The cytoskeletal lattice of the neurohypophysial cells

The cytoskeleton of rat neurohypophysial cells as seen in resinless sections is an irregular three-dimensional lattice of short strands of cytoplasmic matrix (the microtrabeculae) that interconnect parallel arrays of neurotubules, neurofilaments, abundant neurosecretory granules, and other membrane-bound organelles including the plasma membrane. This morphological finding suggests that the cytoplasmic ground substance constitutes a cytoskeletal continuum that may be the ultrastructural expression of a motile apparatus responsible for neurosecretory granule movement and hormone release in the neurohypophysis.     

Interactions of the ring gland, overies, and juvenile hormone with brain neurosecretory cells in Musca domestica.

The staining intensity (median neurosecretory cell index) of the median neurosecretory cells (MNC) in Musca domestica increased as oögenesis progressed from stages 2 to 10. The amount of neurosecretory material within the MNC was dependent upon the presence of ovaries with developing or mature follicles. Ovariectomized flies had a median neurosecretory index that was 50 per cent less than that of control flies with mature eggs. In addition, we found that ring gland removal decreased the staining frequency of three different neurosecretory cell groups; increased staining frequency in another; increased the amount of neurosecretory material within the MNC fibre tract; increased the cytoplasmic area of types A and A′ MNC. Furthermore, neither the juvenile hormone analogue nor the ring gland had a direct effect on the median neurosecretory cell index but did influence neurosecretory activity indirectly by activating the ovaries. We hypothesize that an ovarian hormone—the oöstatic hormone—regulates either the release from or synthesis of neurosecretory material within the MNC.     

Histochemical observations on the giant neurosecretory cells of the thoracic ganglion of the adult and juvenile crabs, Potamon magnum magnum (Pretzman).

The giant neurosecretory cells in the thoracic ganglion of the adult and juvenile crab, Potamon magnum magnum (Pretzman) were histochemically investigated. The secretion is mainly proteinaceous in nature, containing considerable amounts of acid mucosubstances, sulphate esters, lipids and a little carbohydrate but no glycogen. The detailed nature of proteinaceous neurosecretory material in the adult crab was further tested. It appears that the neurosecretory material of these cells contains moderate amounts of sulfhydryl groups and few of disulphide bonds. No trace of tyrosine could be observed. The neurosecretory granules were associated with considerable amounts of cytoplasmic RNA. In general, stronger reactions were obtained in summer and winter than in other seasons.     

Histochemistry of neurosecretory cells in the cerebral ganglion of the adult or juvenile sweet water crab, Potamon magnum magnum (Pretzman)]

The histochemistry of the neurosecretory material of the PF-positive neurosecretory cells of the cerebral ganglion of the adult and juvenile crab, Potamon magnum magnum (Pretzman) has been investigated. The PF-positive neurosecretory material is proteinaceous and contains considerable amounts of cystine; it is associated with significant amount of cytoplasmic RNA, lipids and phospholipids and with moderate amounts of carbohydrates, though no glycogen could be detected. The significance of these results is discussed.     

An electron microscopic study of the corpus cardiacum of adult Drosophila melanogaster and its afferent nerves

The left and right afferent nerves to the corpus cardiacum contain approximately 50 and 90 axons, respectively, when they enter the gland. Both bifurcate within the gland, so that four nerves leave the corpus cardiacum. These, however, contain a total of 90 axons. Of the 50 axons unaccounted for 30 are believed to terminate in the corpus cardiacum and 20 in the corpus allatum. The corpus cardiacum contains 12 intrinsic neurosecretory cells which are disposed laterally with respect to the extrinsic axons. Many of these contain neurosecretory spheres and presumably originate in the brain. The intrinsic corpus cardiacum cells also contain neurosecretory granules, and they produce short cytoplasmic processes which interdigitate with the extrinsic axons.     

