Acid-sensing ion channel 2 (ASIC2) in the intestine of adult zebrafish

Acid-sensing ion channels (ASICs) in mammals monitor acid sensing and mechanoreception. They have a widespread expression in the central and peripheral nervous system, including the gut. The distribution of ASICs in zebrafish is known only in larvae and at the mRNA level. Here we have investigated the expression and cell distribution of ASIC2 in the gut of adult zebrafish using PCR, Western blot and immunohistochemistry. ASIC2 mRNA was detected in the gut, and a protein consistent with predicted ASIC2 (64kDa molecular mass) was detected by Western blot. ASIC2 positivity was found in a subpopulation of myenteric neurons in the enteric nervous system, as well in enteroendocrine epithelial cells. These data demonstrate for the first time the occurrence of ASIC2 in the gut of adult zebrafish where it presumably acts as a chemosensor and a mechanosensor.     

Immunohistochemical localization of parvalbumin in rat and monkey autonomic ganglia

Summary The cellular distribution of parvalbumin-like immunoreactivity in autonomic ganglia such as superior cervical sympathetic ganglia, paravertebral sympathetic chain ganglia (T₆), ciliary ganglia and enteric ganglia was investigated by immunohistochemical peroxidase—antiperoxidase methods using an antiserum against rat skeletal muscle parvalbumin. We detected parvalbumin-like immunoreactivity in almost all neurons of rat superior cervical sympathetic ganglia and other paravertebral sympathetic chain ganglia, where the antigen was located in the cytoplasm but the nuclei were not labelled. No neurons positive for parvalbumin-like immunoreactivity were observed in rat ciliary ganglia or enteric ganglia. In monkey, almost all neurons of the superior cervical sympathetic ganglia contained parvalbumin-like immunoreactivity, but none of the neurons of the ciliary ganglia were labelled with the antiserum to parvalbumin. These results suggest that parvalbumin-like immunoreactivity exists in a specific subpopulation of the neurons of the autonomic nervous system.     

Artemin-like immunoreactivity in the zebrafish, Danio rerio

Artemin is a member of the glial cell line-derived neurotrophic factor (GDNF) family. It is a neurotrophic factor that supports neurite migration and outgrowth and survival of the sympathetic and sensory nervous system. Artemin has been studied in human and murine tissues, but no study has been devoted to nonmammalian species. Zebrafish is a teleost fish belonging to the family Ciprinidae, which is becoming an important model species for genetic and developmental studies. Thus, the aim of the present investigation was to evaluate, by immunochemical and immunocytochemical analyses, the tissue distribution pattern of artemin in zebrafish. Different isoforms of artemin with corresponding different molecular weights were detected in the brain, muscle, testis, ovary, kidney, gut, and gills of zebrafish by Western blot analysis. Immunocytochemical analysis showed artemin-like immunoreactivity in different cell types: in glial cells and rare neurons of the central nervous system, taste buds, retina, neuromasts of the lateral line, dorsal root ganglia, sympathetic ganglia, gill epithelium, tubular kidney epithelium, gut epithelium and ganglia, pancreas, thyroid, hypothalamus, testis, and ovary. These results indicate a wide distribution of artemin-like immunoreactivity in adult zebrafish, related to the presence of different forms of artemin. These findings might suggest a complex maturation pattern of artemin, whose forms could also exert different roles in zebrafish tissues.     

Artemin-like immunoreactivity in the zebrafish,<Emphasis Type="Italic"> Danio rerio</Emphasis>

Artemin is a member of the glial cell line-derived neurotrophic factor (GDNF) family. It is a neurotrophic factor that supports neurite migration and outgrowth and survival of the sympathetic and sensory nervous system. Artemin has been studied in human and murine tissues, but no study has been devoted to nonmammalian species. Zebrafish is a teleost fish belonging to the family Ciprinidae, which is becoming an important model species for genetic and developmental studies. Thus, the aim of the present investigation was to evaluate, by immunochemical and immunocytochemical analyses, the tissue distribution pattern of artemin in zebrafish. Different isoforms of artemin with corresponding different molecular weights were detected in the brain, muscle, testis, ovary, kidney, gut, and gills of zebrafish by Western blot analysis. Immunocytochemical analysis showed artemin-like immunoreactivity in different cell types: in glial cells and rare neurons of the central nervous system, taste buds, retina, neuromasts of the lateral line, dorsal root ganglia, sympathetic ganglia, gill epithelium, tubular kidney epithelium, gut epithelium and ganglia, pancreas, thyroid, hypothalamus, testis, and ovary. These results indicate a wide distribution of artemin-like immunoreactivity in adult zebrafish, related to the presence of different forms of artemin. These findings might suggest a complex maturation pattern of artemin, whose forms could also exert different roles in zebrafish tissues.     

