Hiroshi Nishiye

Identification of a synaptic vesicle-specific 38,000-dalton protein by monoclonal antibodies

Synaptic vesicles were purified from the guinea pig cerebrum by sucrose density gradient centrifugation, and monoclonal antibodies (MAbs) were produced against this vesicle fraction. Seven MAbs (171B5, 171E8, 174D12, 174H11, 177A2, 177H11 and 178D4) recognized a novel acidic protein of about 38,000 daltons which was specific to synaptic vesicles. In immunofluorescence microscopy, the staining pattern of these MAbs corresponded to the distribution of the synapses in the guinea pig central nervous system. These MAbs appeared to stain all synaptic regions, irrespective of their synaptic function or type of neurotransmitters. MAb 171B5 and 174H11 stained the rat, rabbit and bovine synapses similarly to the guinea pig. Two other MAbs (171E8 and 177H11) stained other mammals weakly but the remaining 3 MAbs reacted only with the guinea pig. In immunoelectron microscopy of both the cerebellar tissue and isolated vesicle fraction, these MAbs selectively labeled the synaptic vesicles but not other structures. Immunoblot analysis was performed on electrophoretically separated proteins in vesicle fraction and brain homogenate. All of 7 MAbs reacted with a band at a molecular weight of about 38,000 from the guinea pig. Isoelectric focussing disclosed that this protein was acidic (pI 4.5-5).

Four synaptic vesicle-specific proteins: identification by monoclonal antibodies and distribution in the nervous tissue and the adrenal medulla

Synaptic vesicles from the guinea-pig cerebrum were isolated and administered to mice for the production of monoclonal antibodies (MAb). Four vesicle-associated proteins in the guinea-pig nervous tissue were specifically and differentially recognized by MAbs thus obtained. These proteins had molecular weights of 30,000, 36,000, 38,000 and 65,000 Da and were named SVPs (synaptic vesicle proteins) 30, 36, 38 and 65, respectively. Immunohistochemistry demonstrated that all SVPs were localized in the synaptic regions throughout the central nervous system and in the adrenal medulla. Nerve terminals in skeletal muscle, smooth muscle and sympathetic ganglion contained SVPs 36 and 38. Immunoelectron microscopy of the cerebellar cortex confirmed the localization of SVPs in the synaptic vesicles and the adjacent membranes of the presynaptic nerve terminals. Fractionation of the cerebral tissue and treatment with various agents showed that SVPs were localized in the synaptic vesicles and the synaptic plasma membrane and that SVPs were integrated within the membrane and liberated only after solubilization of the membrane.

Abnormal distribution of nerve terminals in infantile hypertrophic pyloric stenosis

Smooth muscle biopsy specimens obtained from nine infants with infantile hypertrophic pyloric stenosis (IHPS) and from three controls were studied immunohistochemically with respect to the distribution of nerve terminals and neurofilaments. To label nerve terminals and neurofilaments, monoclonal antibodies (MAb) 171B5 and 2F11 were used, respectively. In all specimens of the control group, nerve terminals were numerous in both the myenteric plexus and the muscle layer. There were abundant neurofilaments in the myenteric plexus and a moderate number in the muscle layer. In all specimens of the IHPS group, the density of nerve terminals and neurofilaments was reduced in the muscle layer. In the myenteric plexus, there was no such reduction. The results indicate poor neuronal innervation of the muscle layer in the pylorus of infants with IHPS. This poor innervation may be related to the pathogenesis of pyloric stenosis and hypertrophy.