Brain hormone carrier haemocytes in the moth Monema flavescens

The movement of neurosecretory substances released from the neurosecretory B cell in the pars intercerebralis to the haemolymph was examined with the progress of the termination of diapause in the slug moth pharate pupa, Monema flavescens.The injection of precipitates in the haemolymph of the pharate pupa just before the termination of diapause into diapausing pharate pupae reduced the numbers of days required for them to pupate. In the precipitates, seven types of haemocytes were present. The number of haemocytes, especially the granular cell, increased just before the termination of diapause. AF and CHP positive substances not detected in the haemocytes of diapausing pharate pupae appeared in the granular cells just before the termination of diapause. The period also coincided well with the releasing period of the neurosecretory B cell. Histological examination showed that granular haemocytes gathered around the pars intercerebralis at this period and exchange of neurosecretory substances occurred between granular haemocytes and neurosecretory B cells. Then granular haemocytes migrated to the region of the prothoracic gland. From digestion tests of the neurosecretory substances with rabbit serum and from the implantation tests of the neuroendocrine system, the substances detected in both the neurosecretory B cell and the granular haemocytes seemed to be the same. The dye injection caused a delay in larval-pupal ecdysis emergence. Droplets of black ink are incorporated into the granular haemocytes. This seems to be caused by blocking of the transport of neurosecretory substances released from cytoplasmic processes of the neurosecretory B cell.From these experiments, it is suggested that neurosecretory substances of the prothoracotropic hormone are transported to the prothoracic gland, along with granular haemocytes, after being released directly from the neurosecretory B cell to the haemolymph.     

Cytochemistry of the neurosecretory cells in the crab Menippe rumphii (Fabricius, Crustacea: Brachyura)

In Menippe rumphii five types of neurosecretory cells are found in the cerebral, commissural and thoracic ganglia. Detailed cytochemical observations on the neurosecretory cells revealed that they have responded strongly to saliva resistant PAS staining. Among proteins those rich in disulfides and sulhydryl groups are observed. Greater amounts of cytoplasmic RNA are observed in the reproductive season. Considerable amounts of lipids and phospholipids are also observed in the AS cells. The cytochemical differences between the NS cells and the nonsecretory neurons are also discussed.     

Dynamics, following axotomy, of the A1 and A2 median protocerebral neurosecretory cells of the African locust. II. Ultrastructural study

In the African locust after axotomy of the A1 and A2 median protocerebral neurosecretory cells (M-NSC), the decrease of the basophil neurosecretory products into the pericaryons does not result from an increase of the granulolysis but results from an inhibition of the production. The A1 and A2 neurosecretory products, stored anteriorly and posteriorly to the site of the axonal section, seem destroyed by: 1. a suspected entrance of lytic enzymes into the granule (individual granulolysis); 2. a vacuolar inclusion of small or big cytoplasmic areas rich in granules (partial or total collective granulolysis). The axons of the M-NSC, regenerated without reconnexion to the corpora cardiaca (CC), are not separated by glial elements. This glial deficiency could be at the origin of the inhibition of the neurosecretory dynamics observed in the A1 and A2 M-NSC after axotomy and regeneration without reconnexion to the CC.     

Requirements for the identification of dense-core granules

Dense-core granules (DCGs), cytoplasmic organelles competent for regulated exocytosis, show considerable heterogeneity depending upon the specificity of their expressing cells--primarily neurons and neurosecretory cells. DCGs have been mainly identified by detecting their cargo molecules, often members of the granin family, and using conventional electron microscopy and immunocytochemistry. However, by a critical analysis of the various stages of DCG "life" within neurosecretory cells, we have highlighted several specific molecular and functional properties that are common to all these organelles. We propose that these properties be considered as strict requirements for the identification of DCGs.     

Ontogenetic Development of the Caudal Neurosecretory System in the Chum Salmon, Oncorhynchus keta, with Regard to Its Ultrastructural Changes and with Relation to Neuropeptide Y-immunoreactive Fibers

The ontogeny of the caudal neurosecretory cells (Dahlgren cells) in the caudal spinal cord of the chum salmon, Oncorhynchus keta, was examined by conventional electron microscopy and with immunohistochemistry for urotensins (U) and neuropeptide Y (NPY). The precursors of the Dahlgren cells first appeared as agranular ovoid cells in the caudal region of the neural tube of 40-day-old embryos about one week before hatching. The occurrence of cytoplasmic granules in the immature Dahlgren cells became evident by the 14th day after hatching. At this moment, the U-positive reaction was merely demonstrated in some of the granules. Close association of NPY-positive fibers with the caudal neurosecretory structures was recognizable in 1-month-old larvae. Thus, it is apparent that the salmon Dahlgren cells start their secretory activity (production of the secretory granules) in early larval stages and that, thereafter, NPYergic afferent innervation of the caudal neurosecretory system becomes evident.     

