Adhesion Molecule Immunoreactivity Research Articles

Neuronal immaturity in normoganglionic colon from cases of Hirschsprung disease, anorectal malformation, and idiopathic constipation

Aim Immaturity of neurons in normoganglionic colon in Hirschsprung disease (HD), anorectal malformation (AM), idiopathic constipation (IC), and normal controls (C) was assessed using polysialyated neural cell adhesion molecule. Methods Polysialyated neural cell adhesion molecule immunoreactivity in 3 sections of normoganglionic colon from HD (n = 48), AM (n = 25), IC (n = 36), and C (n = 18) were scored semiquantitatively according to age; 1 day to 11 months (G1), 1 to 4 years (G2), and 5 years and older (G3). Results Neurons in all specimens appeared mature irrespective of age on hematoxylin-eosin stain. Polysialyated neural cell adhesion molecule was positive (immaturity) in all specimens during G1 (1.34 in HD, 1.60 in AM, 0.89 in IC, and 1.59 in C) and decreased significantly with age in C (0.34* for G2, 0.25* for G3; * P < .01), decreased after 4 years old in IC (0.93 for G2, 0.10 # for G3; # P < .05), decreased gradually in AM (1.10 for G2, 0.75 § for G3; § P < .05), but remained strongly positive in HD (1.34 for G1, 1.26 for G2, and 1.21 for G3; P = not significant), which after 4 years was significantly higher than C ( P < .05). Conclusion Postoperative colonic dysmotility may be because of persistence of immature neurons in HD and impaired maturation of neurons in AM and IC.

Characterization of the subventricular zone neurogenic response to rat malignant brain tumors

The subventricular zone (SVZ) is one of the neurogenic regions of the adult brain. We characterized the neurogenic response of the SVZ to the growth of brain tumors in the rat striatum. Abundant nestin positive cells, most likely representing reactive astrocytes, were found surrounding the tumor. However, we observed no substantial migration of nestin positive cells from the SVZ toward the tumor. Tumor growth resulted in decreased numbers of bromodeoxyuridine positive and Ki-67 positive proliferating cells and a concomitant increase in doublecortin and polysialylated neural cell adhesion molecule immunoreactivity within the SVZ. Neuroblasts were observed in high numbers in the area between the SVZ and the tumor, most likely pointing to the SVZ as the principal source of these cells. Neuroblasts located between the SVZ and the tumor expressed the transcription factor Pbx, a marker for immature striatal neurons. However, no evidence of neuroblast differentiation into fully mature neurons was found. This study thus demonstrates increased neuroblast immunoreactivity within the SVZ ipsilateral to a brain tumor in the striatum. SVZ-derived neuroblasts attracted by the tumor adopt an immature striatal phenotype indicating a region specific reparative mechanism in response to a malignant tumor.

Notch-1 regulates pulmonary neuroendocrine cell differentiation in cell lines and in transgenic mice

The notch gene family encodes transmembrane receptors that regulate cell differentiation by interacting with surface ligands on adjacent cells. Previously, we demonstrated that tumor necrosis factor-alpha (TNF) induces neuroendocrine (NE) cell differentiation in H82, but not H526, undifferentiated small cell lung carcinoma lines. We now test the hypothesis that TNF mediates NE cell differentiation in part by altering Notch gene expression. First, using RT-PCR, we determined that TNF treatment of H82, but not H526, transiently decreases notch-1 mRNA in parallel with induction of gene expression for the NE-specific marker DOPA decarboxylase (DDC). Second, we treated H82 and H526 with notch-1 antisense vs. sense oligodeoxynucleotides. Using quantitative RT-PCR and Western analyses we demonstrate that DDC mRNA and protein are increased in H82 by notch-1 antisense, whereas notch-1 mRNA and activated Notch-1 protein are decreased. mRNA for Hes1, a transcription factor downstream from activated Notch, is also decreased by Notch-1 antisense in H82 but not H526. After 7 days of Notch-1 antisense treatment, neural cell adhesion molecule (NCAM) immunoreactivity is induced in H82 but not H526. Third, we generated transgenic mice bearing notch-1 driven by the neural/NE-specific calcitonin promoter, which express activated Notch-1 in developing lung epithelium. Newborn NotchCal mouse lungs have high levels of hes1 mRNA, reflecting increased activated Notch, compared with wild-type. NotchCal lungs have decreased CGRP-positive NE cells, decreased protein gene product 9.5 (PGP9.5)-positive NE cells, and decreased gastrin-releasing peptide (GRP), CGRP, and DDC mRNA levels compared with normal littermates. Cumulatively, these observations provide further support for a role for Notch-1 signaling in regulating pulmonary NE cell differentiation.

