Influence of chronic doses of mercuric acetate and lead acetate on the number and activity of Gomori-positive glial cells in the mouse brain.

Intraperitoneal injections of mercuric acetate or lead acetate in doses of 0.2 mg daily during 14 and 21 days caused statistically significant rise in the number of the Gomori-positive glial cells around the third cerebral ventricle of mice. In addition, the nuclei of the Gomori-positive glial cells markedly increased in volume.     

The glial Gomori-positive material is sulfane sulpfur

The Gomori-positive glia are periventricular astrocytes with abundant cytoplasmic granular material, predominantly occupying a periventricular site in the brain. These granular inclusions are strongly stained with chrome hematoxylin in the Gomori's method as well as exhibit red autofluorescence and non-enzymatic peroxidase activity. The glial Gomori-positive material (GGPM) granules are positive in the performic acid Alcian blue method indicating the presence of protein-bound sulfur, what has been shown by our previous studies. The number of cells containing glial Gomori-positive granules dropped after administration of cyanide and increased under the influence of sulfane sulfur donor (diallyl disulfide). This suggests, that sulfur of these granules is a sulfane sulfur, possibly in the form of protein-bound cysteine persulfide. Sulfane sulfur is labile, reactive sulfur atom covalently bound to another sulfur atom. In this paper we present evidence that GGPM exhibit affinity to cyanolysis and its stainability in Gomori's method is due to the presence of protein-bound sulfane sulfur. The biological role of the Gomori-positive glia connected with protective properties of sulfane sulfur has been discussed.     

Effect of fixation on the demonstration of neurophysin and "Gomori-positive" substances in neurosecretory granules of the rat hypothalamus.

Proteins reacting with neurophysin antibodies and "Gomori-positive" substances were demonstrated histochemically in hypothalamic neurosecretory material of normal and bilaterally adrenalectomized rats after two different fixations: a) picric acid-formalin (PAF) for 7 days at 37 degrees C; b) Bouin's fluid for 20 h at 4 degrees C. After PAF-fixation anti-neurophysin reactive neurosecretory granules are found in all parts of the supraoptico-hypophysial system and in the suprachiasmatic nucleus of normal and adrenalectomized animals. In the latter they can additionally be demonstrated in the outer layer of the median eminence. Amount and distribution of "Gomori-positive" substances correspond to those described for the immunoreactive material, except for the suprachiasmatic nucleus, in which the substances can not be detected; Following fixation in Bouin's fluid the immunohistochemical reactions are unchanged whereas the staining of "Gomori-positive" substances is remarkably impaired. The amounts of the substances demonstrable in the neural lobe are diminished and in the cells of the supraoptic and paraventricular nuclei as well as in both median eminence layers only traces of the substances are to be seen. The findings indicate that negative results in demonstrating "Gomori-positive" substances may be caused by inappropriate fixation and need to be controlled by immunohistochemical techniques.     

Ultrastructure of the Neurohypophysial Lobe of the Hagfish,Eptatretus stouti (Cyclostomata)

The neurohypophysial lobe is a thin-walled sac that, except for a few blood vessels, lacks any anatomical link with the adenohypophysis. Its wall consists of ependymal, fiber and palisade zones and is surrounded by blood vessels. The lobe is differentiated into distinct dorsal and ventral regions. The dorsal wall is doubly innervated by Gomori-positive axons arising in the anterior hypothalamus and by Gomori-negative fibers of unknown origin. Its surface is covered by an extensive vascular plexus. The ventral wall is innervated only by Gomori-negative fibers and is sparsely supplied with a few fine capillaries. All of the ependymal cells in both regions have the same ultrastructural appearance. The Gomori-positive or Type I axons are identified at the electron microscope level as fibers containing elementary granules with a diameter of 150–230 run. The Gomori-negative or Type II fibers contain dense-cored vesicles that vary from 80–125 nm in diameter. Both Type I and II fibers form synaptic-like complexes with the processes and end-feet of the ependymal cells. Type I axons also abut on the basal lamina bounding the perivascular spaces. It is suggested that the agranular reticulum of the ependymal cells may provide a transport pathway for neural products that are destined for release into the circulation. It is also possible that the ependyma itself is a target of neural activity.     

