Topographische Verteilung der Monoaminfluoreszenz im Zwischenhirn-Hypophysensystem von Carduelis chloris und Anas platyrhynchos

Zusammenfassung Im Hypothalamus von Grünfink (Carduelis chloris) und Ente (Anas platyrhynchos) zeigen Neurone und Neuropilstrukturen des Nucleus infundibularis und Nucleus ventromedialis eine grüngelbe Fluoreszenz (Methode von Falck und Owman). Der sog. Basiskern des Nucleus infundibularis zeichnet sich bei beiden Vogelarten durch eine wesentlich stärkere Fluoreszenzintensität aus als die beiden gleichmäßig leuchtenden dorsalen Auflagerungen. In der Eminentia mediana von Grünfink und Ente sind in einer subependymalen Zone feine fluoreszierende Granula zu beobachten. Die Palisadenschicht weist nur einen schwach leuchtenden Saum auf; lediglich bei zwei von 65 untersuchten Grünfinken ließ sich hier ein stärkerer Fluoreszenzstreifen darstellen. Die Fluoreszenzphänomene sind in der mit Paraldehydfuchsin elektiv färbbaren Pars anterior (rostralis) der Eminentia mediana stärker als in der Pars posterior (caudalis). Vom rostralen Abschnitt der Eminentia mediana und vom Nucleus infundibularis lassen sich fluoreszierende Faserzüge bis zur lateralen Zellgruppe des Nucleus supraopticus verfolgen; der Ursprung dieser Bahn ist unbekannt. Die nicht fluoreszierenden Perikaryen des Nucleus supraopticus sind in einen stark leuchtenden Faserfilz eingebettet. Die Ergebnisse der Reserpinbehandlung und der mikrospektrographischen Bestimmung (Maximum des Emissionsspektrums bei 485 nm) sprechen dafür, daß für die Fluoreszenz der kleinzelligen Tuberkerne Monoamine (Dopamin/ Noradrenalin) verantwortlich sind. Eine fluoreszenzmikroskopische Unterscheidung von Dopamin und Noradrenalin war im Zwischenhirn-Hypophysensystem von Carduelis chloris und Anas platyrhynchos bisher nicht möglich.

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Distribution of monoamine fluorophores in the hypothalamo-hypophysial system of Carduelis chloris and Anas platyrhynchos

Summary Neurons and neuropile structures of the infundibular and ventromedial nuclei of the hypothalami of the greenfinch (Carduelis chloris) and the mallard (Anas platyrhynchos) displayed a green-yellow fluorescence with the method of Falck and Owman. The fluorescence of the basal layer of the infundibular nucleus in both of these species is significantly stronger than that of the middle and dorsal layers of this nucleus. Fine fluorescent granules can be observed in a subependymal zone in the median eminence of both species. The palisade layer shows only a weakly fluorescent margin; only in two of 65 greenfinches investigated was it possible to demonstrate here a stronger fluorescent band. The fluorescence was stronger in the anterior median eminence, which is aldehydefuchsin positive, than in the posterior median eminence. From the anterior part of the median eminence and from the infundibular nucleus, it was possible to trace fluorescent fibers to the lateral cell groups of the supraoptic nucleus; the origin of this tract is unknown. The nonfluorescent perikarya of the supraoptic nucleus lie in a meshwork of fluorescent fibers. The results of treatment with reserpine and microspectrographic analysis (maximum emission at 485 nm) suggest that the fluorescence of the tuberal nuclei is attributable to monoamines (dopamine and norepinephrine). A differentiation of dopamine and epinephrine in the hypothalamo-hypophysial system of Carduelis chloris and Anas platyrhynchos has thus far not been possible by fluorescence microscopy.

Mit Unterstützung durch die Deutsche Forschungsgemeinschaft. Herrn Prof. D. S. Farner, Seattle, danke ich für freundliche Anteilnahme am Fortgang dieser Studien.     

