Comparative immunocytochemical localization of putative opioid ligands in the central nervous system

Summary We report a detailed comparative immunocytochemical mapping of enkephalin, CCK and ACTH/gb-endorphin immunoreactive nerves in the central nervous system of rat and guinea pig. Enkephalin immunoreactivity was detected in many groups of nerve cell bodies, fibers and terminals in the limbic system, basal ganglia, hypothalamus, thalamus, brain stem and spinal cord. -endorphin and ACTH immunoreactivity was limited to a single group of nerve cell bodies in and around the arcuate nucleus and in fibers and terminals in the midline areas of the hypothalamus, thalamus and mesencephalic periaqueductal gray with lateral extensions to the amygdaloid area. Cholecystokinin immunoreactive nerve fibers and terminals displayed a distribution similar to that of enkephalin in many regions; but striking differences were also found. An immunocytochemical doublestaining technique, which allowed simultaneous detection of two different peptides in the same tissue section, showed that enkephalin-, CCK- and ACTH/-endorphin-immunoreactive nerves although closely intermingled in many brain areas, occurred separately. The distributions of nerve terminals containing these neuropeptides showed striking overlaps and also paralleled the distribution of opiate receptors. This may suggest that enkephalin, CCK, ACTH and -endorphin may interact with each other and with opiate receptors.Index of Abbreviations CA Commissura anterior - CAI Capsula interna - CO Chiasma opticum - CPF Cortex piriformis - CSDD Commissura supraoptica dorsalis, pars dorsalis (Ganser) - CSDV Commissura supraoptica dorsalis, pars ventralis (Meynert) - FMP Fasciculus medialis prosencephali - FOR Formatio reticularis - GD Gyrus dentatus - GP Glubus pallidus - H Habenula - HI Hippocampus - S Subiculum - SGCD Substantia grisea centralis, pars dorsalis - SGCL Substantia grisea centralis, pars lateralis - SGPV Substantia grisea periventricularis - SNC Substantia nigra, zona compacta - SNL Substantia nigra, pars lateralis - ST Stria terminalis - STP Stria terminalis, pars precommissuralis - TD Tractus diagonalis (Broca) - TO Tractus opticus - TSHT Tractus septohypothalamicus - TUOP Tuberculum olfactorium, pars corticalis - SUM Decussatio supramamillaris - a Nucleus accumbens - ac Nucleus amygdaloideus centralis - aco Nucleus amygdaloideus corticalis - am Nucleus amygdaloideus medialis - ar Nucleus arcuatus - cp Nucleus caudatus putamen - dcgl Nucleus dorsalis corporis geniculati lateralis - em Eminentia mediana - fm Nucleus paraventricularis, pars magnocellularis - fp Nucleus paraventricularis, pars parvocellularis - ha Nucleus anterior (hypothalami) - hd Nucleus dorsomedialis (hypothalami) - hl Nucleus lateralis (hypothalami) - hp Nucleus posterior (hypothalami) - hpv Nucleus periventricularis (hypothalami) - hv Nucleus ventromedialis (hypothalami) - ip Nucleus interpeduncularis - mcgm Nucleus marginalis corporis geniculatic medialis - mm Nucleus mammillaris medialis - ml Nucleus mammillaris lateralis - mh Nucleus medialis habenulae - p Nucleus pretectalis - pf Nucleus parafascicularis - pom Nucleus preopticus medialis - pop Nucleus preopticus periventricularis - posc Nucleus preopticus, pars suprachiasmatica - pt Nucleus paratenialis - pvs Nucleus periventricularis stellatocellularis - re Nucleus reuniens - sc Nucleus suprachiasmaticus - sl Nucleus septi lateralis - so Nucleus supraopticus - st Nucleus interstitialis striae terminalis - tad Nucleus anterior dorsalis thalami - tam Nucleus anterior medialis thalami - tav Nucleus anterior ventralis thalami - td Nucleus tractus diagonalis (Broca) - th Nuclei thalami - tl Nucleus lateralis thalami - tlp Nucleus lateralis thalami, pars posterior - tm Nucleus medialis thalami - tml Nucleus medialis thalami, pars lateralis - tmm Nucleus medialis thalami, pars medialis - tpo Nucleus posterior thalami - tr Nucleus reticularis thalami - tv Nucleus ventralis thalami - tvd Nucleus ventralis thalami, pars dorsomedialis - tvm Nucleus ventralis medialis thalami, pars magnocellularis     