Satellite Cell Activation in Response to 16 Weeks Resistance Loading in Young and Older Adults

Satellite cells are widely considered integral to the mechanisms of load-induced muscle growth/regeneration. However, differential responses of mitogenic/myogenic factors to resistance loading (RL) suggest load mediated satellite cell activation is influenced by age and/or gender. PURPOSE: To directly quantify the number of satellite cells in situ to determine if differences exist by age, gender, or training state (pre-/post 16-wk RL). METHODS: Twelve young (25.0 ± 1 yr, 6 men, YM; 6 women, YF) and 11 older (63.1 ± 1 yr, 6 men, OM; 5 women, OF) adults trained knee extensors by leg press, knee extension, and squat 3 d/wk, 3 sets x 8–12 repetitions, with training loads of 70–80% one-repetition maximum. At baseline and after 16 wk RL, a needle biopsy was taken from m. vastus lateralis. Satellite cells were identified by neural cell adhesion molecule immunoreactivity (NCAM CD-56). Nuclei were counterstained with Mayer's hematoxylin. Satellite cells were denned as nuclei stained brown or with a brown rim localized to the muscle fiber membrane. Total number of nuclei, satellite cells per 100 fibers (SC/100), myonuclei per fiber, mean myofiber area (MFA), and myonuclear domain (myofiber area per nucleus) were quantified. RESULTS: Myofiber hypertrophy based on MFA occurred in YM only (1693 μn2, P<0.05) with no other group showing significant growth. SC/100 did not differ between groups at baseline (YF, 8.7; YM, 12.9; OF, 11.8; OM, 13.9). An overall training effect for SC/100 (28% increase, P<0.05) was driven primarily by YM (59% increase, P<0.05). An age x training interaction (P<0.05) for myonuclei per fiber was driven by YM (+28%) combined with declining trends in older adults (−6%). Pre-training, myonuclear domain was greatest in YM (2002 μm2) and lower in women and older adults (P<0.05), with the smallest domain among OF (1389 μm2). YM were the only age-gender group to maintain myonuclear domain with training (post: 2083 μm2). The other groups began training with a myonuclear domain below a theoretical ceiling (approximately 2000 μm2) and the domain tended to expand with training (main training effect, P<0.01; YF, 17%; OF, 31%; OM, 15%) coincident with subtle trends toward hypertrophy. CONCLUSIONS: After 16 wk RL, some hypertrophy occurs without the fusion of new nuclei. This initial hypertrophy is halted once a ceiling size is reached for myonuclear domain with further hypertrophy requiring the recruitment of additional nuclei. Young men were the only age-gender group to maintain the myonuclear domain ceiling at baseline and add new nuclei in order to maintain the myonuclear domain during load-mediated hypertrophy. Funded by NIAR01 AG17896.

Complete innervation profile of whole bowel resected at pull-through for Hirschsprung’s disease. Unexpected findings