Localization of monoamines in the forebrain of two salmonid species,with special reference to the hypothalamo-hypophysial system

Summary In the salmon and trout aminergic cell bodies were found in the nucleus recessus lateraralis (NRL) and the nucleus recessus posterioris (NRP), both of which are situated near the third ventricle. Three cell types could be distinguished. Type 1 produces a green and type 2 a yellow fluorescence. The former type probably contains dopamine and the latter 5-hydroxytryptamine. Both types possess intraventricular protrusions in contact with the cerebrospinal fluid. The third cell type produces a less intense blue-green fluorescence; relatively few cells of this type have thick processes in contact with the ventricle. In addition, large fluorescent cells were found in the salmon, dorsal from the caudal part of the NRL. The various parts of the NRL and NRP are interconnected by thick bundles of nerve fibers; tracts leaving the nuclei could be traced for short distances only. The cells of the nucleus praeopticus (NPO), those of the medial part and to a much lesser extent also of the lateral part of the nucleus lateralis tuberis (NLT) have an aminergic innervation which probably originates from the NRL and/or NRP. All parts of the neurohypophysis contain many monoaminergic fibers, with aminergic material concentrated at the neuro-adenohypophysial interface. Fibers were not observed to penetrate the basal lamina. In the salmon and trout the fibers have a similar distribution, but differ in the intensity of fluorescence, being high in the salmon and low in the trout. Only in the trout have fluorescent cells been found in the adenohypophysis and very occasionally in the neurohypophysis. A number of these cells are basophilic and show a PAS-positive reaction.     

Neuronal localization of dopamine and 5-Hydroxytryptamine in some mollusca

Summary The localization of biogenic monoamines in ganglionic tissues from Anodonta piscinalis, Helix pomatia, and Buccinum undatum has been studied by means of the histochemical fluorescence method of Falck and Hillarp.In cerebral, visceral, and pedal ganglia (besides nonfluorescent nerve cells) neurons emitting a green or yellow fluorescence were found. No other cell systems exhibiting a specific fluorescence were observed. An abundance of monoaminergic terminals were found in the central parts of these ganglia. Spectrophotofluorimetric determinations showed that there are large quantities of dopamine and 5-hydroxytryptamine in the tissues investigated. The amounts of dopamine and 5-hydroxytryptamine agree well with the distribution of green and yellow fluorescence, respectively, in the ganglia.There are many similarities between the vertebrate and the molluscan monoaminergic neurons. The morphology of the neurons is the same, the intraneuronal distribution of the monoamines is identical, depletion experiments with reserpine and denervation experiments give the same results, and the synaptic arrangement of monoaminergic fibres on non-adrenergic neurons has the same appearance. Apparently, however, dopamine and 5-hydroxytryptamine are the only monoamines acting as neuronal transmitters in the species investigated.The research reported in this document has been sponsored by the Air Force Office of Scientific Research under Grant AF EOAR 64-5 through the European Office of Aerospace Research (OAR), United States Air Force and by the Swedish Natural Science Research Council.     

Monoaminergic mechanisms in the nervous system of Lumbricus terrestris (L.)

Summary The localization and intraneuronal distribution of the monoaminergic transmitters in the nervous system of the earthworm, Lumbricus terrestris, have been investigated in detail with the aid of the histochemical fluorescence method of Falck and Hillarp.In the ventral nerve cord, many yellow fluorescent, 5-hydroxytryptamine containing neurons are found, but only few green fluorescent noradrenaline containing cell bodies, which, however, are numerous in the peripheral nervous system. There is an abundance of both fibre types in the neuropile.The 5-hydroxytryptaminergic neurons probably have a motor (possibly inhibitor) function; the adrenergic neurons in the body segments are supposed to have a receptor (exteroceptive and possibly proprioceptive) function.In the cerebral ganglion, both 5-hydroxytryptamine and noradrenaline containing neurons are found in large numbers, and there are closely packed numerous fibres of both types in the neuropile. Their function is more obscure, though an associative function can be presumed for some adrenergic neurons; smaller 5-hydroxytryptaminergic neurons might have a motor (perhaps inhibitor) function.Adrenergic sensory cells are found in the body integument, most frequently in the clitellum segments, in the prostomium, and in the roof of the buccal cavity. These cells give off varicose fibres that form a basi-epithelial network which is in communication with the green fluorescent sensory fascicles in the ventral nerve cord via the epidermal nerves, the ring nerves, and the segmental nerves. No direct adrenergic sensory-effector innervation of either circular and/or longitudinal musculature or gland cells seems to exist. No adrenergic free nerve endings in the body integument have been observed. Instead, there must be a synaptic contact with the motoneurons, either directly in the neuropile or via an interjacent neuron.No synaptic contacts have been observed in the ventral nerve cord between adrenergic or 5-hydroxytryptaminergic fibres and either the giant fibres or fluorescent or nonfluorescent perikarya.An adrenergic innervation of the pharynx musculature has been found, and sensory cells of a different type are present in and below the epithelium; here, a direct senso-motoric innervation of the pharyngeal musculature cannot be excluded. It is established that the adrenergic neurons in the stomatogastric nervous system have an exciting function on the pharynx, whereas a direct monoaminergic influence of the muscular movements of the intestine probably does not exist.Abbreviations Used A adrenaline - CA catecholamine - DA dopamine - 5-HT 5-hydroxytryptamine - MA monoamine - NA noradrenaline The research reported in this document has been sponsored by the Air Force Office of Scientific Research under Grant AF EOAR 67-15 through the European Office of Aerospace Research (OAR), United States Air Force, by the Swedish Natural Science Research Council (99-34, 6627), and by the Swedish Medical Research Council (B67-12X-712-02A).     