Calcium binding protein calcyphosine in dog central astrocytes and ependymal cells and in peripheral neurons

Calcyphosine is a calcium binding protein discovered in the dog thyroid in 1979. Calcyphosine mRNA and immunoreactivity were detected using Western and Northern blotting in the cerebral cortex, cerebral white matter and cerebellum. Using immunohistochemistry and in situ hybridization, both are present in ependymal cells, choroid plexus cells and several types of astrocytes of the subependymal cerebral layer, the cerebellar Bergmann layer, the retinal ganglion cell layer, the optic nerve and the posterior pituitary. Both are also present in neurons of nasal olfactory mucosa, enteric Auerbach and Meissner plexuses, orthosympathic and spinal cord ganglia as well as in endocrine cells of neural crest origin in the adrenal medulla. Calcyphosine immunoreactive astrocytes were also present mainly in hemispheric cerebral gray and white matter, hemispheric subcortical structures, brain stem and spinal cord. These results show that calcyphosine is a characteristic calcium binding protein of astrocytes and ependymal cells in the central nervous system and of neurons in the peripheral nervous system. This is of interest in view of the importance of calcium regulation in these cells, and since calcyphosine a calcium binding protein phosphorylated by cAMP dependent process, may be an intermediate between cAMP and inositol phosphate cascades.     

Immunohistochemical localization of neurocalcin in human sensory neurons and mechanoreceptors

The localization of neurocalcin in the developing and adult human peripheral nervous system (dorsal root and sympathetic ganglia (DRG, SG), and enteric nervous system (ENS)) was investigated using immunohistochemistry. A subpopulation of large-sized neurons in DRG of 9 and 12 weeks old embryos showed immunoreactivity (IR), whereas the sympathetic ganglia or enteric neurons did not. In adults, neurocalcin IR was restricted to a subpopulation of large (13%) and intermediate (15%) sized neurons in DRG. The protein was also found in muscular (67%) and cutaneous (12%) nerve fibers, as well as in the axons supplying muscular (muscle spindles, Golgi's tendon organs, and perimysial Pacinian corpuscles) and cutaneous (Meissner's but not Pacinian corpuscles) mechanoreceptors, as well as motor end-plates. Present results demonstrate that neurocalcin in both developing and adult humans can be used as a specific marker for a subpopulation of sensory neurons coupled to proprioception and touch, and for axons of motoneurons forming motor end-plates.     

Developmental changes in vasoactive intestinal polypeptide immunoreactivity in the human paravertebral ganglia

Vasoactive intestinal polypeptide (VIP) belongs to the glucagon-secretin family of polypeptides and possesses numerous functions. Its existence in the mammalian central and peripheral nervous system has been widely documented. However, there are no reports on the developmental aspects of VIP-like immunoreactivity (VIP-IR) in the human postganglionic sympathetic neurons. In this study the availability and distribution of vasoactive intestinal polypeptide has been localized in human stellate ganglia neurons and nerve fibers from neonates, children and adults using the immunohistochemical method. In neonatal ganglia VIP-immunoreactive postganglionic neurons were revealed in a marked population compared to others age-groups. These nerve cells are both small and large in size and are distributed in small clusters or singly in the area of ganglia sections. In children, VIP-IR in ganglionic neurons decreases. In adult stellate ganglia, VIP-immunoreactive postganglionic neurons rarely occur. In ganglia of an individual human only varicosities of VIP-positive nerve fibers were observed. These results provide the age-dependent reduction of VIP-like immunoreactivity in human stellate ganglia neurons and suggest the different role of this peptide in the function of sympathetic ganglia neurons with age.     