A possible neuroendocrine system in polynoid polychaetes

Within the supraesophageal ganglion of polynoids is a vertical fiber tract which has the appearance of a “Y” in transverse sections of the brain, and contains the axons of many neurosecretory cells. The granule-filled terminals of these neurosecretory fibers are found at the base of the tract where they are in contact with the inner surface of the sheath covering the ventral surface of the brain. This sheath separates these neurosecretory endings from an underlying pericapsular epithelium which is thicker in this region. Beneath this pericapsular epithelium is a coelomic sinus. The dorsal blood vessel is located within this sinus and is “innervated” by a pair of fiber bundles that pass out of the brain at the base of the vertical fiber tract. The outer surface of the vessel is covered by epithelioid cells which contact these fiber bundles and the thickened pericapsular epithelium, and sometimes contain granular cytoplasmic inclusions. The lumen of the vessel is continuous with the lumina of a pair of cellular, thickwalled structures of unknown function which are attached to the ventro-lateral margins of the brain. The relationship between neurosecretory endings, enlarged pericapsular cells, coelomic sinus and blood vessel provides morphological evidence for the hypothesis that these structures are elements of a neuroendocrine system, similar in some respects to the brain-infracerebral gland complex of nereid and nephtyid polychaetes.     

Ultrastructure of neurosecretory cells in the pars intercerebralis of Rhodnius prolixus (Hemiptera).

Six neuron types are distinguished in the pars intercerebralis of the starved fifth instar of Rhodnius prolixus. All neuron types contain electron dense secretory granules derived from Golgi complexes which are of characteristic size and morphology in each type. The neuron types are not thought to represent stages in a secretory cycle. The variety of neuron types described is related to that revealed by staining sections of the same cells with paraldehyde fuchsin. Active synthesis of neurosecretory granules continues throughout starvation and the lysosomal system appears to be involved in the continual degradation of secretory granules. Some of the variations in granule morphology observed may be a consequence of granule fusion and the importance of cytoplasmic events in the development of neurosecretory granules is discussed.     

Light and electron microscopic studies on the neurosecretory control of diapause incidence in Pieris rapae crucivora

The incidence of diapause was shown to be determined humorally during the larval-pupal ecdysis by means of brain extirpation experiments.On the basis of this observation, light and electron microscopic changes in the neurosecretory type II cells in the pars intercerebralis-corpus cardiacum system during pharate pupal and early pupal stages were examined in insects reared under long day-length (non-diapause individuals) and in insects reared under short day-length (diapause individuals). In the diapause individuals, neurosecretory granules in NS-II cells increased during the pupal instar and large aggregates of granules packed the cytoplasm. Thereafter, inclusion bodies showing cytoplasmic breakdown of the granules appeared.In the non-diapause individuals, on the contrary, electron micrographs suggesting the release of neurosecretory material from axon terminals were obtained just after the pupal ecdysis. There were very few granules, with many Golgi bodies and much rough ER 8 to 12 hr after the ecdysis.It is concluded that adult development is determined by the release of neurosecretory material from the axon terminals of NS-II cells at the larval-pupal ecdysis. If release does not occur, the pupae enter diapause. It is also thought that differences in day-length during the larval stages influence the activities of NS-II cells before pupation.     

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).     

Effect of noradrenaline,dopamine and adrenolytics on growth and maturation of the sea urchin,Strongylocentrotus nudus Agassiz

Both noradrenaline and dopamine inhibit growth and maturation of oocytes in sea urchins. The in vitro action of these drugs on gonads was accompanied by a decrease in intensity of incorporation of labelled RNA and protein precursors into oocytes in their cytoplasmic growth. The monoaminergic system appears to participate in the regulation of oogenesis in sea urchins besides the peptidergic neurosecretory system.     