Aminergic Innervation of the Cranial and Caudal Neurosecretory Systems in the Teleost Gillichthys mirabilis

Abstract Numerous fluorescent varicosities surround most of the caudal neurosecretory neurons and also regularly occur among pars intermedia cells of the adenohypophysis in the teleost, Gillichthys mirabilis. The color of the varicosities, as well as their responses to pharmacological treatments, is diagnostic of catecholaminergic neurons and processes. No fluorescence characteristic of monamines is found in the rostral pars distalis, in the proximal pars distalis or in the cells of the nucleus lateralis tuberis (NLT), although fluorescent varicosities are found within the ventral hypothalamus in the vicinity of the NLT. Bilateral clusters of fluorescent cell bodies are located in the ventral hypothalamus (posterior to the NLT); some of these cells border the neurohypophysis. Fluorescent tracts from these cell clusters extend to a pair of elongate nuclei of nonfluorescent neurons which are surrounded by fluorescent varicosities. Alteration of osmotic conditions did not effect the fluorescence, except for the caudal neurosecretory cells of fish exposed to fresh water for long periods. Adrenergic nervous input thus seems to be an important component of both the cranial and caudal neurosecretory systems.     

Aminergic cellular organization in the gills of Aplysia species

The constituent elements of the gills of Aplysia kurodai and A. juliana were examined for the presence of biogenic amines using histochemical, immunocytochemical, and HPLC techniques. Aminergic elements were revealed by glyoxylic acid-induced fluorescence in the branchial nerve, branchial ganglion, branchial vessels, and pinnules in both species. Three types of fluorescent cells were found in the neural plexus of the gill in each species. Two of them might be sensory neurons. Although HPLC analysis showed the presence of serotonin and dopamine in all gill structures including fluorescent neural elements, there were regional differences in concentrations of the monoamines. It was noted in the pinnules that there was a much higher concentration of dopamine than serotonin. Serotonin immunocytochemistry revealed neural processes which were immunoreactive to antiserotonin antibody, but serotonin immunoreactivity could not be found in a population of branchioganglionic neuron (BGN) somata. Serotonergic elements in the ganglion may be processes of the central ganglion, while dopaminergic elements may be processes of neurons in the neural plexus, located beyond the branchial ganglion. BGNs were activated by bath-applied dopamine and serotonin. These results suggest that dopaminergic sensory inputs from the neural plexus and serotonergic descending inputs from the abdominal ganglion may be among the inputs received by BGNs. It was found that serotonin depressed excitatory junctional potentials in muscle cells of the efferent branchial vessel, which were induced by an identified neuron of the abdominal ganglion. The aminergic cellular organization of the gill may involve serotonergic presynaptic-inhibitory fibers arising from the abdominal ganglion.     

Fluorescent histochemical detection of injected dopamine in lateral hypothalamus after degeneration of catecholaminergic fibres

The fluorescent histochemical technique was used to examine the presence of dopamine 1 h after injection into the lateral hypothalamus which had been depleted of catecholamines by repeated injections of 6-hydroxydopamine. There was considerably more fluorescence at the dopamine injection site which had been previously treated with 6-hydroxydopamine than at the contralateral site treated with saline. These results suggest that the destruction of catecholamine containing nerve fibres from the hypothalamus may impair the ability of brain tissue to remove amines which are produced endogenously during degeneration. This could explain why amine accumulation produced during degeneration of catecholamine-containing neurons can remain for several weeks after the parent cells, hypothesized to have produced the accumulating amine, have died.     