Gamma interferon-like immunoreactivity in the rat nervous system

The presence of gamma interferon-like immunoreactivity in the peripheral nervous system and in some central nervous system neurons is described. The immunohistochemical evidence is based upon labeling of neurons with five different monoclonal antibodies against rat gamma interferon and one polyclonal antiserum. Immunoreactive material was abundantly present in the peripheral nervous system including small primary sensory neurons in dorsal root ganglia and postsynaptic neurons of the sympathetic and parasympathetic nervous system. Large neurons in dorsal root ganglia were not stained. Neurites stained with DB1 antibody against rat gamma interferon were found in most organs examined such as the gastrointestinal tract, heart, lungs, kidney, sexual organs and skin. In contrast, staining was weak in the central nervous system and restricted to a few neurons in the hypothalamus and in the midbrain. It is speculated that this newly discovered system containing a gamma interferon-like neuropeptide could be involved in the neuronal control of immunological processes in its target organs.     

VIP – a ’Very Important Peptide’ in the sympathetic nervous system?

Vasoactive intestinal peptide (VIP) is involved in the control of smooth muscle activity, blood flow and exo- as well as endocrine secretion. More recent work has elucidated the effects of this peptide on central and peripheral neurons. These studies suggest that VIP is an important modulator of cell growth, differentiation and neuronal survival during development of the sympathetic nervous system. VIP is also expressed in a subset of adult postganglionic sympathetic neurons. Furthermore, VIP is induced in an additional neuronal subpopulation of the rat superior cervical ganglion after axotomy. The mechanisms leading to increased VIP expression and its possible role during sympathetic nerve regeneration are currently being elucidated. This review summarizes the distribution, regulation and functions of VIP in cervical sympathetic ganglia of higher vertebrates.     

Endotoxin-induced injury of the central, autonomic and enteric nervous systems and intestinal muscularis in Thoroughbred horses

To evaluate the effects of endotoxin on the morphology of the equine central, autonomic and enteric nervous system and intestinal muscularis, six Thoroughbred horses with experimentally induced endotoxaemia were examined. The lesions in the central nervous system consisted of perivascular oedema around arterioles, suggesting brain oedema, and ring haemorrhages around veins, similar to those in human patients with septic shock. In the cranial mesenteric ganglia, neuronal cell bodies became pink or red, with shrinkage of cytoplasm indicative of ischaemic changes; intramural and perivascular infiltration by erythrocytes and neutrophils occurred around arterioles in the epineurium (acute focal interstitial inflammation). In addition, transmission electron microscopy revealed oedema of the endoneurium and mesoaxon in the nerve fascicles running inside or outside the ganglia. Myenteric neurons showed shrinkage of the cytoplasm with multiple cytoplasmic vacuoles, suggesting ischaemic changes. Oedematous degeneration and coagulation necrosis of smooth muscle cells, with dissociation of the cells, were prominent in the tunica muscularis. It is suggested that arterionecrosis elicited by endotoxin and frequently observed in the autonomic and enteric nervous system and intestinal muscularis, was the result of vasoconstriction or vasospasm.     

Nerve growth factor supply for sensory neurons: site of origin and competition with the sympathetic nervous system

Nerve growth factor (NGF) levels in the sensory nervous system were measured by a highly sensitive two-site enzyme immunoassay for NGF. Dorsal root ganglia and the adjacent spinal nerves contained 2.8 +/- 0.3 and 1.7 +/- 0.4 ng NGF/g wet wt., respectively, whereas no NGF was detectable in dorsal roots and spinal cord (less than 0.05 ng NGF/g wet wt.). It is concluded that sensory neurons are supplied with NGF exclusively from their peripheral and not from their central field of projection. Two days after treatment with 6-hydroxydopamine, which destroys sympathetic nerve terminals and thereby prevents the removal of NGF by sympathetic neurons, the NGF content of dorsal root ganglia and trigeminal ganglia increased to 285% and 161% of control, respectively. This indicates that in peripheral target tissues sensory and sympathetic neurons compete for NGF.     

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.     

Cellular and regional expression of glutamate dehydrogenase in the rat nervous system: non-radioactive in situ hybridization and comparative immunocytochemistry.