Enzymatic cleavage prior to antibody incubation as a method for neuropeptide immunocytochemistry

When deplasticized Epon sections were treated with endo- and/or exopeptidases prior to incubation with antibodies, the neuropeptide immuno-reactivity of secretory nerves was often altered in a predictable way. Cleavage of neurosecretory material in octopus nerves by trypsin and carboxypeptidase-B enhanced enkephalin-like immunoreactivity, while Molluscan neuropeptide-like immunoreactivity was prevented by tryptic cleavage. The enzyme effects indicated the occurrence of a heptapeptide (Tyr-Gly-Gly-Phe-Met/Leu-Arg-Phe) that contains both the enkephalin and the Molluscan neuropeptide sequence. Vasopressin terminals of the rat neurohypophysis, which presumably contain enkephalin precursor sequences, exhibited enkephalin-like immunostaining after tryptic cleavage. ACTH/beta-endorphin cells of the rat intermediate pituitary, which synthesize the enkephalin sequence at the N-terminus of Beta-endorphin, exhibited enkephalin=like immunoreactivity when sections were treated with alpha-chymotrypsin or trypsin, but not after incubation with leucine-aminopeptidase or carboxypeptidase-B. Enkephalin-like immunostaining could not be induced in any way in ACTH/beta-endorphin cells of the anterior pituitary. Enzymatic cleavage may give additional information in immunocytochemical localization studies on neuropeptide sequences in secretory nerves and hormonal granules.     

Immunocytochemical demonstration of proopiomelanocortin- and other opioid-related substances and a CRF-like peptide in the gut of the american cockroach, Periplaneta americana L

Using the peroxidase-antiperoxidase technique, we showed the presence of peptides which are immunologically resembling mammalian corticotropin releasing hormone (CRF)-, adrenocorticotropic hormone (ACTH)-, beta-endorphin (beta-END)-, alpha-melanocyte stimulating hormone (alpha-MSH)-, methionine-enkephalin (met-ENK)- and leucine enkephalin (leu-ENK)- like immunoreactivity in hundreds to thousands of endocrine cells and nerve fibers in the midgut of the American cockroach Periplaneta americana. In the cockroach hindgut no immunoreactive cell bodies could be observed, although nerve fibers were clearly noticed to be recognized by antisera to CRF, ACTH1-24, ACTH11-24 and beta-END. Nothing is exactly known as to the function(s) of the demonstrated materials, but one can speculate that these numerous immunoreactive cells, might have important paracrine and/or endocrine functions in the insect physiology.     

Comparison of synenkephalin and methionine enkephalin immunocytochemistry in rat brain

Immunocytochemistry using an antiserum to the C-terminal octapeptide of synenkephalin, proenkephalin(63–70), was performed throughout the rat brain and revealed numerous immunopositive fibers and some cell bodies. The morphology and distribution of synenkephalin immunoreactivity was extremely similar to that of a commercial methionine enkephalin (Met-ENK) antiserum. Colchicine pretreatment allowed the immunostaining of cell bodies not otherwise possible without pretreatment, but did not affect the distribution of immunoreactive fibers. Using 6 μm serial sections, we were able to colocalize synenkephalin and Met-ENK immunoreactivities in gigantocellular neurons of the medullary reticular formation. Preabsorption of the antiserum with [Tyr⁶³]proenkephalin(63–70) octapeptide (YEESHLLA) completely eliminated immunoreactivity in the rat brain, while preabsorption with all other peptides used had no detectable effect. We conclude that our antiserum to synenkephalin is specific for enkephalinergic cell bodies, fibers and terminals. The synenkephalin antiserum used in these studies may have advantages over other antisera utilized for immunocytochemical detection of proenkephalin gene expression.     