The distribution of monoamines in the hypothalamus of the Japanese quail Coturnix coturnix japonica

Summary The distribution of monoamines in the hypothalamus of the Japanese quail (Coturnix coturnix japonica) has been studied using a histochemical fluorescence technique. In the posterior hypothalamus catecholamine-containing nerve fibres are localised in the nucleus tuberis and nucleus hypothalamicus posterior medialis and are linked by fluorescent tracts running in the stratum cellulare internum. Further tracts may be traced from the nucleus tuberis around the base of the third ventricle to the sub-ependymal layer of the median eminence, where they then appear to pass through the hypothalamo-hypophysial neurosecretory tract to terminate in the palisade zone on the portal vascular bed. The innervation of the palisade layer by catecholamines is sparse. The fluorescent terminals are spread evenly throughout both the anterior and posterior divisions of the median eminence. There is no monoamine innervation of the pars nervosa. The paraventricular organ has both 5-hydroxytryptamine- and catecholamine-containing cell bodies and axons may be traced into the region of the nucleus hypothalamicus posterior medialis. In the anterior hypothalamus the neurosecretory paraventricular nucleus contains many catecholamine nerve fibres and terminals. These are linked by fibre tracts to the nucleus basalis and to the nucleus hypothalamicus posterior medialis. The supraoptic nucleus is less well innervated although a dense accumulation of fibres lies in the preoptic recess. The latter is thought to give rise to long axons which pass in association with the neurosecretory tract to end in the nucleus tuberis.Supported by a Grant (AG 24/36) from The Agricultural Research Council. We are indebted to Dr. G. A. Clayton, Institute of Animal Genetics, University of Edinburgh, for supplying the birds.     

Cellular localization of monoamines in the median eminence and the infundibular stem of some mammals

Summary A histochemical analysis of the monoamines which are strongly accumulated in the median eminence and the proximal part of infundibular stem of all species examined (mouse, rat, guinea pig, hamster, rabbit, and cat) was performed with the help of a highly specific and sensitive fluorescence method. Strong evidence was obtained for the view that the monoamines are localized in very high concentrations to the terminal parts of non-sympathetic nerve fibres, which — mainly at least — converge to the primary plexus of the hypophyseal portal system. The capillaries are densely and closely surrounded by the nerve fibres.Pharmacological experiments, involving the administration of reserpine, nialamide, m-tyrosine and -methyl-m-tyrosine, furnished good evidence for the view that primary catecholamines, probably mainly DA but also NA, are the predominant monoamines present. The experiments also revealed the existence of catecholamine-containing nerve cells in the arcuate nuclei and the ventral portion of the anterior periventricular nuclei. These nerve cells, situated in the regions where the tubero-infundibular tract arises, may be the cell bodies of adrenergic neurons to which the amine-containing nerve fibres at least partly belong.The findings indicate that primary catecholamines are released to the primary plexus of the hypophyseal portal system and thus transported to the anterior lobe. These amines may consequently act as neuro-humoral transmittors for the regulation of the activity of the anterior pituitary. — No direct adrenergic innervation of the cells in the pars tuberalis and anterior lobe was found. The portal vesstes in the pars tuberalis receive a very sparse adrenergic innervation and the vessels in the anterior lobe receive no or very few adrenergic nerves. Pars intermedia, on the other hand, may have a non-sympathetic adrenergic innervation.The Following Abbreviations are Used DA Dopamine - NA Noradrenaline - A Adrenaline - 5-HT 5-hydroxytryptamine For generous supplies of drugs we are indepted to Swedish Ciba, Stockholm (reserpine), and Swedish Pfizer, Stockholm (nialamide). The investigation was supported by research grants from the United States Public Health Service (NB 02854-03), the Swedish Medical Research Council, and the Therese and Johan Andersson Memorial Foundation. The excellent technical assistance of Miss M. Gustafsson is gratefully acknowledged.     