In the central nervous system glutamate dehydrogenase appears to be strongly involved in the metabolism of transmitter glutamate and plays a role in the pathogenesis of neurodegenerative disorders. In order to identify unequivocally the neural cell types expressing this enzyme, non-radioactive in situ hybridization, using a complementary RNA probe and oligonucleotide probes, was applied to sections of the rat central nervous system and, for comparison with peripheral neural cells, to cervical spinal ganglia. The results were complemented by immunocytochemical studies using a polyclonal antibody against purified glutamate dehydrodenase. Glutamate dehydrogenase messenger RNA was detectable at varying amounts in neurons and glial cells (i.e. astrocytes, oligodendrocytes, Bergmann glia, ependymal cells, epithelial cells of the plexus choroideus) throughout the central nervous system and in neurons and satellite cells of spinal ganglia. In some neuronal populations (e.g., pyramidal cells of the hippocampus, motoneurons of the spinal cord and spinal ganglia neurons) messenger RNA-labelling was higher than in other central nervous system neurons. This is remarkable because the immunostaining of neurons in the central nervous system regions studied was at best weak, whereas a predominantly high level of immunoreactivity was detected in astrocytes (and Bergmann glia). Thus, in neurons of the central nervous system, the detected levels of glutamate dehydrogenase messenger RNA and protein seem to be at variance whereas in peripheral neurons of spinal ganglia both in situ hybridization labelling and immunostaining are intense.     

Paraneoplastic anti-Purkinje and type I anti-neuronal nuclear autoantibodies bind selectively to central, peripheral, and autonomic nervous system cells

Autoantibodies provide serologic markers for subacute cerebellar degeneration in the setting of gynecologic or breast cancer (anti-Purkinje cell cytoplasmic antibodies, PCAb), and for encephalomyeloradiculoneuropathies in the setting of small cell lung carcinoma (type I anti-neuronal nuclear antibodies, ANNA-I). PCAb and ANNA-I are not species-restricted in their specificities. The subject of this report is a systematic immunocytochemical investigation of the distribution and types of cells in the mouse central and peripheral nervous system that bind these IgG autoantibodies. Sera used for the study were from two patients with prototypic PCAb reactivity and two with prototypic ANNA-I reactivity, none of whom had evidence of other autoantibodies, and from four age- and sex-matched healthy control subjects. The patients' clinical features were consistent with the classic syndromes that have been reported with PCAb and ANNA-I, respectively. PCAb bound prominently to the cytoplasm of cerebellar Purkinje cells, and also to other large cytoplasm-rich neurons throughout the central nervous system, to neurons in sensory and sympathetic ganglia and myenteric plexus, and to cells of the adrenal medulla. ANNA-I, on the other hand, bound to virtually all neurons in the central and peripheral nervous system, including sensory and autonomic ganglia, myenteric plexus and cells of the adrenal medulla. An unanticipated finding was that immunoreactivity with ANNA-I was enhanced by fixing tissues briefly with formalin. Astrocyte processes were stained by PCAb and by ANNA-I (but not by the control sera). The cytoplasm of sciatic nerve Schwann cells was stained strikingly by PCAb, but ANNA-I did not bind to Schwann cells. Although it has not yet been determined whether or not PCAb or ANNA-I per se are pathogenic, it is apparent that they represent at least a component of an immune response that is initiated by tumor antigens. The distribution of these tumor-related antigens in the nervous system is consistent with the diversity of neurologic manifestations that can occur in individual patients with the associated paraneoplastic syndromes.     

Syntaxin 1A and 1B display distinct distribution patterns in the rat peripheral nervous system

Syntaxin 1 has been shown to play an outstanding role in synaptic vesicle exocytosis. Two isoforms of this protein are expressed in neurons, syntaxin 1A and 1B. However, the physiological significance of the occurrence of such closely related isoforms is not still understood. Here, by means of isoform-specific immunocytochemistry, we show that syntaxin 1A and 1B display different patterns of expression in the rat peripheral nervous system. Nerve terminals of sensory neurons reaching the spinal cord were clearly enriched in immunoreactive syntaxin 1A. Both isoforms were detected in cell bodies of sensory neurons at the dorsal root ganglia, although specific immunolabelling displayed very different patterns at the cellular level. Motor endplates and muscle spindles were only immunostained for syntaxin 1B. Syntaxin 1A was mainly associated with nerve fibres reaching small blood vessels. In addition, nerve plexuses of the enteric nervous system showed immunostaining for both syntaxin isoforms. The different distribution pattern of the two neuronal syntaxin isoforms in the rat peripheral nervous system could be related to isoform-specific biochemical properties involved in the exocytotic process.     

