Structural re-evaluation of the neurosecretory system in the crayfish eyestalk

Summary The topography of the neurosecretory system in the decapod eyestalk has not been precisely delineated with light microscopy. Cobalt iontophoresis and electron microscopy have proved useful in clarifying the microstructure of this system. The sinus gland (sg) of the crayfish eyestalk consists of aggregated axon terminals which end at or near the blood space, lontophoresing cobalt back through the cut base of the sinus glands reveals proximal cell bodies in the eyestalk only in the X organ (Xo) region. Electron microscopy demonstrates that axons from about 115 neurosecretory cell bodies in the Xo form the Xo-sg tract. Intermingled with these Xo somata are smaller non-neurosecretory cell bodies which do not send axons into the sinus gland. One of these exhibits catecholamine fluorescence. Backfilling also reveals a second group of fibres which run from the brain along the optic tract and into the sinus gland. These brain-sg fibres are smaller in diameter than Xo-sg axons and lack neurosecretory vesicles. From these fibres collaterals extend into the eyestalk neuropil, especially in the proximity of the visual elements. The possible function of these non-neurosecretory processes within the sinus gland is discussed.This work was supported by a National Research Council of Canada grant     

Ultrastructure of the rat posterior pituitary gland and evidence of hormone release by exocytosis as revealed by freeze-fracturing

Summary Posterior pituitary glands from normal rats, and rats which had been deprived of water for varying periods, were examined by the freeze-fracture method. This technique reveals large areas of the nerve cell membrane. Images consistent with exocytosis as the mechanism of release of the neurohypophysial hormones were observed. These modifications were most numerous after the rat had been starved of water for 2 days.In normal rats, the large number of neurosecretory granules within the nerve fibres caused a bulging of the nerve cell membrane. The bulges disappeared 2 days after removal of drinking water. Regions of the membrane displaying bulges were characterised by the absence of the typical membrane-associated particles.It is postulated that the close proximity of the neurosecretory granules to the nerve cell membrane may result in rapid fusion of the neurosecretory granules on stimulation of the gland. The change in properties of the nerve cell membrane overlying the neurosecretory granules, as suggested by the loss of membrane-associated particles, may represent a change in the structure of the membrane to a form which is more favourable for fusion.This work was supported in part by a grant from the New Zealand Medical Research Council.     

PHB synthase from Streptomyces aureofaciens NRRL 2209

An approximately 4.9 kb Sau3A I genomic DNA fragment from the Streptomyces aureofaciens NRRL 2209 aiding in the biosynthesis of PHB in recombinant Escherichia coli has been sequenced and analysed for phaC gene. The putative phaC(Sa) gene of 2 kb is 79.1% GC rich and encodes a 63.5 kDa protein. It expressed under its own promoter and significant PHA synthase activity was detected in the recombinant E. coli. This is the first putative PHA synthase gene reported from a Streptomyces sp. with serine as the active nucleophile in the conserved lipase box. The phaC(Sa) was found in close proximity to a regulatory gene, which apparently regulated the phaC expression.     

Termination region in rRNA genes from a eucaryotic thermophile, Thermomyces lanuginosus.

S1 mapping of the termination region in the ribosomal DNA from a thermophilic fungus, Thermomyces lanuginosus, revealed three distinct termini corresponding to the mature 25S rRNA, a precursor that is 19 nucleotides longer and corresponds to the 37S precursor in yeast cells, and a putative termination site at +96 that bears a limited sequence homology with the SalI box of mammalian cells. An estimate of the secondary structure suggested that the three termini are in close proximity, a feature that may be essential to precursor termination and maturation. The results raise questions regarding recently reported relationships between ribosomal DNA termination and spacer enhancer elements in fungi.     

Neurosecretory system of the American dog tick,Dermacentor variabilis (Acari: lxodidae). I. Diversity of cell types

An arbitrary classification scheme is presented for the thirteen distinct types of secretory cells distinguished within the central nervous system of Dermacentor variabilis by several specific and general neurosecretory staining techniques. Comparisons to classic arthropod neurosecretory cell types are made and the histochemical implications of the chromophilic response of various secretory products are discussed. Dermacentor cells of Types I, VII, IX and X may be considered neurosecretory on the basis of intracellular elaboration and discharge of secretory product. Type II, III, IV, V, VI, XI and XII cells are considered as putative neurosecretory cells although secretory products were detected only within the perikarya. The large Type XII cells are also similar to motor neurones reported from other arachnids. Cells of Types VIII and XIII appear to be glial elements. The secretory products of Type XIII_A are distributed within trabecular processes in the subperineurium. These products may play a trophic role or they may have some endocrine function as a form of “gliosecretion”.     