We used Acetylcholinesterase (AchE) staining and neural cell adhesion molecule (NCAM) immunoreactivity to examine such resected lengths to determine the complete innervation profile of resected bowel in Hirschsprung's disease (HD). Resected specimens of colon obtained at pull-through surgery from 15 patients with HD [short type (S-type: n=5), recto-sigmoid type (RS-type: n=5), long type (L-type: n=5)] were sectioned at 1.5 cm intervals and stained conventionally with AchE histochemistry and NCAM immunohistochemistry. The number of positive nerve fibers (PNFs) in the lamina propria and smooth muscle layers was assessed on a scale of 0 to 3 where 0 meant no PNF and 3 meant many PNFs. The three types of HD had different AchE and NCAM innervation profiles, especially the L-type. There were also different AchE and NCAM innervation patterns seen within the same aganglionic or transitional segments of bowel depending on the site of sampling. The mean proportion of transitional segment in resected specimens from RS-type HD was significantly larger than that of S-type HD (P<0.001) although the proportion of aganglionic segments from S- and RS-type HD were almost the same. Our results suggest that the etiology of L-type HD may be different from the etiology of S- and RS-type HD because of different innervation profiles. Because segments of the excised bowel would appear to have different innervation patterns depending on whether the specimen is sampled proximally or distally, it is important to record the exact site of sampling to allow valid comparisons between types of HD to be made.

Localization of neural cell adhesion molecule and pan-cadherin immunoreactivity in intrauterine growth-retarded newborn rat kidneys.

To examine the expression and distribution pattern of neural cell adhesion molecule (N-CAM) and pan-cadherin immunoreactivity in intrauterine growth retardation (IUGR) newborn kidneys, we used a rat model of maternal protein restriction throughout pregnancy. Weak or moderate immunoreactivity for N-CAM and pan-cadherin was seen in some proximal tubules, in the thick segments of Henle, and in the collecting tubules of the control sections. However, the number of tubules expressing N-CAM and pan-cadherin was increased in the IUGR group compared with the control group. Increased density of N-CAM and pan-cadherin immunoreactivity was observed mostly in the proximal tubules, in the thick segments of Henle, and in the collecting tubules of IUGR newborn rat kidneys. Furthermore, N-CAM and pan-cadherin immunoreactivity was present in the thin limb of Henle in the IUGR group, whereas it was absent in the control group. Glomeruli were negative in both groups except for some glomeruli that showed very weak N-CAM staining in the IUGR group. Thus it was demonstrated for the first time that IUGR newborn rat kidneys express N-CAM and cadherin adhesion molecules at specific sites of the nephron.

Biochemical and ultrastructural analyses of iglon cell adhesion molecules, kilon and obcam in the rat brain

Kilon ( kindred of Ig LON) and opioid-binding cell adhesion molecule belong to the IgLON subgroup of immunoglobulin superfamily together with the limbic system-associated membrane protein and neurotrimin. In the present study, we have analyzed biochemical and ultrastructural characterization of Kilon and opioid-binding cell adhesion molecule such as regional and developmental expression patterns, light and electron microscopic localization, and intermolecular interactions. Western blotting revealed a widespread distribution pattern of Kilon with high expression levels in the olfactory bulb, cerebral cortex, diencephalon, hippocampus, and cerebellum and low expression levels in the medulla oblongata and spinal cord. In contrast, opioid-binding cell adhesion molecule showed a regionally restricted expression pattern with high levels only in the cerebral cortex and hippocampus. Expression of Kilon and opioid-binding cell adhesion molecule was increased gradually during postnatal development and maintained until adulthood. Light microscopic immunohistochemistry demonstrated that the localization of opioid-binding cell adhesion molecule and Kilon coincided well with that of vesicle-associated membrane protein 2, a synaptic marker protein, in the cerebral cortex and hippocampus of adult brain. In the cerebellum, Kilon-immunoreactive puncta were observed to colocalize well with that of vesicle-associated membrane protein 2, while opioid-binding cell adhesion molecule immunoreactivity was observed only at part of synaptic glomeruli in the granular layer and rare in the molecular layer. Electron microscopic analysis revealed that Kilon and opioid-binding cell adhesion molecule immunoreactivity was observed mainly at postsynaptic sites of dendritic and somatic synapses in adult cerebral cortex and hippocampus. Only trace levels of Kilon and opioid-binding cell adhesion molecule were detected in the soluble fraction of a cortical homogenate, although a substantial amount of F3 was present in the soluble fraction. A binding analysis using a cross-linker and the immunoprecipitation technique demonstrated that Kilon and opioid-binding cell adhesion molecule interacted heterophilically and homophilically. These findings show that Kilon and opioid-binding cell adhesion molecule are clearly distinguishable from each other in regional expression and localization, and binding patterns. These differences possibly represent diverse functions of each IgLON molecule.

