Electron microscopic characteristics of neurosecretory cells in the preoptic nucleus of sturgeon fry]

In the sturgeon fry nucleus preopticus (Npo), light and weakly differentiated neurosecretory cells (NSC) as well as differentiated (i-cells) were revealed. Among these types of cells, there were the transitional forms. No "picnomorphic" cells were found in any Npo zone. NSC contained different amounts of elementary secretory granules 110-270 nm in diameter. The distribution of organelles was evaluated statistically, their number increasing from i-cells to the NSC. These data suggest that growth and differentiation of the NSC take place during this stage of ontogeny. The results are discussed in terms of specific functioning and maturity of the NSC.     

Histology, histochemistry, and ultrastructure of neurosecretory cells in the optic lobe of the cockroach, Periplaneta americana

In the region of the distal optic chiasma of each optic lobe of Periplaneta americana, there is a group of about 120 monopolar neurosecretory cells. These cells do not stain with paraldehyde fuchsin but remain acidophilic after oxidation. They stain red or sometimes indigo with the azan technique. Histochemically, the neurosecretory material is positive for protein and the amino acids tryptophan and arginine but negative for 1, 2-glycols and strongly acidic groups. At the ultrastructural level, the cytoplasm of the cells contain many elementary neurosecretory granules 100 to 170 nm in dia. The cells also contain well-developed Golgi bodies and endoplasmic retieulum. The axons from these cells run toward the interior of the optic lobe. In this region, axons containing dense granules (mean diameter 70 nm) and synaptic vesicles synapse onto the axons from the neurosecretory cells. The neurosecretory axons then cross over to the anterior side of the optic lobe and run towards the brain. The function of these neurosecretory cells is unknown, but they may be involved with photoperiodically controlled activity rhythms.     

Electronmicroscopic immunocytochemical study on the vasopressin-containing neurons of the thirsting rat

Summary Whereas in thirsting animals the perikarya of the nucleus supraopticus are nearly empty of neurosecretory granules as evidenced by electron microscopic observation, the perikarya are heavily stained by light microscopic immunohistochemical staining. In an attempt to discover the substrate responsible for the positive immunohistochemical staining in thirsting rats, the neurons of the supraoptic nucleus of normal and long-term thirsting animals were compared by electron microscopic immunocytochemistry (indirect PAP-method). In controls all parts of the vasopressin-synthesizing neuron are filled with elementary granules which render a positive and uniform reaction after immunostaining with the indirect PAP-method. The positively reacting fibers in the external zone of the median eminence contain smaller granules than those of the tractus supraoptico-hypophyseus. Within the nucleus suprachiasmaticus, no positive reaction after immunostaining was found. In long-term thirsting animals PAP-complexes as markers of vasopressin are located over the ergastoplasm and over the few small elementary granules. The processes within the nucleus supraopticus and the ballooned axons in the internal zone of the median eminence exhibit free, i.e. non granule-bound, PAP-complexes. Findings in the nucleus suprachiasmaticus and the median eminence of thirsting animals correspond to those in controls. The neurohypophysis is almost completely devoid of PAP-labeled elementary granules.From these results it can be concluded that during thirst vasopressin synthesis is increased in the ergastoplasm and that the hormone is transported partly in a non granule-bound form. Direct contacts between neurosecretory cells and the basal lamina are found more often in thirst-stressed animals and are typical of neurohemal regions. It is discussed whether these neurohemal regions may develop transitionally under stress.Supported by the Deutsche Forschungsgemeinschaft (Grant Nr. Kr 569/1) and Stiftung Volkswagenwerk. This work was presented in part at the 72nd meeting of the Anatomische Gesellschaft, Aachen 1977     