Regeneration of the abdominal postganglionic sympathetic system

The abdominal sympathetic system is unique in that its postganglionic axons do not directly innervate gastrointestinal smooth muscle layers but exert their effects through the enteric nervous system. The purpose of the present study was to examine the ability of neurons in abdominal sympathetic ganglia to regenerate after axonal injury and to determine whether reinnervation occurs after the removal of ganglia. Axons from the celiac ganglion and superior mesenteric ganglion complex (CG/SMG) of adult female BALB/c mice were crushed or the ganglion complex was removed. Immunohistochemistry, western blotting and in situ hybridization were performed to examine the changes in tyrosine hydroxylase (TH) and growth-associated protein 43 (GAP-43) in the duodenum and the sympathetic ganglia. Terminal deoxynucleotidyl transferase-mediated dUTP nick end-labeling and injection of the tracer dye, fluorogold were also performed. After crushing the nerve, TH in the duodenum disappeared and reappeared within 90 days. In the CG/SMG, TH decreased and increased as in the duodenum, while the expression of GAP-43 changed in the opposite direction. Nerve crushing caused cell death to limited number of neurons in the CG/SMG. The removal of CG/SMG decreased TH in the duodenum and stomach, but 180 days later TH-positive innervation was recovered. Fluorogold injection revealed that the inferior mesenteric ganglion reinnervated the stomach. Therefore, postganglionic sympathetic nerves in the abdomen are able to regenerate and reinnervation occurs even after the removal of sympathetic ganglia.     

Gamma interferon-like immunoreactive material in rat neurons: evidence against a close relationship to gamma interferon.

Gamma interferon is a potent immunoregulatory peptide produced by activated lymphocytes. Recently, a gamma interferon-like immunoreactive molecule has been demonstrated immunohistochemically in subpopulations of rat neurons. We have now further characterized this molecule. Western blot analysis of spinal ganglia homogenates revealed a single 60,000 mol. wt band that was immunoreactive with monoclonal antibody DB1 directed against rat gamma interferon. A polyclonal antiserum and the monoclonal antibodies DB10 and DB12 failed to detect this band although all antibodies were able to label the major 18,000 mol. wt band of recombinant gamma interferon on the same blots. The 60,000 mol. wt band was selectively present in homogenates from primary sensory and sympathetic ganglia but was absent from the central nervous system and other peripheral organs, corresponding to the reported immunocytochemical distribution of gamma interferon-like immunoreactivity. The 60,000 mol. wt protein does not appear to be glycosylated. It could not be solubilized by detergents such as Triton X-100 and it co-purified with cytoskeleton-enriched preparations. At the nucleic acid level, Northern blot analysis using probes specific for rat gamma interferon mRNA failed to detect specific mRNA in rat spinal ganglia, whereas a strong 1.2 kb signal was detected in activated spleen cells. Functionally, gamma interferon-like immunoreactive material is strongly induced in superior cervical ganglion neurons after preganglionic axotomy of the sympathetic chain, but remains constant or slightly decreases in L5 spinal ganglion neurons after sciatic nerve transection. In contrast, major histocompatibility complex antigens are strongly induced on non-neuronal cells in both systems. We conclude that the neuronal gamma interferon-like immunoreactive material is clearly distinct from lymphocyte-derived gamma interferon and might not be involved in the control of major histocompatibility complex expression on glial cells.     

Genetic screen for mutations affecting development and function of the enteric nervous system.

An intact enteric nervous system is required for normal gastrointestinal tract function. Several human conditions result from decreased innervation by enteric neurons; however, the genetic basis of enteric nervous system development and function is incompletely understood. In an effort to increase our understanding of the mechanisms underlying enteric nervous system development, we screened mutagenized zebrafish for changes in the number or distribution of enteric neurons. We also established a motility assay and rescreened mutants to learn whether enteric neuron number is correlated with gastrointestinal motility in zebrafish. We describe mutations isolated in our screen that affect enteric neurons specifically, as well as mutations that affect other neural crest derivatives or have pleiotropic effects. We show a correlation between the severity of enteric neuron loss and gastrointestinal motility defects. This screen provides biological tools that serve as the basis for future mechanistic studies.