Remarkable adrenergic nerves in the exocrine pancreas

Summary The adrenergic nerves in the pancreas of mice, rats, guinea-pigs, rabbits, and cats were investigated with the fluorescence method of Falck and Hillarp. The relations between the adrenergic fibres and the vessels were studied by the injection of india ink into the vessels.Besides the normal manifestation of adrenergic fibres at the large vessels, some vessels of capillary size were also accompanied by adrenergic fibres. These fibres had a very weak fluorescence, and showed up regularly only when the animal had been treated with Nialamide and L-DOPA or dopamine to increase the catecholamine content of the adrenergic fibres. The weakness of the fluorescence is perhaps due to low transmitter concentration or to small size of the nerve fibres, or to both. A rough estimate indicated that either the transmitter concentration of the nerve fibre is at least approximately 100 times below that seen in adrenergic nerves in other tissues, or that the radius of the varicosities of the nerve fibres is less than 0.2 . Neither alternative has previously been recognized.The secretory acini of the pancreas seem to lack a direct adrenergic supply. In the intrapancreatic ganglia, non-fluorescent nerve cells were reached by adrenergic terminals. No adrenergic nerve cells were detected in the pancreas of rats and cats. Small intensely fluorescent catecholamine-containing cells were observed in connexion with the intrapancreatic ganglia of rats.The research reported in this document has been sponsored by the Air Force Office of Scientific Research under grant AF EOAR 67-15 through the European Office of Aerospace Research (OAR), United States Air Force, by the United States Public Health Service (grant NB 06701-01) by the Swedish Medical Research Council (project B 67-12X-712-02A), and by the Faculty of Medicine, University of Lund, Sweden.     

Microspectrographic analysis of formaldehyde-induced fluorescence in the quail adenohypophysis after injection of l-dopa and 5-hydroxytryptophan

Summary The spectral distribution of the formaldehyde-induced fluorescence emitted by model solutions and by adenohypophyses after intraperitoneal injection of l-dopa or 5-hydroxytryptophan was analyzed microspectrographically. Based on previously reported studies and on present findings, it seems that dopamine is stored in the strongly fluorescent cells after injection of l-dopa, and that a compound closely related to 5-hydroxytryptophan or serotonin is present in most of the cells after injection of 5-hydroxytryptophan. A non-specific, granular fluorescence appeared after 5-hydroxytryptophan and, to a lesser extend, l-dopa treatment. It probably represents autofluorescence of lysosomes, which are numerous in these circumstances.     

Histochemical studies on catecholaminergic cells in the carp retina

Histochemical studies on catecholaminergic cells were conducted with the carp (Cyprinus carpio) retina. Catecholamine (CA)-containing cell bodies appear sparsely distributed among amacrine cells in the innermost cellular row of the inner nuclear layer (INL) and occasionally in the outer half part of the inner plexiform layer (IPL); only exceptionally are they found among ganglion cells. The fluorescent cells interspersed with the amacrine cells and in the IPL send their fiber processes toward both the outer plexiform layer (OPL) and the IPL; the fine fibers form dense networks in the INL and IPL. Pretreatment of the fish with intramuscular injection of reserpine (20 hr prior to enucleation) completely depleted CA from the retina. The fluorescence of catecholaminergic cells was enhanced, and the number of fluorescent cells visible was increased, by intravitreous injection ofl-DOPA, DA, and NA (3 hr prior to enucleation). A combination of pretreatment with intramuscular reserpine and intravitreous NA was particularly effective. These results indicate that catecholamines may play an important role in the modulation of the membrane potential of horizontal cells.     

Distribution of monoamines in the diencephalon and pituitary of the dogfish,Scyliorhinus canicula L.

Summary The distribution of monoamines in the diencephalon and pituitary of the dogfish, Scyliorhinus canicula, has been investigated using the histochemical fluorescence technique of Falck and Hillarp (Falck and Owman, 1965). Terminals of monoamine-containing axons were found in the neurointermediate lobe of the pituitary and the axons were traced, by means of nialamide and L-dopa treatment and lesions, to the nucleus medius hypothalamicus. A separate hypothalamic system converging on the anterior median eminence and the occurrence of aminergic cells in the nuclei lobi inferiores and nucleus medius hypothalamicus were similarly demonstrated. Normal fish show a bilateral uncrossed tegmental tract and two areas of catecholamine-containing neurones in modified ependymal organs. The organum vasculosum hypothalami includes both primary catecholamine and 5-hydroxytryptamine-containing cell types whilst the organum vasculosum praeopticum has only the former type. Both organs contain cells which send club-like processes into the third ventricle. The subcommissural organ does not contain monoamines.The role of hypothalamic catecholamine systems in the regulation of pituitary function is discussed.     