Ultrastructure of the hypothalamic neurosecretory system of the dog

Summary The hypothalamic neurosecretory system of normal dogs was studied by light and electron microscopy after perfusion-fixation. In the supraoptic nucleus most neurons are loaded with elementary neurosecretory granules having a content of low electron density. Neurons with less neurosecretory material and signs of enhanced synthetic activity, as recognized by the changes in the endoplasmic reticulum, were also observed.The vesiculated neurons ofJewell were studied under the electron microscope and various stages of development were described. It was postulated that they originate by a localized process of cytoplasmic cytolysis which ends in the formation of a large aqueous intracellular cavity limited by a plasma membrane. The possible significance of these vesiculated neurones is discussed. Some few myelinated neurosecretory axons are found in the supraoptic nucleus.The neurons of the paraventricular nucleus are smaller and contain less neurosecretory material. This is abundant and very pale in the axons. The median eminence consists of an inner zone, mainly occupied by the neurosecretory axons of the hypothalamic-neurohypophysial tracts, and an outer zone in which some neurosecretory axons end on the capillary of the portal system. This outer zone contains numerous axons with the axoplasm rich in neurofilaments and some containing granulated and non-granulated synaptic vesicles. Some neurons with granulated vesicles were observed in this region. The adrenergic nature of these neurons and axons is postulated.The infundibular process of the neurohypophysis shows small axons with discrete amounts of elementary granules and vesicles of synaptic type at the endings. Some enlarged axons having, in addition, large polymorphic bodies are observed and related to the Herring bodies.The size and morphology of the granules are analyzed along the entire hypothalamic-neurohypophysial system. The changes in diameter and electron density are related to the maturation of the granules and the possible significance of such evolution.Supported by grants from the Consejo Nacional de Investigaciones Cientificas y Técnicas and by the Air Force Office of Scientific Research (AF-AFOSR 963-66).     

Neurosecretory processes projecting from the preoptic nucleus into the third ventricle of Zoarces viviparus L.

Summary The cellular processes loaded with neurosecretory elementary granules penetrate the ependyma and project into the third ventricle at the level of preoptic nucleus of Zoarces viviparus L. These cellular processes seem to be arising from the neurosecretory cells. At this zone, not all but some of the ependymal cells have a cilium. In this paper the possible function of these neurosecretory processes and the ciliated ependymal cells are discussed.This work was aided by a Grant from NATO and the Deutsche Forschungsgemeinschaft.     

Changes in oxytocin content in the magnocellular neurons of the rat hypothalamus following water deprivation or estrogen treatment

Summary The effect of water deprivation or estrogen treatment on the oxytocin content of rat hypothalamic cells was examined using a quantitative immunohistological technique. Oxytocin-containing cells were visualized using the immunoperoxidase technique of Sternberger and a primary antiserum directed against oxytocin. The optical density of the darkest 3.2 m diameter spot in the cytoplasm of a cell was used as a measure of the oxytocin content of that cell. Water deprivation produced a significant decrease in anti-oxytocin staining in the anterior commissural nucleus of males and females. There was a similar decrease in the paraventricular nucleus of males, but not in the paraventricular nucleus of females or the supraoptic nucleus of either males or females. Estrogen treatment of ovariectomized female rats produced a fall in anti-oxytocin staining in the anterior commissural, but not paraventricular or supraoptic nuclei.     

Ecologic-histophysiological analysis of the neurohypophysis-metaadenohypophysis complex of the sazan female before and after spawning]

Much neurosecretory material (4.4 +/- 0.1 units) is seen in the neurohypophysis of sazan females before spawning. A1, A2, and B type terminals contain numerous neurosecretory granules, in particular, elementary granules. Synaptic vesicles are not numerous. The amount of neurosecretory material decreases during and shortly after spawning down to 3.6 +/- 0.3 units. Neurosecretory terminals have less elementary granules. The number of granulated, disintegrating, residual granules and synaptic vesicles somewhat increases. It is hypothesized that mainly peptide neurohormones are discharged from A1 and A2 terminals in the common circulation, and that both peptide neurohormones and monoamines reach glandular cells of the metaadenohypophysis in sazan females during and immediately spawning. The role played by neurohormones and monoamines in controlling the function of both the metaadenohypophysis glandular cells and visceral organs involved in the general adaptive reactions of the fish organism is discussed.     