Nerve growth factor receptor-like immunoreactivity in primary and permanent canine tooth pulps of the cat

Summary The distribution of nerve growth factor receptor (NGF receptor)-like immunoreactivity in pulps of developing primary and mature permanent cat canine teeth was examined, by use of a monoclonal antibody against NGF receptor detected by fluorescence immunohistochemistry and pre-embedding immunocytochemical light- and electron microscopy. Both primary and permanent pulps contained a vast number of NGF receptor-like immunoreactive nerves. Immunolabelling appeared to be localized both to axons and Schwann cells. In addition, many blood vessel walls in immature primary tooth pulps showed NGF receptor-like immunoreactivity, in contrast to permanent pulps where blood vessels rarely were NGF receptor-immunoreactive. Double-labelling immunofluorescence experiments revealed that in the permanent pulp a majority of the NGF receptor-positive nerves also showed calcitonin gene-related peptide (CGRP)-like immunoreactivity, and many showed substance P-like immunoreactivity. However, nerve fibers with neuropeptide Y-like immunoreactivity lacked NGF receptor-like immunoreactivity. In developing primary tooth pulps fewer NGF receptor-positive nerves were CGRP-like immunoreactive or substance P-like immunoreactive, as compared to the permanent pulp. Neuropeptide Y-like immunoreactive nerve fibers were not detected in the primary tooth pulp. The results suggest a role for nerve growth factor in both developing and mature sensory nerves of the tooth pulp.     

Electron-microscopic cytochemistry of the catecholaminergic innervation of ACTH-containing neurons in the rat hypothalamic arcuate nucleus

The synaptic relationship between catecholamine terminals and adrenocorticotropic hormone (ACTH)-containing neurons in the arcuate nucleus (AN) of the rat hypothalamus was investigated by electron microscopy, using ACTH immunocytochemistry combined with autoradiography after 3H-dopamine (3H-DA) injection or 5-hydroxydopamine (5-OHDA) uptake in the same tissue section. ACTH-like (ACTH-LI) immunoreactive nerve cell bodies and fibers received synaptic inputs by axon terminals labeled with 3H-DA or 5-OHDA in the AN. This suggests that catecholaminergic neurons, at least DA- and 5-OHDA-containing neurons, may play an important role in the regulation of ACTH secretion or other functions of ACTH neurons via synapses in the AN of the rat hypothalamus.     

Immunohistochemical evidence of gastro-entero-pancreatic neurohormonal peptides of vertebrate type in the nervous system of the larva of a dipteran insect, the hoverfly, Eristalis aeneus

Using rabbit and guinea-pig antisera, raised against GEP neurohormonal peptides of mammalian origin, cells were observed in the brain and/or in the fused ventral ganglia of the last (fifth) larval instar of the hoverfly, Eristalis aeneus, being immunoreactive with antisera against insulin, somatostatin, glucagon, PP, secretin, gastrin/CCK/caerulein; substance P, enkephalin and endorphin. Most of these GEP neurohormonal peptides also occurred in nerve fibers. No immunoreactive cells or nerve fibers could be detected with antisera against GIP, VIP, (the central fragments of) CCK, bombesin or neurotensin. The antisera tested failed to reveal any immunoreactive cells or nerves in Weismann's ring (fused corpus allatum/corpus cardiacum and thoracic gland) or in different parts of the alimentary tract. The observations support the hypothesis that neuronal GEP hormonal peptide production in the brain is a genuinely original mechanism and the appearance of endocrine cells in the gut a later feature in evolution.     

POMC-derived peptides in the neuromuscular system of streptozotocin-diabetic mice.