The Cerebral Neurosecretory System,Secretory End-Foot System and Infracerebral Gland—a Probable Neuroendocrine Complex in Nephtys (Annelida; Polychaeta)

Abstract The brain of Nephtys contains four neurosecretory cell types with distinctive cytoplasmic inclusions, a cells are located uniquely in a single pair of ganglionic nuclei and b cells are represented by a single pair of cells, whereas c cells and d cells have a scattered distribution. Their axons form two types of secretory release structure. First, possible axon collaterals synapse upon slender “dentritic twigs” in the core of the brain. Secondly, two tracts descend to the brain floor to form a “neurosecretory neuropile” (or storage and release complex) in contact with the inner surface of the brain capsule. Other neurosecretory fibres penetrate through the capsule, branch extensively, and terminate in contact with its ventral surface in close association with the “infracerebral gland”. The gland is derived from the pericapsular epithelium and exhibits signs of specialization for glandular function. In contrast to certain other polychaetes, it does not contain secretory neuron perikarya. The secretory end-foot system is poorly developed. Its terminals are located adjacent to the neurosecretory neuropile, which they encircle. The cell bodies are probably represented by four e cells which, like the terminals, contain many mitochondria.     

Mitotic division of differentiated neurosecretory cells in the hypothalamus of adult amphibians

By means of multiple 3H-thymidine administration to adult frogs, a direct electron microscopic radioautographic evidence is first by presented regarding the possibility of an in vivo mitotic division of differentiated hypothalamic peptidergic neurosecretory cells. The absence of any signs of cytoplasmic dedifferentiation, as well as a poor development of spindle microtubules in this cell may be suggestive of a polyploidizing, possibly acytokinetic mitotic process occurring in such kind of cells.     

锯缘青蟹窦腺显微和超微结构研究

借助光学和电子显微镜观察据缘青蟹（Ｓｃｙｌｌａ ｓｅｒｒａｔａ）窦腺的形态结构。窦腺位于眼柄视神经节内髓背侧近外髓处。窦腺呈羹状;腺体壁山神经分泌细胞的末梢和神经胶质细胞组成。神经末梢内充满了电子致密的神经分泌颗粒。根据颗粒的大小、形态及电子致密度等特征,可以区分出４种类型的神经末梢。一些末梢中的多形性颗粒可能是由Ⅱ型末梢中的颗粒转变而成的。一些现象表明,神经分泌物质可以通过胞吐作用或一种类似“顶浆分泌”的方式释放,从而说明神经激素的释放可能是多途径的．     

Maturation of the human hypothalamo-hypophyseal neurosecretory system in prenatal ontogeny. A light-optical and electron microscopic study

The hypothalamic-hypophysial neurosecretory system (HHNS) was studied in the human foetuses from the age of 8 weeks till birth. The hypothalamus of 8 weeks old foetuses is weakly differentiated, no individual cell groups, so-called nuclei, are identified. The supraoptic (SON) and paraventricular (PVN) nuclei are identified from the age of 12 weeks on. The size of cell nuclei increases with the age. The Homori-positive granules were first found in some SON and PVN cell and in neurohypophysis in the 18 weeks old foetuses. It was shown under the electron microscope that the neurohypophysis of 8 weeks old foetuses consisted mainly of pituicytes with axons among the cytoplasmic processes of the latter. After the age of 10 weeks, the area of parenchyma of the neurohypophysis occupied by axons increased and typical elementary neurosecretory granules appeared in them. The data obtained are discussed with respect to the participation of HHNS in the regulation of water metabolism in the human foetuses.     

Serotonin-producing pancreatic endocrine tumour. Histological, ultrastructural and immunohistochemical study of a case

Serotonin-producing pancreatic endocrine tumours are rare neoplasms which in most cases exhibit malignant biological behaviour. These tumours, in the majority of the well-documented cases, are composed of argyrophil- and argentaffin-positive cells which contain large pleomorphic neurosecretory granules. In contrast, argyrophilic non-argentaffin pancreatic endocrine tumours with tumour cells containing round neurosecretory granules are exceptional. In this study we describe such a tumour not associated with clinical evidence of carcinoid syndrome in a 60-year-old woman. Histological examination revealed tumour extension in pancreatic lymphatic vessels and veins but no evidence of locoregional or distant metastases. Ten months after surgery the patient showed no recurrence of the disease. Immunohistochemistry revealed cytoplasmic serotonin production in the tumour cells which were negative for anti-gastrin, insulin, glucagon, somatostatin, pancreatic polypeptide (PP), vasoactive intestinal peptide (VIP) and ACTH. This study emphasizes the usefulness of combined ultrastructural and immunohistochemical investigations in order to identify and characterize the rare pancreatic endocrine tumours with serotonin production.