Morphometric and electron microscopic studies of the secretory granules of neurosecretory cells of the supraoptic and paraventricular nuclei of white rats and mice]

The morphometrical and electron microscopic analysis of secretory granules in the perikaryons of neurosecretory cells of the supraoptic and paraventricular nuclei in male rats and mice has shown than in the cells of these nuclei in both species of animals there occur secretory granules of the same kind and size. Therefore this method fails to determine which of them contain oxytocin and which of them contain vasorpressin. The neurosecretory granules located in the Golgi apparatus zone are of a less size and have more osmiophilic cnetral material than the granules localized on the periphery which mainly have granular central material and are of a greater size. The distinctions in the size and type of secretory granules are associated with certain stages of their "maturation". Granular particles appear to be "swallen", more active forms of storing neurohormones. The presence of larger granular particles in the supraoptic nucleus of mice allows to suggest greater reactivity of this nucleus than in rats which is likely to be associated with a higher ability of mice, as compared with rats, to adaptate to disturbances in water-salt metabolism.     

An electron microscopical investigation of the follicle gland (cerebral gland) and of some neurosecretory cells in the lateral lobe of the cerebral ganglion of the pulmonate gastropod Lymnaea stagnalis L.

Summary The ultrastructure of the follicle gland and of some Gomori-positive neurosecretory cells in the lateral lobes of the cerebral ganglia of Lymnaea stagnalis is described.The follicle wall consists of epithelial cells containing secretion granules, and of processes of lateral lobe nerve cells bearing cilia, including the processes of bipolar neurosecretory B-cells. The ultrastructure of the follicle of Ancylus fluviatilis and Planorbarius corneus appeared to be very similar to that of L. stagnalis. From the ultrastructure of the follicle wall and lumen, no conclusions can be drawn as to its formerly proposed possible functions (sense organ, endocrine organ, neuroendocrine organ). Of three neurosecretory cell types (B-cells, canopy cells, droplet cells), the positivity to chrome-haematoxylin and paraldehyde-fuchsin appeared to be due to elementary granules of different size and appearance. This finding supports in a particular sense the view that results obtained with the neurosecretory stains, should be judged carefully. Also in ordinary neurons elementary granules can be found, at times in great numbers. Several types of elementary granules (at least 6) could be distinguished. Their character and function (neurohormones, neurotransmitters) are not clear.     

Ultrastructure of the peptidergic and monoaminergic neurons in the hypothalamic neurosecretory system of Anuran Batracians

Summary In the toad Bufo arenarum Hensel the following regions of the hypothalamic — neurohypophyseal system were studied under the electronmicroscope: preoptic and paraventricular nuclei, median eminence and infundibular process of the neurohypophysis.Neuronal perikarya of the preoptic nucleus are loaded with typical neurosecretory granules of peptidergic nature having a mean diameter of 1660 Å. While most neurons of the winter toad are in a storage stage a few show signs of a more active synthetic activity. A distinctive feature of preoptic neurons is the presence of large lipid droplets. The paraventricular nucleus contains small neurons containing granulated vesicles with a mean diameter of 800-1000 Å. In the region extending between these two nuclei and the median eminence axons containing either neurosecretory elementary granules or granulated vesicles are observed.The inner zone of the median eminence is occupied by axons of the preoptic neurohypophyseal tract; two types of axons, according to the size and density of the neurosecretory granules, may be recognized. The outer zone of the median eminence contains mainly axons and nerve terminals containing granulated vesicles of probable monoaminergic nature and only a few with granules of peptidergic type.The neurohypophysis contains two kinds of axons: one with more dense granules of 1800 Å and the other with granules of lesser electron density and 2100 Å. At the ending proper small clear vesicles of synaptic type are found.A progressive increase in volume of the peptidergic granules along the axon is demonstrated. This is of the order of 218% from the preoptic perikarya down to the infundibular process. The physiological significance of the two neurosecretory systems — i.e. the monoaminergic and the peptidergic — and the probable nature of the two types of peptidergic axons is discussed.Supported by grants from the Consejo Nacional de Investigaciones Científicas y Técnicas and by the Air Force Office of Scientific Research (AF-AFOSR 963-67).The authors want to express their gratitude to Mrs. Defilippi-Novoa and Mr. Alberto Sáenz for their skillful assistance.     