“Gomori-positive” neurosecretion in the rat after deafferentation of the medial basal hypothalamus

A portion of the "Gomori-positive" peptidergic neurosecretory (NS) cells in the paraventricular and especially in the supraoptic and postoptic nuclei degenerate three weeks after deafferentation of the medial basal hypothalamus. Most of the remaining NS cells show signs of high activity. Regenerating NS fibres form "muffs" around the blood vessels laterally from the lesion; some of them enter the "isolated" area or persist there if a thin layer of the brain tissue is left somewhere untouched under the basal end of the cut. The regenerating NS fibres are also found outside the nervous tissue: within the scar tissue, in the proliferating connective tissue of the brain sheet below the basal end of the cut and in the mantel plexus area. The NS fibres make close contact with blood vessels invading or penetrating the vascular wall. It is suggested that peptide neurohormones discharged from the "Gomori-positive" NS terminals enter the general blood circulation as well as the portal blood at the site of these newly formed axovasal contacts. It is supposed that under these conditions monoaminergic terminals do not discharge monoamines because no stimulation of monoamine-producing NS cells occurs with deafferentation.     

Gomori-positive elementary granules in inner and outer layer of the infundibulum

With the gallocyanine technique (Wittkowski, Bock and Franken, 1970) Gomori-positive substances of the infundibulum can be stained for light- and electron-microscopic examination. In various mammalian species, the size of Gomori-positive elementary granules in the outer layer is markedly different from that in the inner layer of the infundibulum. In general, the granules of the outer layer have less then half the diameter of those of the inner layer. In birds and fish, however, only small differences were found between the granules of both layers. The significance of the results is discussed.     

The histological picture of the hypothalamus (the nucleus preopticus) and hypophysis in male Anguilla anguilla L. treated with hormones

Studies were conducted on the effect of human chorionic gonadotropin (HCG), testosterone and desoxycorticosterone acetate (DOCA) on the histological picture of the nucleus preopticus (NPO), hypophysis and gonads of male European eels. It was ascertained that none of the injections used changed the content of the Gomori-positive material within the NPO cells. HCG and testosterone injections altered the histological picture of the hypophysis and injections of HCG influenced the gonads by accelerating their maturity. The injections of DOCA did not change the histological picture of the hypophysis and gonads in male eels.     

Light and electron microscopy of granules in the toad choroid plexus

Summary Two types of granules can be distinguished in the toad choroid plexus under the light microscope: pigment granules, mainly localized in the cells that line the free ends of the choroidal villi, and Gomori-positive granules, present in most epithelial cells.The ultrastructural analysis of the choroid plexus reveals three types of granules: multivesicular bodies (MVB), multigranulous bodies (MGB) and dense bodies (DB), and intermediate stages between the last two bodies. The pigment granules seen under the light microscope probably correspond to the DB of the electron micrographs, and the Gomori-positive granules to the MGB. The probable role of these bodies is discussed and so is the significance of the glycogen present in the choroidal cells, their processes and endothelium.This study was partially supported by the Consejo Nacional de Investigaciones Científicas y Técnicas de la República Argentina and the Rockefeller Foundation (School grant RF — 58028).Fellow of the Consejo Nacional de Investigaciones Científicas y Técnicas de la República Argentina. The author wishes to thank Prof. M. H. Burgos for his constant interest. His thanks are also due to Prof. H. Heller for providing certain facilities in his department and for his criticism.     

Immunohistochemical demonstration of a CRF-associated neurophysin in the external zone of the rat median eminence

Cell and Tissue Research - In picric acid-formalin fixed, paraplast embedded median eminence sections from normal and bilaterally adrenalectomized rats, the amount of “Gomori-positive”...     