Localization of intestinal pacemaker cells and synapses in the muscle layers of a patient with colonic hypoganglionosis

Bowel dysmotility in association with hypoganglionosis remains unexplained. The proto-oncogene c-kit encodes a transmembrane tyrosine kinase receptor, and the c-kit protein-product (C-KIT) positive cells in the mammalian gut are responsible for intestinal pacemaker activity. The authors examined the localization of intestinal pacemaker cells in the muscle layers of a patient with colonic hypoganglionosis, using an antihuman C-KIT serum. In the normoganglionic ileum, many C-KIT immunoreactivity positive (C-KIT-IR+) cells were present in the muscle layers. In contrast, there were no C-KIT-IR+ cells in the muscle layers of the hypoganglionic colon. These findings suggest that a lack of c-kit expression may be responsible for the autonomic gut dysmotility in hypoganglionic bowels.

Cortical synaptogenesis in congenitally hydrocephalic HTX-rats using monoclonal anti-synaptic vesicle protein antibody

We attempted to develop a method for investigating impairment of synaptogenesis quantitatively involving measurement of the fluorescence intensity emitted by immunohistochemically stained rat brain using a monoclonal antibody (Mab 171B5) against a synaptic vesicle protein (SVP-38). We applied this method to congenitally hydrocephalic and non-hydrocephalic brains of HTX-rats, and compared the postnatal changes in the fluorescence intensity in the molecular layer of the cerebral cortex. In non-hydrocephalic HTX-rats, the fluorescence intensity remained nearly unchanged from the 1st to 7th postnatal day and then increased at an almost linear rate until the 21st postnatal day, when it reached 4.5 times the value on the 7th postnatal day. The increase thereafter was gradual until the 28th postnatal day. In hydrocephalic HTX-rats, the fluorescence intensity increased nearly in parallel with that in non-hydrocephalic HTX-rats up to the 21st postnatal day. On the 28th postnatal day, the fluorescence intensity showed a marked reduction (P less than 0.01). This finding indicates that despite the presence of continuous pressure due to progressive ventricular dilatation after birth, synaptogenesis in the cerebral cortex may be relatively resilient.

Hirschsprung's disease : diagnosis using monoclonal antibody 171B5

A new reliable immunohistochemical method for diagnosing Hirschsprungs disease (HD) using our unique monoclonal antibody (MAb) 171B5 against synaptic vesicles is described. Fresh frozen sections of rectal tissues were used from 13 patients with HD aged 2 weeks to 13 months; 9 had rectosigmoid HD and 4 had total colonic aganglionosis (TCA). Comparable normal colonic and rectal specimens were also obtained from 13 age-matched controls. All specimens were labeled with MAb 171B5, to demonstrate neuronal innervation patterns of both mucosa and submucosa. In all control specimens, many synapses arranged in variciform plexuses were seen in the lamina propria, a moderate number in the muscularis mucosae, and dense clusters in the submucosal plexus. In all aganglionic specimens, only scanty numbers of synapses which were not organized in variciform plexuses were seen in the lamina propria, none in the muscularis mucosae, and a few in the submucosa. These findings suggest that MAb 171B5 immunohistochemistry on the lamina propria alone can differentiate between normal and aganglionic bowel and appears to be a reliable and useful method for detecting HD on suction rectal biopsy.

Correlation between extrinsic nerve fibers and synapses in the muscle layers of bowels affected by Hirschsprung's disease

The aim of this study is to clarify any correlation between nerve terminals (synapses) and proliferating extrinsic nerve fibers in the muscle layers of bowels affected by Hirschsprungs disease (HD). Synapses and extrinsic nerve fibers in the muscle layers of bowels of 10 patients with HD and 8 comparable controls were labeled with monoclonal antibody (MAb) 171B5 and acetylcholinesterase (AChE), respectively. In the control a rich and even distribution of synapses, representing neuromuscular junctions, was seen in the muscle layers, together with dense clusters of synapses in the adjacent myenteric plexuses; proliferation of extrinsic nerve fibers was not seen. In the transitional oligoganglionic segment of HD, many synapses were present in the myenteric plexus, but a few synapses in the muscle layers; there was a gradual increase of extrinsic nerve fibers from proximal to distal. In the narrow aganglionic segment very few synapses were seen in the muscle layers; proliferating nerve fibers and bundles were prominent. We conclude that the muscle layers of bowels affected by HD were almost denervated despite presence of intrinsic nervous elements in the oligoganglionic segment and proliferating extrinsic nerve fibers in the aganglionic segment.