Temporal and spacial changes of highly polysialylated neural cell adhesion molecule immunoreactivity in amygdala kindling development

To investigate the migration of neural stem cells as well as neural plastic changes in epileptic brain, spaciotemporal expression of immunoreactive highly polysialylated neural cell adhesion molecule (PSA– NCAM) was examined in amygdala kindling development of rat. The neural migration and synaptic remodeling detected with PSA–NCAM staining occurred in dentate gyrus of hippocampus, subventricular zone and pyriform cortex with amygdaloid kindling in generalized seizure but not in partial seizure. Although PSA–NCAM positive dendrite in dentate gyrus was minimally found in the control brain, it extended slightly in animals with partial seizure, and greatly toward the molecular layer with generalized seizure. Thus, the migration of neural stem cells as well as neural plastic changes were spacially and temporally different between brain regions depending on different kindling stages. These changes may mainly contribute to the reorganization of neural network in epileptic brain.

Localization of neural cell adhesion molecule (N-CAM) immunoreactivity in adult rat tissues

Neural cell adhesion molecule (N-CAM) mediates homophilic adhesion between cells and heterophilic adhesion between cells and extracellular matrix in a Ca2+-independent manner. N-CAM is widely expressed during development and plays a crucial role in cell division, migration, and differentiation, but its expression is restricted in adults. The distribution of N-CAM immunoreactivity in adult rat tissues was investigated in the present study. N-CAM immunoreactivity was present in the nervous system in the molecular layer of the cerebellum, ependymal cells surrounding the central canal, axons of the white matter, and in Lamina X of the gray matter of the spinal cord. N-CAM immunoreactivity also was found in autonomic nerves. In the digestive system, N-CAM immunoreactivity was found in the stratified squamous epithelium and nerve plexus of the esophagus, glandular cells of the stomach and pylorus, lamina propria, and epithelium of the villi of the duodenum, jejunum, and ileum. N-CAM immunoreactivity was demonstrated in the secretory cells of the adenohypophysis, islets of Langerhans, and acinar cells of the exocrine pancreas. Alveolar cells of the lung were also N-CAM immunoreactive. In the urinary system, N-CAM immunoreactivity was seen in the proximal convoluted tubules of the kidney. In the male reproductive system, N-CAM immunoreactivity was demonstrated in the nerve plexus around the urethral epithelium and in the nerve fibers around the smooth muscle cells of the corpus cavernosum penis. In the visual system, N-CAM immunoreactivity was seen in the epithelial cells of the corpus ciliaris. Cornea and lens epithelium also showed positive immunoreactivity. Our results suggest that cells in many tissues and organs of the adult rat synthesize N-CAM.

Localization of neural cell adhesion molecule (N-CAM) immunoreactivity in adult rat tissues

Neural cell adhesion molecule (N-CAM) mediates homophilic adhesion between cells and heterophilic adhesion between cells and extracellular matrix in a Ca2+-independent manner. N-CAM is widely expressed during development and plays a crucial role in cell division, migration, and differentiation, but its expression is restricted in adults. The distribution of N-CAM immunoreactivity in adult rat tissues was investigated in the present study. N-CAM immunoreactivity was present in the nervous system in the molecular layer of the cerebellum, ependymal cells surrounding the central canal, axons of the white matter, and in Lamina X of the gray matter of the spinal cord. N-CAM immunoreactivity also was found in autonomic nerves. In the digestive system, N-CAM immunoreactivity was found in the stratified squamous epithelium and nerve plexus of the esophagus, glandular cells of the stomach and pylorus, lamina propria, and epithelium of the villi of the duodenum, jejunum, and ileum. N-CAM immunoreactivity was demonstrated in the secretory cells of the adenohypophysis, islets of Langerhans, and acinar cells of the exocrine pancreas. Alveolar cells of the lung were also N-CAM immunoreactive. In the urinary system, N-CAM immunoreactivity was seen in the proximal convoluted tubules of the kidney. In the male reproductive system, N-CAM immunoreactivity was demonstrated in the nerve plexus around the urethral epithelium and in the nerve fibers around the smooth muscle cells of the corpus cavernosum penis. In the visual system, N-CAM immunoreactivity was seen in the epithelial cells of the corpus ciliaris. Cornea and lens epithelium also showed positive immunoreactivity. Our results suggest that cells in many tissues and organs of the adult rat synthesize N-CAM.