Immunoreactivity for beta-endorphin and alpha-MSH/ACTH was demonstrated in intramuscular nerves in soleus, extensor digitorum longus, and diaphragm muscles of normal and streptozotocin-diabetic mice. There was a higher incidence of immunoreactive nerves in the muscles of the diabetic mice. Specific binding for [125I]ACTH was detected in a proportion of the muscle fibers, using autoradiography. There were significantly more fibers with specific [125I]beta-endorphin sites and specific [125]ACTH sites in some muscles in the diabetic mice. The increased expression of POMC-derived peptides and their receptors in the neuromuscular system of streptozotocin-diabetic mice may indicate early neuropathic change.     

P物质、脑啡肽在豚鼠耳蜗的分布——免疫组织化学观察

本研究应用免疫组织化学方法系统地观察了P物质(SP)、亮氨酸脑啡肽(L-ENK)在豚鼠耳蜗的分布以及SP、L-ENK免疫反应阳性神经纤维与Corti's器毛细胞之间的关系,结果表明:SP的免疫反应活性(SP-IR)存在于耳蜗螺旋神经节的部分神经细胞及传入神经纤维中,在Corti's器的毛细胞下方亦可见SP免疫反应阳性纤维;L-ENK的免疫反应活性(ENK-IR)存在于耳蜗的传出神经纤维中。节内螺旋束、内螺旋束、隧道螺旋束、横贯纤维均含有大量的L-ENK免疫反应阳性纤维,Cort's器中的L-ENK免疫反应阳性终末与毛细胞之间具有密切接触,由此提示,SP可能为听觉初级传入神经递质之一;L-ENK作为传出神经递质或调质对听觉传入起调控作用。     

Corticotropin-releasing hormone in the human hypothalamus. Free-floating immunostaining method

We have clearly demonstrated corticotropin-releasing hormone (CRH) immunoreactive cell bodies and nerve fibers in the human hypothalamus by immunocytochemistry using free-floating sections instead of paraffin-embedded sections. Human hypothalami were obtained at autopsy, fixed and cryostat-sectioned at 40 microns. Free-floating sections were immunostained with antibody to CRH using the Vector ABC system. Most of CRH immunoreactive nerve fibers from the paraventricular nucleus pass under the fornix, while some CRH immunoreactive nerve fibers pass beyond the fornix and some through the fornix. Then the CRH immunoreactive nerve fibers run downward, medially to the supraoptic nucleus and toward the pituitary stalk. This method of immunocytochemistry is a very sensitive and suitable means for immunocytochemical studies of neuropeptides in the human brain.     

Alpha-melanocyte-stimulating hormone (alpha-MSH) in the brain of the cartilagenous fish. Immunohistochemical localization and biochemical characterization

The distribution of immunoreactive alpha-melanocyte-stimulating hormone (alpha-MSH) in the central nervous system and pituitary of the elasmobranch fish Scyliorhinus canicula was determined by the indirect immunofluorescence and the peroxidase-antiperoxidase methods using a highly specific antiserum. Perikarya containing alpha-MSH-like immunoreactivity were localized in the dorsal portion of the posterior hypothalamus, mainly in the tuberculus posterioris and sacci vasculosus nuclei. Immunoreactive alpha-MSH cell bodies were found in the dorsal wall and ventral region of the caudal part of the tuberculum posterioris. These structures were densely innervated by fine beaded immunoreactive fibers. Some alpha-MSH immunoreactive cells were occasionally detected in the ventral part of the nucleus periventricularis. Scattered cell bodies and fibers were also observed in the dorsal wall of the posterior recess. Outside the hypothalamus very few fibers were detected in the dorsal thalamus and mesencephalon. No immunoreactivity was found in any other parts of the brain. The alpha-MSH immunoreactive material localized in the brain was characterized by combining high-performance liquid chromatography (HPLC) analysis and radioimmunological detection. Brain and pituitary extracts exhibited displacement curves which were parallel to that obtained with synthetic alpha-MSH. The concentrations of alpha-MSH immunoreactive material were determined in 5 different regions of the brain. The highest concentration was found in the hypothalamus. HPLC analysis resolved two major forms of immunoreactive alpha-MSH in the hypothalamus, which had been same retention times as des-N alpha-acetyl-alpha-MSH and its sulfoxide derivative. These results provide the first evidence for the presence of alpha-MSH-like peptides in the fish brain.(ABSTRACT TRUNCATED AT 250 WORDS)     