Quantitative analysis of neuronal innervation in the aganglionic bowel of patients with Hirschsprung's disease

Although there is marked proliferation of nerve fibers in the aganglionic bowel of patients with Hirschsprungs disease (HD), controversy exists as to whether these fibers terminate in the cells of the bowel wall. This study quantitates biochemically the synaptic vesicle proteins and neurofilaments in the aganglionic bowel of HD patients. The bowel specimens obtained from 12 patients with HD (mean age, 4.6 months) and nine age-matched controls were analyzed by Western blot analysis using monoclonal antibody 171B5 against the synaptic vesicle 38,000-d protein (SVP38), and the specific band obtained was quantitated by densitometry. Similarly, using monoclonal antibody NF70K for detecting the 70,000-d component of neurofilament (NF70), nerve fibers were quantitated. In the aganglionic HD bowel, the quantity of SVP38, representing a proportion of synapses, was significantly lower than that in the normoganglionic bowel (P < .001). The quantity of NF70, representing a proportion of nerve fibers, was significantly greater than that in the normoganglionic bowel (P < .05). These findings suggest that the nerve fibers in the aganglionic bowel of HD patients have much less developed connections with the cells of the bowel wall, indicating overall poor innervation, despite marked proliferation of the nerve fibers.

Abnormal distribution of nerve terminals in the normoganglionic bowel of Hirschsprung's disease: a causative factor of failed pull-through operations?

The aim of this study was to examine the innervation pattern of the muscle layers of normoganglionic pulled-through bowel in patients with Hirschsprungs disease (HD) by observing the distribution of nerve terminals comprising neuromuscular junctions and synapses. As a marker for nerve terminals, monoclonal antibody (MAb) 171B5 was used. Pulled-through normoganglionic bowel from 12 patients with HD that was either biopsied or resected at operation and normal bowel specimens from 7 age-matched controls were labelled using an immuno-histochemical technique with MAb 171B5. In all specimens of the control group and 9 patients of the HD group, numerous neuromuscular junctions were demonstrated in the muscle layers of the normoganglionic bowel and numerous synapses in the myenteric plexuses. However, in the specimens of 3 patients of the HD group abnormal distribution of nerve terminals was seen in the normoganglionic bowel. Two of these 3 patients had abnormal postoperative defecation. Based on our study, there appears to be a small number of HD patients who have an innervation disorder of the muscle layers in the proximal, normoganglionic bowel pulled through at surgery, which hitherto have been thought to be normal.

A new method for electron microscopic observation of isolated synaptic vesicles labelled with monoclonal antibody

The immunoreaction of a monoclonal antibody (Mab) and an isolated synaptic vesicle (SV) was processed on a grid mesh and the result could be easily observed with electron microscopy. The SV suspension was obtained and dispersed on the grid mesh where immunoreaction procedures were performed. The resulting immunoreaction was visualized by labelling with ferritin particle (FAD) or horseradish peroxidase (HRP) for the electron microscopic observation. The SV specimen was observed by electron microscopy after faint negative staining with 1% uranyl acetate. With this method, the positive immunoreaction of Mab 171B5 and the isolated SV could be easily identified by the formation of a halo of FAD or a cobweb of HRP surrounding the SV. In the control experiment, the SV specimen was incubated with normal mouse serum instead of the Mab while the other procedures were performed in the same way. The SV was not outlined by FAD in the control experiment. Thus, the positive immunoreaction of the Mab and SV was thought to be an immunologically specific one. It was also determined that the Mab reacted specifically with the SV but not with the small membrane fragments and other unknown material. The present method seems to be useful for observing the immunoreaction of subcellular structures and their antibodies under electron microscopy.