Lipopolysaccharide aggravates cerebral pathology in B10.PL-derived CD1-/-, beta2m-/-, TCRalpha-/-, and TCRdelta-/- knockout mice

Adult B10.PL-derived immunological genes knockout mice injected with 100 microg lipopolysaccharide (LPS) showed severe hydrocephalus and meningitis. A consequence of the hydrocephalus is pineal hyperplasia, sponginess of periventricular parenchyma, gliosis and, at the last stage of hydrocephalus formation, disappearance of the ependymal layer and the Gomori-positive subependymal astrocytes. Possible mechanisms for the aggravation of cerebral pathology induced by LPS are discussed.     

On the neurosecretory system of Dendrobaena atheca Cernosvitov

Four kinds of neurosecretory cells A, B, U and C are distinguished in the central nervous system of Dendrobaena atheca Cernosvitov. A cells, which show different morphological characteristics under different physiological states and during their cyclic changes, are the most active neurosecretory cells. They form the outer layer of the cortical cell zone in the cerebral ganglion. B cells are large and medium sized and are distributed in all parts of the central nervous system. U cells are found only in the sub-pharyngeal ganglion while C cells are distributed in the sub-pharyngeal as well as in the ventral nerve cord ganglion. The number and secretory activity of C cells decrease in caudal direction. Further, Gomori-positive cells are also observed in the ganglia of the vegetative nervous system. A rudimentary neurohaemal organ, the storage zone, has been observed in the cerebral ganglion and there appears to be another neurohaemal area in the ventral nerve cord ganglion. The storage zone is formed by the terminal ends of the axons of A cells. The chrome alum haematoxylin phloxin (CHP) and aldehyde fuchsin (AF) positive substances in the form of granules are found in this area. The cerebral ganglion is richly supplied by blood capillaries. The distal end of the axons of B cells are swollen like a bulb while in some cases the axons are united to form an axonal tract. Extra-cellular material is abundant in different parts of the nervous system. In all cell types, the perinuclear zone is the first to show activity in the secretory cycle. It appears that the nucleus may be involved in the elaboration of the neurosecretory material in the cells.     

Reaction of the hypothalamo-hypophyseal system of cats to stimulation of the cervical sympathetic nerve and the afferent fibers of the vagus nerve]

Data are presented on the functional morphology of the hypothalamo-hypophysial neurosecretory system of cats in stimulation of the cervical sympathetic nerve and of the afferent fibers of the vagus. Stimulation of the sympathetic nerve selectively activated the supraoptic nucleus and caused the discharge of the neurohormones from the posterior lobe of the hypophysis, whereas its infundibular portion contained much neurosecretory material. In response to the stimulation of the vagus all the portions of the neurohypophysis were released of the Gomori-positive substance; both the supraoptic and the paraventricular nucleus were activated.     

LRF producing cells of the mammalian hypothalamus

Summary The demonstration of perikarya of mediocellular neurones producing LRF, using indirect immunofluorescence on slides and anti synthetic LRF antibodies, requires both their activation and the inhibition of their axoplasmic transport. This fact suggests that LRF is present in an immunoreactive form, but usually in very low concentrations. Perikarya of neurons producing LRF are found principally in the preoptic and septal areas of the rat and decrease caudally, particularly beyond the retrochiasmatic area. Most of the axons coming from these perikarya are incorporated in the hypothalamoinfundibular tract and terminate around the capillaries of the primary portal plexus, particularly those of interealar plexus. Other axons (or axon collaterals) may be found in various areas (suprachiasmal crista, epithalamus, amygdala, mesencephalon) and form circuits recalling the “extrahypophyseal pathways” described for the magnocellular Gomori-positive neurons of the SON and PVN. These axons are probably concerned in intersegmental regulations involving “neurosecretory synapses”, particularly of the axosomatic type. The placement of stereotaxic lesions was used to determine the topography and direction of axoplasmic flow of the axons transporting LRF. The infundibular immunoreactive material, already discernible at the end of gestation in the foetus, shows considerable variations between birth and puberty, during the estrous cycle and under various other physiological or experimental conditions. The observations made under various experimental or physiological conditions suggest that, in the guinea-pig in particular, the greater part of the hypothalamic immunoreactive material is concentrated in the infundibular area. This area of accumulation is comparable to the distal neurohypophysis of the Gomori-positive neurosecretory system coming from the SON and PVN. This work was financed by the D.G.R.S.T. Contract No. 72-7-0375.     