Glucagon-related peptides in the rat hypothalamus

Summary Immunohistochemically, nerve fibers and terminals reacting with anti-N-terminal-specific but not with anti-C-terminal-specific glucagon antiserum were observed in the following rat hypothalamic regions: paraventricular nucleus, supraoptic nucleus, anterior hypothalamus, arcuate nucleus, ventromedial hypothalamic nucleus and median eminence. Few fibers and terminals were demonstrated in the lateral hypothalamic area and dorsomedial hypothalamic nucleus. Radioimmunoassay data indicated that the concentration of gut glucagon-like immunoreactivity was higher in the ventromedial nucleus than in the lateral hypothalamic area. In food-deprived conditions, this concentration increased in both these parts. This was also verified in immunostained preparations in which a marked enhancement of gut glucagon-like immunoreactivity-containing fibers and terminals was observed in many hypothalamic regions. Several immunoreactive cell bodies were found in the ventromedial and arcuate nuclei of starved rats. Both biochemical and morphological data suggest that glucagon-related peptides may act as neurotransmitters or neuromodulators in the hypothalamus and may be involved in the central regulatory mechanism related to feeding behavior and energy metabolism.     

Effects of Chronic Striatal Kainate Lesions on Some Dopaminergic Parameters and Enkephalin Immunoreactive Neurons in the Basal Ganglia

Abstract: The chronic effects of kainate-induced lesions of the neostriatum have been evaluated in rats 12 months following the injection of kainic acid. Light microscopical analysis revealed marked disappearance of nerve cells in the neostriatum, with some cells remaining within the medial and lateral zone of the neostriatum and in the most ventral part. The rest of the markedly atrophied neostriatum was mainly made up of densely packed myelinated nerve bundles. Tyrosine hydroxylase immunoreactivity was used as a marker for dopamine neurons and revealed that tyrosine hydroxylase immunoreactive nerve terminals remained between the axon bundles in the striatum and that tyrosine hydroxylase immunoreactive nerve cell bodies in the substantia nigra seemed intact. Studies on enkephalin immunoreactive neurons revealed a marked disappearance of such nerve cells and nerve terminals within the neostriatum. Neurochemical analysis showed a clearcut reduction in the number of dopamine receptors as evaluated by studies on both [³H]spiperone binding and on [³H]ADTN binding. Dopamine levels remained unchanged while choline acetyltransferase activity was reduced significantly. Taken together, the present findings demonstrate that the chronically kainate lesioned striatum is characterized by a substantial loss of enkephalin immunoreactive and cholinergic nerve cells and a marked reduction in the number of dopamine receptors. These findings are discussed in relation to neurochemical and therapeutic aspects of Huntington's disease.     

Interaction of iodinated human [D-Ala2]beta-endorphin with opitate receptors.

The interaction of beta-endorphin with opiate receptors was studied by using the radioiodinated, metabolically stable D-Ala2 derivative of human beta-endorphin. This analog binds specifically to rat brain membrane preparations with an apparent Kd of about 2.5 x 10-9 M. The ability of various enkephalin analogs, as well as opiate agonists and antagonists, to inhibit the binding of beta-endorphin clearly demonstrates that this peptide can bind to opiate receptors. However, the effects of various cations on the binding of 125I-[D-Ala2]beta-endorphin are markedly different from those found for enkephalin binding. Sodium ion at physiological concentrations decreases substantially the binding of enkephalins but only slightly decreases endorphin binding, whereas manganese enhances enkephalin binding but has no effect on endorphin binding. Moreover, potassium (100 mM) decreases the binding of beta-endorphin but does not affect enkephalin binding. These results suggest that beta-endorphin and enkephalin bind differently to the same receptor or bind to different receptors with overlapping specificity.     