Polysialylated neural cell adhesion molecule is involved in the neuroplasticity induced by axonal injury in the avian ciliary ganglion.

We demonstrated previously in the quail ciliary ganglion, that the immunoreactivity for the neural cell adhesion molecule labeling the postsynaptic specializations of intraganglionic synapses decreases when synaptic remodeling is induced by crushing the postganglionic ciliary nerves. Here we show, in the same experimental conditions, that the immunolabeling for its polysialylated non-stabilizing isoform, which promotes cell plasticity, increases at these subcellular compartments. In control ganglia, poor immunolabeling for the polysialylated neural cell adhesion molecule was occasionally observed surrounding the soma of the ciliary neurons, in correspondence with the calyciform presynaptic ending and the perineuronal satellite cells sheath. At the electron microscope, several neuronal compartments, including some postsynaptic specializations, somatic spines and multivesicular bodies, were immunopositive. Three to six days after ciliary nerve crush, both the number of ciliary neurons labeled for the polysialylated neural cell adhesion molecule and the intensity of their immunolabeling increased markedly. Electron microscopy revealed that, in parallel to the injury-induced detachment of the preganglionic boutons, numerous postsynaptic specializations were found to be immunopositive. Twenty days later, when intraganglionic connections were re-established, polysialylated neural cell adhesion molecule immunoreactivity was comparable to that observed in control ganglia. The increase in immunolabeling also involved the other neuronal compartments mentioned above, the perineuronal satellite cells and the intercellular space between these and the ciliary neurons. From these results we suggest that the switch, at the postsynaptic specializations, between the neural cell adhesion molecule and its polysialylated form may be among the molecular changes occurring in axotomized neurons leading to injury-induced synaptic remodeling. Moreover, from the increase in polysialylated neural cell adhesion molecule immunolabeling, observed at the somatic spines and at the interface between neurons and perineuronal satellite cells, we suggest that this molecule may be involved not only in synaptic remodeling, but also in other more general aspects of injury-induced neuronal plasticity.

Immunocytochemical and physiological characterization of a population of cultured human neural precursors.

Human neural precursor cells (HNPC) have recently become commercially available. In an effort to determine the usefulness of these cells for in vitro studies, we have grown cultured HNPCs (cHNPCs) according to the supplier specifications. Here we report our characterization of cHNPCs under nondifferentiating and differentiating growth conditions and make a comparison to primary HNPCs (pHNPCs) obtained at the same developmental time point from a different commercial supplier. We found that under nondifferentiating conditions, cHNPCs expressed nestin, divided rapidly, expressed few markers of differentiated cells, and displayed both 4-aminopyridine (4-AP)-sensitive and delayed-rectifier type K(+) currents. No inward currents were observed. On changing to differentiating culture conditions, a majority of the cells expressed neuronal markers, did not divide, expressed inward and outward time- and voltage-dependent currents, and responded to the application of the neurotransmitters acetylcholine and glutamate. The outward current densities were indistinguishable from those in undifferentiated cells. The inward currents included TTX-sensitive and -resistant Na(+) currents, sustained Ca(2+) currents, and an inwardly rectifying K(+) current. Comparison of the properties of differentiated cells from cHNPCs with neurons obtained from primary fetal cultures (pHNPCs) revealed two major differences: the differentiated cHNPCs did not express embryonic neural cell adhesion molecule (E-NCAM) immunoreactivity but did co-express GFAP immunoreactivity. The co-expression of neuronal and glial markers was likely due to the growth of cells in serum containing medium as the pHNPCs that were never exposed to serum did express E-NCAM and did not co-express glial fibrillary acidic protein (GFAP). The relevance of these results is discussed and compared with results from other neuronal progenitor populations and cultured human neuronal cells.