The effect of castration upon the ultrastructure of the rat hypothalamus

Summary The neurosecretory hypothalamic nuclei and the inner zone of the median eminence of castrated rats were studied under the electron microscope. After one month of castration all the neurosecretory neurons of both nuclei show signs of hyperactivity characterized by dilated cisternae of the endoplasmic reticulum containing a macromolecular filamentous material and an increase in the number of ribosomes. After six months of castration, some neurosecretory neurons show an increased number of neurotubules and larger lysosomes than in the controls. Other neurons show a very significant hypertrophy of the endoplasmic reticulum, with large amounts of intracisternal filamentous material. These cells have few neurosecretory granules and in the adjacent synapses the number of granulated vesicles is increased. In the supraoptic nucleus there are two kinds of neurosecretory axons: the clear ones, which are similar to those that appear in control animals and the dark ones, which have smaller elementary granules. In the inner zone of the median eminence the axons show an increase in the number of neurosecretory granules with respect to the controls. After supplementary administration of sexual hormones, all the modifications produced by castration disappear. The ultrastructural changes observed in the neurosecretory nuclei after castration are discussed in relation to those previously described in the neurohypophysis under the same experimental conditions. A feedback regulatory action of sex hormones on hypothalamic neurosecretory neurons is postulated.Supported by grants from the Consejo Nacional de Investigaciones Científicas y Técnicas and by the Air Force Office of Scientific Research (AF-AFOSR 963-67).We are deeply indebted to Mrs. Defilippi-Novoa and Mr. Alberto Saenz for their skillful assistence.     

The secretory cycle of supraoptic neurons in the rat

Summary After perfusion with formaldehyde and glutaraldehyde the supraoptic nucleus and infundibular process of the neurohypophysis of the rat were dissected and prepared for electronmicroscope observation. This study was carried out in specimens under normal water balance, in others fed on dry food and in rats submitted to forced hydration.Two extreme types of neurons with intermediary stages were recognized in the normal supraoptic nucleus. The main difference between them is in the content of ribosomes, development and dilatation of the vacuolar system and in the number of elementary neurosecretory granules. In both types lysosome-like particles are observed. The volume of the elementary granules increases 1.7 times along the hypothalamic-hypophyseal tract while the increase in the dense core of the granule is of the order of 4.3 times.After forty-eight hours on dry food there is a general depletion of secretory granules from the perikaryon and nearby axons, the ribosomes are numerous and the endoplasmic reticulum is dilated in all cells and contains a macromolecular filamentous material. With more prolonged dehydration the neurosecretory granules reappear in relation to the Golgi complex and the vacuolar system becomes progressively flattened. With forced hydration the number of granules in the perikaryon increases considerably.These observations are interpreted as indicative that the early stages of synthesis take place at the level of the ribosomes. The product, in a dilute macromolecular form, is transferred into the cisternae of the endoplasmic reticulum and then condensed into granules within the Golgi complex. The increase in size of the granules along the axon is discussed in relation to the progressive increase in hormone content.Supported by grants from the Consejo Nacional de Investigaciones Científicas y Técnicas and by the Air Force Office of Scientific Research No 963-65.Fellow of the Consejo Nacional de Investigaciones Científicas y Técnicas.     

Cytodifferentiation of the paraventricular nucleus in the chick embryo

The developmental changes in the cytoarchitecture of the hypothalamic paraventricular nucleus of the chick embryo were studied with particular emphasis on the differentiation of the magnocellular neurons. These cells can be distinguished from the parvocellular elements starting from stages 34--35 (Hamburger and Hamilton 1951) in Golgi-impregnated specimens. At the same stages, electron microscopy reveals dense-core granules, resembling the characteristic elementary granules of the neurosecretory material in the cytoplasm of the larger neurons. In addition, a few immature synapses were observed on these magnocellular perikarya. The present observations suggest that the early onset of neurosecretion in this area may be neurally regulated during early phases of development.     