Adrenergic and cholinesterase-containing neurons of the heart

Summary The adrenergic and acetylcholinesterase-containing nerves of the hearts of mice, rats, guinea-pigs, rabbits, and cats were studied. The fluorescence technique of Falck and Hillarp was used for the demonstration of adrenergic nerves, whereas a modified Koelle cholinesterase technique was used for the cholinesterase-containing nerves. The inhibitors used were Mipafox, iso-OMPA and Nu 683. Microspectrofluorometry was used to identify the structures containing dopamine.Adrenergic as well as acetylcholinesterase-containing fibres were found in all parts of the heart, most abundantly in the atria. Dense nerve plexa supplied the sinoarial and atrioventricular nodes. There was a plexus of both fibre types in the endocardium and on the atrial side of the valves. In the valves, it could be shown that adrenergic and cholinesterase-containing fibres ran closely parallel to each other. Indirect evidence suggested that this applies also to the myocardium.No nerve fibres containing dopamine were revealed in the microspectrofluorometer. The dopamine previously found in the atria seems, instead, to be situated in so-called small intensely fluorescent cells.No adrenergic ganglion cells were found in the heart despite extensive search. The vagus of rabbits was found to contain only few adrenergic preterminals.     

Fluorescence microscopy of the 5-HTP turnover in the exocrine pancreas of mice and rats

Summary The turnover ofl-5-HTP,d-5-HTP and 5-HT in the exocrine pancreas have been studied by means of the fluorescence method ofFalck andHillarp. l- andd-5-HTP are easily taken up by the acinar cells, whereas 5-HT seems to pass into the cells only to a minor extent. After the administration ofl-5-HTP (and in some cases after 5-HT administration), specific fluorescence is seen in the form of apically located granules (probably identical with the zymogen granules) for a short period, which is prolonged, if the animals are pretreated with a MAO inhibitor. Decarboxylase inhibition prevents the appearance of these fluorescent granules. Administration ofd-5-HTP does not give rise to this granular fluorescence but to a diffuse fluorescence throughout the cells. Thus, there are reasons to assume that the granular fluorescence derives from 5-HT. The results obtained in this work correspond well with those from a similar study withl-DOPA and some of its analogues.abbreviations DOPA 3,4-dihydroxyphenylalanine - DA dopamine - NA noradrenaline - A adrenaline - 5-HTP 5-hydroxytryptophan - 5-HT 5-hydroxytryptamine - MAO monoamine oxidase This work was supported by grants from the Swedish Medical Research Council (B68-12X-712-03B and B68-14X-56-04B), the United States Public Health Service (06701-02) and the Faculty of Medicine, University of Lund, Lund, Sweden.     

<Emphasis Type="SmallCaps">l</Emphasis>-Aspartate-immunoreactive neurons in the rat enteric nervous system

l-Aspartate (l-Asp) is an excitatory neurotransmitter in the central nervous system. In the present study, we demonstrate, for the first time, the presence of l-Asp in a particular neuronal cell class in the enteric nervous system (ENS). Scattered l-Asp-immunoreactive neuronal cell bodies and nerve fibers were found extensively in both the myenteric and submucosal plexus throughout the small and large intestines. Many l-Asp-immunoreactive nerve fibers, which originated from intrinsic nerve cell bodies, were found in the ganglia and interconnecting nerve bundles. Electron microscopy revealed that l-Asp-immunoreactive terminals frequently formed synaptic contacts with intrinsic nerve cells, suggesting that some l-Asp-immunoreactive neurons might function as interneurons. These results suggest that l-Asp-immunoreactive neurons play a significant role within the ENS to control intestinal functions. The presence of enteric l-Asp-immunoreactive neurons provides strong support for the proposal that l-Asp is a neuromodulator in the rat ENS.     

Demonstration of the tuberoinfundibular tract of the cat

Summary The distribution of dopaminergic nerve cells in the cat hypothalamus, particularly in the arcuate and periventricular nuclei, and the projections of their axons were studied by fluorescence and electron microscopy after electrothermic coagulation. The majority of these perikarya were located in the arcuate nucleus and the periventricular nucleus dorsocaudal to the optic chiasma. Large lesions caused a wide and diffuse depletion of dopamine fluorescence within the external layer; small lesions caused ipsilateral partial depletion of the dopamine fluorescence. Electron microscopic observations in animals with a lesioned arcuate nucleus revealed that in the external layer degenerating nerve terminals are engulfed by glial processes. In some cases nerve fibers had entirely disappeared and a heavy reactive proliferation of glial processes was observed. Persistence of the form of the median eminence in spite of the extensive degeneration of its nervous elements is considered to depend upon this glial proliferation.Dedicated to Professor W. Bargmann in honour of his 70th birthday     