Physiological dependency between the hypothalamus and the thymus in Wistar rats. II. The neurosecretion level and microstructural changes following para-chlorophenylalanine administration. The differences in DL-5-hydroxy G-3H tryptophane incorporation in the hypothalamus of normal and thymectomized rats

The experiments were carried out on male Wistar rats, both normal and thymectomized in which the thymus was excised in 12th h of life. 8 weeks later, the animals were administered parachlorophenylalanine [PCPA], i.e. a compound inhibiting tryptophane hydroxylase, in the amount of 200 mg/kg of body weight. The studied hypothalamus preparations, i.e. supraoptical [NSO] and paraventricular nuclei [NPV] revealed an increased level of Gomori-positive neurosecretory material in thymectomized rats when compared to control animals. It was observed that the former rodents manifested an elevated incorporation of the isotope, i.e. DL-5-Hydroxy [G-3H] Tryptophane. The calculations performed by the use of the Gosset's t-test ("Student's") showed that the difference was statistically significant (p less than 0.001).     

Cytologie du lobe anterieur de l'hypophyse du chien

Summary Detailed histochemical studies have been made on the distribution of various enzymes such as phosphatases, cholinesterases, glycolytic enzymes and respiratory enzymes in various components of the hypothalamus with special reference to the supraoptic and paraventricular nuclei of the Squirrel Monkey. Cytological studies have also been made by the McManus, Einarson, Gomori and Bargmann methods.A few neurons of these nuclei showed scanty Gomori-positive material in the cytoplasm for the Gomori and Bargmann methods. Nissl granules were located in the peripheral cytoplasm of most neurons. No glycogen granules were observed in these neurons. For these reasons, the Squirrel Monkey, like the rat, may not be a suitable species for the study of neurosecretory phenomena.The axons of these neurons were negative for the specific cholinesterase test, though the perikaryon and some parts of the processes gave a moderately positive reaction. These neurons may be non-cholinergic and the cholinergic fibers from an unknown nucleus may end in synapses on their cell bodies. Blood vessels and glial cells in the neurosecretory nuclei showed non-specific cholinesterase activity. This enzyme may hydrolyze the acetylcholine which has escaped splitting by specific cholinesterase. Alkaline phosphatase and acid phosphatase in these neurons may be involved in the metabolism concerned with the production of neurosecretory material. The neurons may be physicochemical receptors and may get enough energy and raw material to synthesize the neurosecretory material from the rich blood supply. Neurons of the supraoptic and paraventricular nuclei as well as other hypothalamic neurons, like neurons of other regions of the brain, are well equipped with the enzymes of the glycolytic pathways and the tricarboxylic acid cycle. Since the glial cells of these nuclei have amylophosphorylase activity and glycolytic pathways, they may work as energy donators to the neurons of the neurosecretory nuclei. T. R. Shanthaveerappa in previous publications.     