Ultrastructural studies on the secretory cycle of the neurosecretory cells and the formation of herring bodies in the paraventricular nucleus of the rat

Summary The ultrastructure of the neurosecretory cells in the paraventricular nucleus of the normal male rat was studied by electron microscopy during various functional states. Four morphologically distinct types of neurosecretory cells were observed. It appears that they do not represent different classes of cells but different phases of secretory activity of a single cell type. The perikarya of the neurosecretory cells show a definite cycle of formation and transportation of secretory granules. We have designated the phases of this cycle as: (1) phase of synthesis, (2) phase of granule production, (3) phase of granule storage and (4) phase of granule transport. The neurosecretory granules appear to be moved in bulk into the axons, forming a large axonal swelling filled with granules as a result of one cycle in the neurosecretory process. Thus it may be postulated that a secretory cycle in the perikaryon of the neurosecretory cell seems to result in the formation of a Herring body in its axon, and that its content is then conveyed to the posterior pituitary.     

Morphofunctional basis of neurosecretory cell plasticity

Mass accumulation and storage of neurosecretory products are typical only for nonapeptidergic elements, as it has been shown by our study of the structure and function in neurosecretory cells of different nature. All liberinergic, statinergic and monoaminergic neurosecretory cells keep constancy in the state of high functional activity of extrusive processes at normal conditions. Morpho-functional features of these elements principally differ from those of nonapeptidergic neurosecretory cells, which are characterized by remarkable secretory cycles. The extremely large size of elementary secretory granules, maximum development of the Herring bodies, various modes of secretion, secretory and extrusive cycles in neurosecretory function, and massive accumulation of neurosecretory granules occurring in neurosecretory terminals finally, all these characters are considered to be the primary features of a high plasticity of the nonapeptidergic neurosecretory cell. A high reactivity of nonapeptidergic neurosecretory cells has been demonstrated here by the quantitative ultrastructural research of the dynamics of functional activity of neurosecretory terminals at both experimental and physiological stressful states. The highest plasticity of nonapeptidergic neurosecretory cells compared to all other neurosecretory cell types may be provided by their ability to restore the initial law level of functional activity, referred to as "functional reversion".     

Morphology of identified neurosecretory and non-neurosecretory cells in the cockroach pars intercerebralis

Electrophysiologically identified cells of the cockroach pars intercerebralis (Periplaneta americana) were injected with the dye Lucifer Yellow for morphological examination and with horseradish peroxidase for ultrastructural marking. In addition to this, uninjected cells were also studied to elaborate the findings from the injected material. The two electrophysiologically distinct classes of cells (type I and type II) correspond to two distinct morphological and ultrastructural classes. Type I cells are the medial neurosecretory cells of the pars intercerebralis, which project their axons to the retrocerebral neuro-hemal complex. Their cell bodies have a mean diameter of 17 microns, and they contain neurosecretory granules 200 nm in diameter. Arborizations emanate from the axon in the anterior part of the protocerebral neuropil. The type II cell bodies are larger (38 microns in diameter). Their axons project into the contralateral circumesophageal connective. These cells were usually multipolar, having somatic arborizations in the anterior portocerebral neuropil. The cell bodies contain vesicles 40 nm in diameter, numerous trophospongia, and a multi-layered glial envelope.     

Ultrastructure of the frontal ganglion of Chaoborus and observations on neurosecretory cells during the annual cycle

The frontal ganglion contains approximately 20 cells and rests on the two posterior elevator muscles of the roof of the pharynx, thus locating the ganglion ventral and anterior to the brain. Two frontal nerves, a pair of lateral connectives, and the single recurrent nerve connect with the ganglion. There is a centrally located neuropile which is surrounded by the perineurium which in turn is covered by the neural lamella. The perineruium contains numerous glial cells and neurons with two large neurosecretory cells located in a dorsal lateral position of the ganglion.The neurosecretory cells were examined on five occasions during the year, and no significant changes occurred in the fine structure of the organelles or cellular products. The cells appear to be engaged in the synthesis of elementary neurosecretory granules throughout the year. This observation differs from previous studies on diapausing lepidopterous larvae and pupae. Axons from these two cells enter the lateral connectives and extend toward the protocerebrum.     