Thrombolysis with tissue plasminogen activator alters adhesion molecule expression in the ischemic rat brain.

We tested the hypothesis that treatment of embolic stroke with recombinant human tissue plasminogen activator (rhtPA) alters cerebral expression of adhesion molecules. Male Wistar rats were subjected to middle cerebral artery occlusion by a single fibrin-rich clot. P-selectin, E-selectin, and intercellular adhesion molecule-1 (ICAM-1) immunoreactivity was measured at 6 or 24 hours after embolic stroke in control rats and in rats treated with rhtPA at 1 or 4 hours after stroke. To examine the therapeutic efficacy of combined rhtPA and anti-ICAM-1 antibody treatment at 4 hours after embolization, ischemic lesion volumes were measured in rats treated with rhtPA alone, rats treated with rhtPA and anti-ICAM-1 antibody, and nontreated rats. Administration of rhtPA at 1 hour after embolization resulted in a significant reduction of adhesion molecule vascular immunoreactivity after embolization in the ipsilateral hemisphere compared with corresponding control rats. However, when rhtPA was administered to rats at 4 hours after embolization, significant increases of adhesion molecule immunoreactivity in the ipsilateral hemisphere were detected. A significant increase of ICAM-1 immunoreactivity was also detected in the contralateral hemisphere at 24 hours after ischemia. A significant reduction in lesion volume was found in rats treated with the combination of rhtPA and anti-ICAM-1 antibody compared with rats treated only with rhtPA. The present study suggests that the time of initiation of thrombolytic therapy alters vascular immunoreactivity of inflammatory adhesion molecules in the ischemic brain and that therapeutic benefit can be obtained by combining rhtPA and anti-ICAM-1 antibody treatment 4 hours after stroke.

Schwann cell differentiation in Charcot-Marie-Tooth disease type 1A (CMT1A): normal number of myelinating Schwann cells in young CMT1A patients and neural cell adhesion molecule expression in onion bulbs.

Charcot-Marie-Tooth disease type 1A (CMT1A) is a common hereditary demyelinating neuropathy caused by a duplication of the gene for the myelin protein PMP22, resulting in overexpression of PMP22 in young patients. Although genetically well defined, the pathogenesis of the hereditary demyelinating neuropathy CMT1A is still unclear. Homology of PMP22 cDNA to the growth arrest-specific gene gas3 and experiments in vitro showing decreased proliferation in PMP22-overexpressing Schwann cells suggest a role of PMP22 in Schwann cell differentiation. Furthermore, overexpression of PMP22 in fibroblasts induces programmed cell death. In this report we applied morphometrical methods using electron micrographs and immunohistochemistry to further characterise Schwann cells in CMT1A nerve biopsy samples from CMT1A patients. We show that the total number of PMP22-expressing Schwann cells, i.e. Schwann cells that are in a 1:1 relationship with axons, was not reduced in sural nerve biopsy samples from six young CMT1A patients. We excluded non-specific secondary Schwann cell proliferation. Thus, in young CMT1A patients with increased PMP22 overexpression there seems to be no evidence for altered initial Schwann cell proliferation in achieving a 1:1 relationship to axons prior to the process of de- and remyelination. Further, using electron microscopy we found no evidence for apoptosis of Schwann cells in CMT1A. However, we provide additional support for an abnormal Schwann cell phenotype in CMT1A by showing the expression of neural cell adhesion molecule immunoreactivity in onion bulbs. Thus, the role of PMP22 in cell growth and differentiation does not lead to an altered number of myelinating Schwann cells but to altered Schwann cell differentiation in CMT1A.