Neuroendocrine heart and hypothalamus

Data on the endocrine heart—neurosecretory cells of heart, producing coronarydilatory, metabolically active glycopeptides with physico-chemical and biological properties similar to those of previously discovered cardioactive hypothalamic neurohormones—are summarized. Heart hormones participate in both local and distant regulation of heart metabolism and function. Formation and action of these heart hormones is closely related to hypothalamic cardioactive neurohormones K, C, and G and their protein precursors. Neurohormones from heart and hypothalamus comprise a system of neurohumoral connections between these two organs. A possible role of APUD cells in the generation of a number of heart peptides and glycopeptides exerting hormonal activity is discussed.Abbreviations Used NC Neurohormone C - NK Neurohormone K - NC-H Hypothalamic NC - NK-H Hypothalamic NK - PC-NC NC cleaved from protein-carrier - PC-NK NK cleaved from protein-carrier - BB-NC Brain blood NC - BB-NK Brain blood NK - H₁ Substrate 1 from heart - H₂ Substrate 2 from heart - H₃ Substrate 3 from heart - HB₁ Substrate 1 from heart blood - HB₂ Substrate 2 from heart blood - PC-H₁ H₁ cleaved from protein-carrier - PC-H₂ H₂ cleaved from protein-carrier - PC-H₃ H₃ cleaved from protein-carrier - PC-CC Coronaroconstrictory substance cleaved from protein-carrier - GPG Gomori-positive granules - MLC Mast-like cells     

GLUT2 immunoreactivity in Gomori-positive astrocytes of the hypothalamus.

A specialized subtype of astrocyte, the Gomori-positive (GP) astrocyte, is unusually abundant and prominent in the arcuate nucleus of the hypothalamus. GP astrocytes possess cytoplasmic granules derived from degenerating mitochondria. GP granules are highly stained by Gomori's chrome alum hematoxylin stain, by the Perl's reaction for iron, or by toluidine blue. The source of the oxidative stress causing mitochondrial damage in GP astrocytes is uncertain, but such damage could arise from the oxidative metabolism of glucose transported into astrocytes by high-capacity GLUT2 glucose transporters. In accord with this hypothesis, the reported anatomical distribution of astrocytes staining positively for GLUT2 glucose transporters closely matches that of GP astrocytes. To examine whether or not these two staining procedures detect the same population of astrocytes, immunocytochemistry was performed on semithin sections to detect GLUT2 protein and sections were then stained with toluidine blue to detect GP granules. It was determined that GP astrocytes are frequently immunoreactive for the GLUT2 transporter protein. These data support the possibility that GP astrocytes may have an important influence upon the reactivity of the hypothalamus to glucose and that a specialized glucose metabolism may in part underlie the development of mitochondrial abnormalities in hypothalamic GP astrocytes.     

Electron microscopical and histochemical observations on the relation between medio-dorsal bodies and neurosecretory cells in the basommatophoran snails Lymnaea stagnalis,Ancylus fluviatilis,Australorbis glabratus and Planorbarius corneus

Summary In Basommatophora medio-dorsal bodies (MDB) are closely attached to the cerebral ganglia, in which, just underneath the bodies, groups of Gomori-positive neurosecretory cells (MDC) occur. It has been suggested that the MDB-cerebral ganglion complex should be regarded as a neuro-endocrine association.In the present study the morphological relation between MDB and the ganglion is histochemically and ultrastructurally investigated in Lymnaea stagnalis, Ancylus fluviatilis, Australorbis glabratus and Planorbarius corneus.Histochemical tests showed the paraldehyde-fuchsin positive material of fibers in the MDB to be different from the neurosecretory material (NSM) in the MDC. At the ultrastructural level no penetration of nerve cell processes through the perineurium, separating the MDB from the ganglion, into the medulla of the MDB was observed. However, excepting for Lymnaea, the perineurium at these places shows particular differentiations. In the medulla of the MDB granule laden profiles (granule ø 700–900 Å) occur. They appeared to be processes of MDB cells.From these results it is concluded that the medulla of the MDB should not be regarded as a neurosecretory neuropile. Apparently, the MDB-cerebral ganglion complex is no neuroendocrine association. Probably the MDB is an endocrine organ. The small electron dense granules of the profiles in the medulla were also found in the MDB cell bodies. They are thought to represent a secretion product. The close morphological relation between MDB and cerebral ganglion may be connected with the origin of the MDB cells from perineural elements.     