Fluorescence microscopic observations of catecholamines in cultures of the sympathetic chains

Summary A histochemical technique for the demonstration of catecholamines developed by Falck et al. has been successfully applied to the sympathetic chains of rats and mice maintained in vitro. Catecholamines were localized in the nerve fibers, showing identical green fluorescence as in tissue sections of healthy rats. The cultures 8 days in vitro exhibited positive reaction in a few terminals, whereas sister cultures 1 month in vitro showed strong fluorescence reaction in thicker proximal axons and networks of nerve fibers as well. Reactivity of neuron somas became positive after 1 month of cultivation. Application of reserpine in amount of 0.00025 mg/ml for 2 hours resulted in complete disappearance of fluorescence. Furthermore, cultures of spinal ganglia from fetal rat produced no fluorescence reaction with this technique. Therefore, the reaction is specific for sympathetic nervous tissue and reliable for the differentiation of sympathetic neurons from other types of nerve cells.This work was supported by research grant NBO 3173 from the National Institute of Neurological Diseases and Blindness, U.S. Public Health Service, and research grant No. 355 from the National Multiple Sclerosis Society, New York.     

Immunocytochemical study of the hypothalamic magnocellular neurosecretory nuclei of the snake Natrix maura and the turtle Mauremys caspica

Summary An immunocytochemical study of the magnocellular neurosecretory nuclei was performed in the snake Natrix maura and the turtle Mauremys caspica by use of antisera against: (1) a mixture of both bovine neurophysins, (2) bovine oxytocin-neurophysin, (3) arginine vasotocin, and (4) mesotocin. Arginine vasotocin- and mesotocin-immunoreactivities were localized in individual neurons of the supraoptic and paraventricular nuclei, with a distinct pattern of distribution in both species. The same cells appeared to be stained by the anti-oxytocin-neurophysin and anti-mesotocin sera. The supraoptic nucleus can be subdivided into rostral medial and caudal portions. In N. maura, but not in M. caspica, neurophysin-immunoreactive neurons were found in the retrochiasmatic nucleus. No immunoreactive elements were seen in the suprachiasmatic nucleus of both species after the use of any of the antisera. A dorsolateral aggregation of neurophysin-containing cells, localized over the lateral forebrain bundle, was present in both species. Magnocellular and parvocellular neurophysin-immunoreactive neurons were present in the paraventricular nucleus of both species. In the turtle, the paraventricular neurons were arranged into four distinct layers parallel to the ependyma; these neurons were bipolar with the major axis perpendicular to the ventricle, and many of them projected processes toward the cerebrospinal-fluid compartment. In N. maura a group of large neurons of the paraventricular nucleus was found in a very lateral position. The posterior lobe of the hypophysis and the external zone of the median eminence contained arginine vasotocin- and mesotocin-immunoreactive nerve fibers. The lamina terminalis of both species was supplied with a dense bundle of fibers containing immunoreactive neurophysin. Neurophysin-immunore-active fibers were also present in the septum, some telencephalic regions, including the cortex and the olfactory tubercule, in the paraventricular organ, and the periventricular and periaqueductal gray of the brainstem.This work was partially supported by a Grant S-85-39 from the Direccion de Investigaciones, Universidad Austral de Chile to E.M. Rodriguez     

Distribution of biogenic amines in the slug,Limax maximus

Summary The distribution of monoamines inLimax maximus was studied by the histochemical fluorescent method of Falck and Hillarp. The number of 5-HT-containing and catecholamine-containing perikarya in the central nervous system is small compared with the non-fluorescent perikarya. However, all the ganglia except the proto-cerebral ganglia have some amine-containing neurons. There are relatively larger numbers of fluorescent cells in the cerebral, visceral, pedal and right parietal ganglia than in the other ganglia. A single, giant 5-HT-containing neuron was observed in each meta-cerebral ganglion.Monoamine neurons are localised in a number of peripheral tissues (heart, integument, tentacles, penis retractor muscle, sole of foot, kidney, alimentary canal, reproductive organs and tentacular, pharyngeal and cephalic retractor muscles). Neurons containing catecholamine are mostly associated with sensory structures such as the statocysts, the retina of the eye and the integument of the tentacles, whereas 5-HT-containing nerve fibres are mainly observed in muscle tissues.We wish to thank the Wellcome Trust for financial support.