Cingulate cortex synaptic terminal proteins and neural cell adhesion molecule in schizophrenia

The neuronal organization and patterns of afferent innervation are abnormal in the cingulate cortex in schizophrenia, and associated changes in synaptic terminals could be present. A panel of monoclonal antibodies was defined with biochemical and fusion protein studies as detecting syntaxin (antibody SP6), synaptophysin (antibody SP4) and synaptosomal-associated protein-25 (antibody SP12). These antibodies and a polyclonal antibody reactive with neural cell adhesion molecule were used to investigate the cingulate cortex in schizophrenia. Immunocytochemistry indicated that syntaxin immunoreactivity had a considerably wider distribution than synaptophysin. Overall, multivariate analysis indicated increased synaptic terminal protein immunoreactivity in schizophrenia compared to controls ( P=0.004). Controlled for age and post mortem interval, syntaxin immunoreactivity was significantly elevated in schizophrenia ( P=0.004), and neural cell adhesion molecule immunoreactivity was also elevated ( P=0.05). The neural cell adhesion molecule to synaptophysin ratio was increased ( P=0.005), possibly indicating the presence of less mature synapses in schizophrenia. Elevated syntaxin immunoreactivity is consistent with increased glutamatergic afferents to the cingulate cortex in schizophrenia, and combined with the neural cell adhesion molecule to synaptophysin ratio results suggests that synaptic function in this region in schizophrenia may be abnormal.

Regional distribution of neural cell adhesion molecule immunoreactivity in the adult rat telencephalon and diencephalon. Partial colocalization with heparan sulfate proteoglycan immunoreactivity

In the present paper immunocytochemical analysis at the fluorescence microscopical level has been performed of neural cell adhesion molecule (NCAM) immunoreactivity in the adult rat tel- and diencephalon in order to further substantiate the highly selective neuronal localization of NCAM immunoreactivity, using an affinity purified rabbit antiserum recognizing homologous NCAM proteins from rat brain. Also, double immunolabelling experiments were performed with monoclonal antibodies specific for heparan sulfate related epitopes or γ-aminobutyric acid (GABA) to establish in which cell populations a colocalization existed with immunoreactive heparan sulfate proteoglycans or GABA. Within the neocortex NCAM immunoreactivity was exclusively localized to the area of the cell membrane of soma and proximal dendrites of subsets of large pyramidal nerve cells of the layer 5 of the frontoparietal cortex. Within the dorsal hippocampus, the NCAM immunoreactivity was exclusively located to the cell surface area of the pyramidal cell bodies of area CA2. Two colour immunofluorescence procedures demonstrated a colocalization of NCAM and 3G10 but not 10E4 immunoreactivities in the cell surface area of many of the NCAM-positive nerve cell bodies of these two regions. Within the thalamus, strong NCAM immunoreactivity was exclusively demonstrated at all rostrocaudal levels of the reticular thalamic nucleus. The horizontal band of NCAM immunoreactivity was not continuous, but split up into patches of NCAM immunoreactivity within groups of nerve cell bodies. When analysing the number of cells per unitary square in the rostrocaudal direction, a significant increase of positive cells was found in the rostral and middle thirds versus the caudal third of the reticular thalamic nucleus. Many of the cell bodies with NCAM immunoreactivity in their cell surface area showed cytoplasmic GABA immunoreactivity. In the three regions shown to contain NCAM immunoreactivity, proteins of the NCAM type may play a special role for the maintenance of the synaptic structure. The findings also suggest that the sulfated proteoglycans and NCAM can interact in the regulation of cell–cell interaction via adhesion. In the reticular thalamic nucleus NCAM molecules may be part of a set of cell-adhesion molecules involved in a structural organization of the nucleus, which allows it to play a key role in relating cortical maps to thalamic maps.

Dorsal rhizotomy induces transient expression of the highly sialylated isoform of the neural cell adhesion molecule in neurons and astrocytes of the adult rat spinal cord

Expression of the weakly adhesive, highly sialylated isoform of the neural cell adhesion molecule is a feature common to cells capable of migration and conformation changes. [11, 18, 19]Polysialylated neural cell adhesion molecule also intervenes in axonal outgrowth and synaptogenesis during development and after lesion. [11, 13]High levels of polysialylated neural cell adhesion molecule immunoreactivity are normally visible in laminae I, II and X of the adult rat spinal cord. [2, 15]We show here that unilateral cervical dorsal rhizotomy induced no detectable changes in immunoreactivity in these areas. However, 24 h after lesion, polysialylated neural cell adhesion molecule immunoreactivity appeared in neurons scattered in laminae III–IX, ipsi- and contralateral to lesion. This reaction increased particularly on the contralateral side, became maximal at four days and disappeared eight days later. At this time, there was immunolabelling of astrocytes with an activated morphology. The astrocytic labelling, predominant on the side ipsilateral to the lesion, was strongest 12 days after rhizotomy, then diminished progressively. Deafferentation thus causes a transient expression of polysialylated neural cell adhesion molecule within areas of the spinal cord distinct from those which permanently express this adhesion molecule. Such expression occurs both in neurons and glial cells, with a temporal pattern specific to each type of cell.