Selective Alterations of Opiate Receptor Subtypes in Mono sodium Glutamate-Treated Rats

Neonatal treatment of rats with monosodium glutamate (MSG) has been demonstrated to destroy cell bodies of neurons in the arcuate nucleus including the brain beta-endorphin (B-END) system. The effects on opiate receptors of the loss of B-END is unknown. Neonatal rats were treated with MSG as previously described. After reaching maturity (7-9 months), MSG-treated rats and litter-matched untreated control rats were decapitated and brains dissected into brain regions. Opiate receptor assays were run with [3H]morphine (mu receptor ligand) and [3H]D-alanine2-D-leucine5 (DADL) enkephalin (delta receptor ligand) for each brain region for both MSG and control rats simultaneously. Scatchard plot analyses showed a selective increase in delta receptors in the thalamus only. No corresponding change in mu receptors in the thalamus was found. The cross-competition IC50 data supported this conclusion, showing a loss in the potency of morphine in displacing [3H]DADL enkephalin in the thalamus of MSG-treated rats. This shift in delta receptors produced an IC50 displacement pattern in thalamus, ordinarily a mu-rich area, similar to that of striatum or cortex, delta-rich areas, again indicating an increase in delta receptors. Similar changes in delta receptors in other brain regions were not found. These results represent one of the few examples of a selective and localized shift in delta with no change in mu sites. Furthermore, the delta increase may reflect an up-regulation of the receptors in thalamus after chronic loss of the endogenous opioid B-END.     

Organization of neuropeptide tyrosine-like immunoreactive system in the brain of the Antarctic fish, Trematomus bernacchii

Antarctic notothenioids have developed unique freezing-resistance adaptations, including brain diversification, to survive in the subzero waters of the Southern Ocean surrounding Antarctica. In this study we have investigated the anatomical distribution of neuropeptide tyrosine (NPY)-like immunoreactive elements in the brain of the Antarctic fish Trematomus bernacchii, by using an antiserum raised against porcine NPY. Perikarya exhibiting NPY-like immunoreactivity were observed in distinct regions of the brain. The most rostral group of immunoreactive perikarya was found in the telencephalon, within the entopeduncular nucleus. In the diencephalon, three groups of NPY-like immunoreactive perikarya were found in the hypothalamus. Two groups of positive cell bodies were found in distinct populations of the preoptic nucleus, whereas the other group was found in the nucleus of the lateral recess. More caudally, NPY immunoreactivity was detected in large neurons located in the subependymal layers of the dorsal tegmentum of the mesencephalon, medially to the torus semicircularis. NPY-like immunoreactive nerve fibres were more widely distributed throughout the telencephalon to the rhombencephalon. High densities of nerve fibres and terminals were observed in several regions of the telencephalon, olfactory bulbs, hypothalamus, tectum of the mesencephalon and in the ventral tegmentum of the rhombencephalon. The distribution of NPY-like immunoreactive structures suggests that, in Trematomus, this peptide may be involved in the control of several brain functions, including olfactory activity, feeding behaviour, and somatosensory and visual information. In comparison with other neuropeptides previously described in the brain of Antarctic fish, NPY is more widely distributed. Our data also indicate the existence of differences in the brain distribution of NPY between Trematomus and other teleosts. In contrast with previous results reported in other fish, Trematomus contains positive fibres in the olfactory bulbs and immunoreactive perikarya in the nucleus of the lateral recess, whereas NPY-immunopositive cell bodies are absent in the thalamus and rhombencephalon, and no NPY immunoreactivity is present in the pituitary. These differences could be related to the Antarctic ecological diversity of notothenioids living at subzero temperatures.     