Ultrastructure of the neurohaemal region of the toad median eminence

Summary According to the internal structure and size of the granules, six types of nerve endings can be distinguished in the toad median eminence: 1. Endings containing mostly dense granules of 600 Å in diameter; 2. Endings containing dense granules of about 800 Å in diameter; 3. Endings which contain dense granules 1,000–2,000 Å in diameter, with the peak at 1,200–1,400 Å; 4. Endings containing granules with a characteristic structure, which differentiate them from the other three types; 5. Scarce endings containing granules 2,000 to 3,800 Å in diameter; and 6. Endings containing only vesicles 400–500 Å in diameter. Types 3 and 4 endings are mainly found in the outer pericapillary zone, and are probably responsible for the strong Gomori-positive reaction observed in this zone. The other four types of endings occur mainly in the inner pericapillary zone, and appear to be Gomori-negative.The probable origins of the different types of endings, and their possible relations with the different releasing factors is discussed.The subendothelial basement membrane has numerous long processes which form a complicated network in contact with all the nerve endings, some nerve fibres and glial cells.Two types of glial cells are described. Pinocytotic vesicles are frequently seen at the points where these cells contact the basement membrane. All the ultrastructural features suggest that these cells are carrying out transport functions.Fellow of the Consejo Nacional de Investigaciones Científicas y Técnicas de la República Argentina.The author is very grateful to Professor H. Heller for his continued encouragement and criticism and to Mr. J. Lane and Mr. P. Heap for their valuable help.     

Cerebrospinal fluid-contacting neurons,ciliated perikarya and “peptidergic” synapses in the magnocellular preoptic Nucleus of teleostean fishes

Summary The magnocellular preoptic nucleus of fishes (Anguilla anguilla, Amiurus nebulosus, Cyprinus carpio, Carassius auratus, Ctenopharyngodon idella, Cichlasoma nigrofasciatum) has been studied by light and electron microscopy.Two kinds of neurons were found: a) large, electron-dense, Gomori-positive cells with moderate acetylcholinesterase (AChE) positivity which contain granulated vesicles of 1400 to 2200 Å (in average 1600 to 1800 Å), and b) small, strongly AChE-positive, electron-lucent neurons containing granulated vesicles of 900 to 1200 Å. The nerve cells are supplied with axo-somatic and axo-dendritic synapses. These are formed by axon terminals containing either 1. synaptic vesicles of 500 Å, or 2. synaptic vesicles of 500 Å and dense-core vesicles of 600 to 800 Å, or 3. synaptic vesicles of 600 Å and granulated vesicles of up to 1100 Å, or 4. synaptic vesicles of about 400 Å and granulated vesicles of up to 1800 Å. The presence of peptidergic and numerous other synapses shows the complexity of the organization and afferentation of the magnocellular preoptic nucleus.In the eel, both types of nerve cells form dendritic terminals within the cerebrospinal fluid (CSF). These CSF contacting dendrites are supplied with 9×2+0 cilia. In the other species investigated, only some large neurons build up intraventricular endings. The ependymofugal process of the CSF contacting neurons enters the preoptic-neurohypophysial tract.Perikarya of both the large and the small cells may give rise to single, paired or multiple 9×2+0 cilia extending into the intercellular space. The number of CSF contacting neurons is reciprocal to the number of perikarya with intercellular cilium. These latter cells may represent modified, more differentiated forms of the CSF contacting neurons. We think that atypical cilia protruding into the intercellular space may have the same significance for the intercellular fluid as the cilia of the intraventricular dendrites of the CSF contacting neurons for the CSF.Dedicated to Prof. Dr. W. Bargmann on the occasion of his 70th birthday.