Migration of luteinizing hormone-releasing hormone (LHRH) neurons in early human embryos.

Luteinizing hormone-releasing hormone (LHRH) neurons originate in the epithelium of the medial olfactory pit and migrate from the nose into the forebrain along nerve fibers rich in neural cell adhesion molecule (N-CAM). The present study examined the ontogenesis of LHRH neurons in early human embryos and found a similar pattern of development of these cells. Luteinizing hormone-releasing hormone immunoreactivity was detected in the epithelium of the medial olfactory pit and in cells associated with the terminal-vomeronasal nerves at 42 (but not 28-32) days of gestation. The migration route of these cells was examined with antibodies to N-CAM and antibodies to polysialic acid (PSA-N-CAM), which is present on N-CAM at certain stages of development. Neural cell adhesion molecule immunoreactivity was present in a population of cells in the olfactory placode of the earliest embryos examined (28-32 days) and later (42 and 46 days) throughout the migration route. The PSA-N-CAM immunoreactivity was not detected until 42 days and was present in a more limited distribution in nerve fibers streaming from the olfactory placode and along the caudal part of the migration route below the forebrain. Previous studies have indicated that the highly sialated form of N-CAM is less adhesive. The PSA-N-CAM may therefore facilitate the migration of these cells by lessening the adhesion between the fascicles that make up the migration route, expediting the passage of cords of LHRH cells between the nerve fibers as these cells move toward the brain.

An opioid binding protein is specifically down-regulated by chronic morphine treatment in dorsal root and trigeminal ganglia.

Despite the recent cloning of mu, delta and kappa opioid receptors, a role in opioid receptor function for an opioid binding cell adhesion molecule is supported by several lines of evidence, including inhibition of opioid binding by opioid binding cell adhesion molecule antibodies, down-regulation of opioid binding cell adhesion molecule by chronic opioid agonist treatment of cultured NG108-15 cells, and reduction of opioid binding in NG108-15 cells by transfection of opioid binding cell adhesion molecule antisense cDNA. In the present study, we report that chronic in vivo treatment of mice with morphine results in down-regulation of opioid binding cell adhesion molecule immunoreactivity in primary afferent neurons in dorsal root and trigeminal ganglia as well as their axons. This effect was blocked by the opioid antagonist naloxone. Down-regulation of opioid binding cell adhesion molecule immunoreactivity was not observed in other areas of the central nervous system. Taken together, the previous studies which demonstrated the role played by opioid receptors in regulating release of transmitters from primary afferent neurons and the present findings of a specific regulation of opioid binding cell adhesion molecule expression by chronic exposure to morphine, provides evidence from an in vivo perspective which advances the notion that opioid binding cell adhesion molecule plays a role in the action of opioids.

Neural cell adhesion molecule immunoreactivity in Merkel cells and Merkel cell tumours.

We have analysed the expression of the neural cell adhesion molecule (NCAM) in normal Merkel cells of pig and human skin, and in nine neuroendocrine carcinomas of the skin (Merkel cell carcinomas). NCAM immunoreactivity was observed in virtually all Merkel cells, both in epidermis and vibrissae of pig snout skin and in human epidermis. Immunostaining surrounded the entire surface of Merkel cells and was not restricted to the contact areas between Merkel cells and nerve terminals. All Merkel cell carcinomas studied were also positive for NCAM. The immunostaining pattern of the tumour cells was similar to that observed in normal Merkel cells; the immunoreactivity was confined to the cell membranes. These results suggest that NCAM may be used as an immunohistochemical marker for both Merkel cells and Merkel cell tumours.