The structure of the hypothalamic neurosecretory cells of Zoarces viviparus L. under the conditions of constant dark and light during the reproductive cycle

Summary The Structure of the hypothalamic neurosecretory cells during their activity in continuous light and dark conditions and depending on the seasonal alteration has been investigated in Zoarces viviparus L. in the level of light and electron microscopy.The depletion of AF- or AT-stainable material, of the elementary neurosecretory granules and the disappearance of smooth-surfaced vesicles occur during April and June. The accumulation of the stanable material as well as the elementary neurosecretory granules and the smooth-surfaced vesicles has been observed in the cell body in late September.An excess increase in number of the smooth-surfaced vesicles of dark-induced animals and light-induced animals kept in a black stained tank is apparent. On the other hand, the disappearance of the elementary granules and the smooth-surfaced vesicles and an enlargement in the reletive nuclear surface of the neurosecretory cells of light-induced animals which were kept in a gray stained tank in April is also evident.Taking into consideration the responsiveness of both the elementary neurosecretory granules and the smooth-surfaced vesicles in relation to the external environment as well as their topographical arrangement in the cell body the possible differences in their origin and function are discussed.Numerous studies indicate that the physical environment is in part responsible for the functional properties of the hypothalamic neurosecretory centers of various vertebrates. In the level of light microscope, it has been repeatedly shown that the neurosecretory cells are activated in the animals subjected to continuous illumination, and in those subjected to long daily photo period (Oksche et al., 1958; Fiske and Greep, 1959; Öztan and Gorbman, 1960; Satyanesan, 1965). The enlargement of the nuclei and the amount of Gomori — or aldehyde fuchsin — stainable material, as well as the enzymatic activity, were used as the criteria of cellular activity in the histological preparation. In the level of electronmicroscope it has been shown that Gomori positive material (Bargmann, 1949) is represented as aggregated elementary neurosecretory granules in the ultrathin sections of neurohypophysis (Bargmann et al,. 1957). Although the fine structure of the hypothalamic neurosecretory cells of various fishes and higher vertebrates have been studied in normal and experimental conditions (Palay, 1960; Lederis, 1962, 1964; Follenius et Porte, 1962; Follenius, 1963; Murakami, 1961–1964; Gansler, 1965; Holmes, 1965) the type of granules and their function still remains as an open question (see Bargmann, 1963; Knowles, 1965).This work was aided by a grant from Nato and the Deutsche Forschungsgemeinschaft.This paper was written as a tribute in honor of the 60th birthday of Prof. Dr. Berta Scharrer.     

鳗鲡繁殖生物学研究 Ⅱ.下海雌鳗脑垂体超显微构造的研究

神经垂体主要由神经分泌纤维、脑垂体细胞和微血管组成。神经分泌纤维主要是无髓鞘神经纤维,也有一些是有髓鞘神经纤维。神经垂体中还有一些多层体构造。神经分泌纤维有两个基本类型:A型纤维含有直径为1250—1750Å的神经分泌颗粒;B型纤维含有直径为450—1000Å的颗粒状囊泡。腺垂体的分泌细胞按其超显微构造的特点和所含的分泌颗粒大小不同可以区分为六个类型:催乳激素分泌细胞、促甲状腺激素分泌细胞,促肾上腺皮质激素分泌细胞、促生长激素分泌细胞、促性腺激素分泌细胞和后腺垂体的分泌细胞。       

The development of the corticoliberin- and vasopressinergic elements of the rat hypothalamus during postnatal ontogeny

In 10--81-day and adult Wistar rats, neurosecretory cells were revealed which react with antisera to corticoliberin and vasopressin. Morphometric analysis of these cells in the supraoptic, paraventricular and anterior commissural nuclei shows that in the latter vasopressinergic cells develop somewhat later than in the supraoptic and paraventricular nuclei. Complete differentiation of neurosecretory cells in all the centres investigated is observed in 2-month animals. Studies were also made on the amount of corticoliberin- and vasopressinergic terminals in the external zone of the median eminence. Vasopressin-immunoreactive fibers are more numerous in young rats than in adult ones. Corticoliberin-positive neurosecretory fibers are more abundant in adult animals. Earlier development of vasopressinergic elements corresponds to a hypothesis of a more ancient origin of nonapeptidergic structures as compared to those producing liberins and statins.