Distribution of the delta sleep-inducing peptide in the brain of rabbits: study by immunofluorescence

Using the indirect immunofluorescence method, the distribution of the Delta Sleep Inducing Peptide (DSIP)-containing neurons was studied in the rabbit brain. DSIP antisera were raised in rat by multiple injections of synthetic DSIP conjugated to thyroglobulin. Some DSIP immunoreactive cell bodies were detected in the diagonal band of Broca and anterior part of the hypothalamus. Large populations of immunofluorescent fibers and terminals were visualized mainly through the organum vasculosum of the lamina terminalis, the preoptic areas, the subfornical organ, the thalamus, the ventromedial hypothalamus and infundibulum. Further, most of the cells of the intermediate lobe of the hypophysis displayed DSIP-immunoreactivity. The predominant localization of DSIP-immunoreactive fibers and terminals in certain circumventricular organs suggests that DSIP could play a specific role in the neurohumoral regulation.     

Occurrence of bombesin-like immunoreactivity in the brain of the cartilaginous fish,Scyliorhinus canicula

Summary The presence and distribution of bombesin-like material were investigated in the brain of the cartilaginous fishScyliorhinus canicula using conventional immunocytochemical techniques. Perikarya containing bombesin-like immunoreactivity were identified in the hypothalamus, within the magnocellular component of the preoptic nucleus. Some immunopositive elements appeared to be of cerebrospinal fluid-contacting type. Beaded immunoreactive fibers were seen crossing the ventral telencephalon and the whole hypothalamus. An important tract of fibers was found in the infundibular floor and in the median eminence, in close contact with the vascular system of the pituitary portal plexus. A moderate number of positive fibers innervated the habenular complex and the dorsal wall of the posterior tuberculum. These findings indicate that a neuropeptide strictly related to amphibian bombesin is located in specific hypothalamic neurons ofS. canicula. The distribution of the immunoreactive fibers and terminals suggests that, in fish, this peptide, may be involved in neuroendocrine and neuromodulator functions.     

Immunocytochemical evidence for anti-LHRH and anti-ACTH activity in the "F" antiserum.

An antiserum which has previously been thought to be specific for LHRH-like immunoreactive material was shown to contain two populations of antibodies, one demonstrating anti-LHRH activity and the other anti-ACTH(1-24) activity. In rat and mouse, ACTH(1-24)-like immunoreactive substance is present in perikarya within the basal hypothalamus and in fibers in arcuate, periventricular and dorsomedial nuclei. LHRH-like immunoreactivity is present in fibers within the median eminence and arcuate nucleus, in a few fibers running along the ventral border of the hypothalamus, and in a small number of cell bodies within the medial basal hypothalamus.     

Distribution of atrial natriuretic factor-like immunoreactivity in the brain of the frog Rana ridibunda

The localization of atrial natriuretic factor (ANF)-like immunoreactivity in the central nervous system of the frog Rana ridibunda was examined by the indirect immunofluorescence technique, using an antiserum against synthetic ANF (Arg101-Tyr126). Immunoreactive cell bodies were principally found in the dorsal and medial pallium, the medial septal nucleus, the ventrolateral and anteroventral areas of the thalamus, the lateral forebrain bundle, the posterolateral thalamic nuclei, the preoptic nucleus, the dorsal infundibular nucleus, and the anteroventral tegmentum nucleus of the mesencephalon. Numerous cell bodies and a very dense fiber bundle were visualized in the interpeduncular nucleus. All the areas mentioned above contained a high density of immunoreactive fibers. In addition, the amygdala, the infundibular nucleus, the median eminence, and most of the areas of the mesencephalon contained a moderate number of ANF-positive nerve processes. In the frog pituitary, fibers and nerve terminals were found in the peripheral zone of the neural lobe. The intermediate and anterior lobes of the frog pituitary were totally devoid of ANF immunoreactivity. These results indicate that ANF-like material is widely distributed in the frog brain and that ANF may be involved in various brain functions including neuroendocrine regulations.