,增生的ＰＧＰ９－５ 阳性神经纤维是肠道外源性神经的代偿,对其神经元的性质尚有待确定。（３）ＨＤ有遗传倾向     

A neuronal subpopulation in the mammalian enteric nervous system expresses TrkA and TrkC neurotrophin receptor-like proteins

Increasing evidence suggests that, in addition to peripheral sensory and sympathetic neurons, the enteric neurons are also under the control of neurotrophins. Recently, neurotrophin receptors have been detected in the developing and adult mammalian enteric nervous system (ENS). Nevertheless, it remains to be established whether neurotrophin receptors are expressed in all enteric neurons and/or in glial cells and whether expression is a common feature in the enteric nervous system of all mammals or if interspecific differences exist. Rabbit polyclonal antibodies against Trk proteins (regarded as essential constituents of the high-affinity signal-transducing neurotrophin receptors) and p75 protein (considered as a low-affinity pan-neurotrophin receptor) were used to investigate the cell localization of these proteins in the ENS of adult man, horse, cow, sheep, pig, rabbit, and rat. Moreover, the percentage of neurons displaying immunoreactivity (IR) for each neurotrophin receptor protein was determined. TrkA-like IR and TrkC-like IR were observed in a neuronal subpopulation in both the myenteric and submucous plexuses, from esophagus to rectum in humans, and in the jejunum-ileum of the other species. Many neurons, and apparently all glial cells, in the human and rat enteric nervous system also displayed p75 IR. TrkB-like IR was found restricted to the glial cells of all species studied, with the exception of humans, in whom IR was mainly in glial cells and a small percentage of enteric neurons (about 5%). These findings indicate that the ENS of adult mammals express neuronal TrkA and TrkC, glial TrkB, and neuronal-glial p75, this pattern of distribution being similar in all examined species. Thus, influence of specific neurotrophins on their cognate receptors may be considered in the physiology and/or pathology of the adult ENS. Anat. Rec. 251:360–370, 1998. © 1998 Wiley-Liss, Inc.     

An ultrastructural study of neurons and non-neuronal cells in the myenteric plexus of the rabbit colon

The myenteric plexus of the rabbit colon showed a degree of structural organization that was unusually high for the peripheral nervous system, providing a basis for the complex integrative activity which is known to occur. It resembled central nervous tissue in several respects: a wide range of neuron types was present; the proportion of glial cells to neurons was about 2:1; and there was a densely packed, avascular neuropil, not penetrated by connective tissue. Most neurons had at least one surface exposed to the extraganglionic space. Clear evidence was obtained for spontaneous neuronal degeneration. Three types of non-neuronal (glial) cells were observed: Type 1, which was most common, contained many 10 nm ‘gliofilaments’ and resembled enteric glial cells or astrocytes in the central nervous system; Type 2, composing about 5% of the glial cells, had few filaments; Type 3 was seen only rarely, had a small dark nucleus, little cytoplasm, may have been of extraganglionic origin and resembled microglia of the central nervous system. Fibroblast-like cells were also present in extraganglionic sites. Schwann cells could not be identified within the myenteric ganglia.     

Organization of the enteric nervous system in the human colon demonstrated by wholemount immunohistochemistry with special reference to the submucous plexus.

To demonstrate the normal topography and structure of the enteric nervous system (ENS) in the human colon, the colonic wall of patients (n = 10, mean age 66.3 years), who underwent abdominal surgery unrelated to intestinal motility disorders, was submitted to wholemount immunohistochemistry. The specimens were stretched out and separated into the tunica muscularis, the outer and inner portion of the tela submucosa and the tunica mucosa. Prior to the application of the neuronal marker Protein Gene Product (PGP) 9.5, the laminar preparations were pretreated with the maceration agent KOH. The plexus myentericus was composed of prominent ganglia and interconnecting nerve fiber strands (NFS) forming a polygonal network, which was denser in the descending than in the ascending colon. Nerve cells were observed within the ganglia as well as in primary, secondary and tertiary NFS. The latter ramified into the adjacent smooth muscle layers, which contained the aganglionated plexus muscularis longitudinalis and circularis. The submucous plexus comprised three nerve networks of different topography and architecture: the delicate plexus submucosus extremus consisted of parallel orientated NFS with isolated nerve cells and small ganglia and was located at the outermost border of the tela submucosa adjacent to the circular muscle layer. The plexus submucosus externus was closely associated with the plexus submucosus extremus and composed of larger ganglia and thicker NFS. The plexus submucosus internus was situated adjacent to the lamina muscularis mucosae and formed a network with denser meshes but smaller ganglia and NFS than the plexus submucosus externus. The NFS of the aganglionated plexus muscularis mucosae followed the course of the smooth muscle cells of the lamina muscularis mucosae. The honeycomb-like network of the plexus mucosus was located within the lamina propria mucosae and divided into a subglandular and a periglandular portion. Single and accumulated nerve cells were observed within the plexus mucosus as a regular feature. The findings confirm the complex structural organisation of the ENS encountered in larger mammals, in particular the subdivision of the submucous plexus into three different compartments. PGP 9.5-immunohistochemistry applied to wholemount preparations comprehensively visualized the architecture of the intramural nerve plexus in human colonic specimens. In addition to conventional cross-sections, this technique allows a subtle assessment and classification of structural alterations of the ENS in patients with colorectal motor disorders.     

人直肠肌间神经丛透射电镜的观察

目的研究人直肠肌间神经丛形态学的微观结构。方法采用国人成年直肠标本,经LKB-V型超薄切片机制成半薄切片,在直肠半薄切片上定位肌间神经丛后,进行超薄切片,厚度为50～70nm。醋酸铀、柠檬酸铅染色,JEOL-100CX透射电镜观察。结果在典型的肌间丛神经节可观察到3种细胞成分,即被囊细胞、胶质细胞和神经节细胞。根据神经节细胞间电子密度不同,可将神经节细胞分为明细胞和暗细胞两类。结论人直肠肌间神经丛含有与中枢神经系统相似的细胞成分,神经节内含有丰富神经胶质细胞,其与神经元的比例为2∶1,神经元发出“翼翅”状突起。