Studies on the neurosecretory system and retrocerebral endocrine glands of Nezara viridula Linn. (Heteroptera: Pentatomidae)

The neurosecretory system and retrocerebral endocrine glands of Nezara viridula Linn. have been described on the basis of in situ preparations and histological sections employing the paraldehyde fuchsin (PF) and performic acid-victoria blue (PAVB) techniques. In the brain of N. viridula, there are two medial groups–each consisting of five neurosecretory cells which belong to A-type. The lateral neurosecretory cells are absent. The axons of the two groups of medial neurosecretory cells (MNC) compose the two bundles of neurosecretory pathways (NSP) that decussate in the anterodorsal part of the protocerebrum. The two pathways, after the cross-over, run deep into the protocerebrum and deutocerebrum and emerge as NCC-I from the tritocerebrum. The nervi corporis cardiaci-I (NCC-I) of each side which are heavily loaded with NSM terminate in the aorta wall. Thus, the neurosecretory material (NSM), elaborated in the medial neurosecretory cells of the brain, is stored in the aortic wall and nervi corporis cardiaci-I (NCC-I). The NCC-II are very short nerves that originate from the tritocerebrum and terminate in the corpora cardiaca (CC) of their side. Below the aorta, but dorsal to the oesophagus, lie two oval or spherical corpora cardiaca. A corpus allatum (CA) lies posterior to the corpora cardiaca (CC). The corpora cardiaca do not contain NSM; only the intrinsic secretion of their cells has been occasionally observed which stains orange or green with PF staining method. The corpus allatum sometimes exhibits PF positive granules of cerebral origin. A new connection between the corpus allatum and aorta has been recorded. The suboesophageal ganglion contains two neurosecretory cells of A-type which, in structure and staining behaviour, are similar to the medial neurosecretory cells of the brain. The course and termination of axons of suboesophageal ganglion neurosecretory cells, and the storage organ for the secretion of these cells have been reported. It is suggested that the aortic wall and NCC-I axons function as neurohaemal organ for cerebral and suboesophageal secretions.     

The noradrenergic innervation of the excretory ducts of the parotid, mandibular and sublingual glands in the rat

Summary The noradrenergic innervation of the excretory ducts of the parotid, mandibular and sublingual salivary glands in the rat has been examined using fluorescence histochemistry. None of the ducts were found to be innervated directly but, in the mandibular duct, innervated blood vessels are in close proximity to the epithelial cells of the duct and it is suggested that noradrenaline may diffuse from the vascular nerve endings to receptors on the epithelial cells.     

Annulate lamellae in hamster pineal gland

Pineal glands from young adult hamsters (Mesocricetus auratus Water-house) kept on a 14-10 light-dark photoperiod contain annulate lamellae. These annulate lamellae are apparently limited to the light pinealocytes. They are found in close proximity to nuclei, the Golgi apparatus, and agranular endoplasmic reticulum. There is also an interesting association or microtubules with the annulate lamellae. It seems reasonable that the presence of annulate lainellae in the pinealocytes may have some correlation with the physiological function or functions of these cells.     

The cardiacal neurosecretory system and associated organs of an adult mosquito, Aedes aegypti

Unlike most other insects, mosquitoes do not possess discrete corpora cardiaca composed of neuropile, intrinsic neurosecretory cells and glial cells. Cells homologous with the intrinsic neurosecretory cells of other insects are located at the junction of the neck and thorax of mosquitoes, close to the corpora allata. These cells are named cardiacal neurosecretory cells. Axons run forwards from the cardiacal neurosecretory cells into the allatal nerves. Neurosecretory release sites occur over almost the whole of the nervi corporum cardiacorum, allatal nerves and oesophageal nerves, and these nerves constitute a very extensive neurohaemal organ for many of the cerebral neurosecretory cells. The neurosecretory release sites of the cardiacal neurosecretory cells appear to be in the allatal nerves and possibly also on the perikarya of these cells.     

Alcian blue-alcian yellow mapping of neurosecretory cells in the central nervous system of the salt marsh pulmonate snail Melampus bidentatus

1. The neurosecretory system of the primitive ellobiid Melampus bidentatus (Pulmonata: Basommatophora) was investigated using Alcian blue-Alcian yellow histochemistry. 2. Putative neurosecretory cells within the central ganglia were distinguished by the criteria of cell size, position, and staining reaction. 3. The cerebral ganglia, with attached lateral lobes, contained the greatest diversity of neurosecretory cell types (at least seven), including single cells and cell clusters ranging from two to 40 cells. 4. Four neurosecretory cell types were identified in the parietal and visceral ganglia, two in the pedal ganglia, and one each in the buccal and pleural ganglia. 5. Neurosecretory system homology among pulmonate gastropods is suggested by the close similarity of the Melampus AB/AY cell map to those reported in the literature for two limnic basommatophorans and for four terrestrial stylommatophorans.     

Release of neurosecretory granules within the corpus allatum in relation to the regulation of juvenile hormone synthesis in Diploptera punctata

The release of neurosecretory granules within the corpora allata (CA) of the viviparous cockroach Diploptera punctata has been compared in glands with intact nerves from the brain (Brain-CA) and those detached from the brain. Measurements of juvenile hormone (JH) synthesis in vitro, comparing these two conditions of the CA at several stages of vitellogenesis in adult females, showed lower production of hormone in Brain-CA complexes than in CA alone. Glands treated with tannic acid to trap exocytotic granules before fixation for electron microscopical examination showed, in sample sections, 10 times more exocytotic profiles in the glands with intact nerves to the brain than in the isolated glands. Sections treated with antibody against allatostatin I (Dip 7), a member of the neuropeptide family that inhibits JH synthesis by CA in vitro, showed neurosecretory granules in allatostatin immunoreactive nerves to be 75+/-4% of the granules in the sample of sections of CA. Because the total quantity of allatostatin in CA was found by ELISA not to vary significantly with changes in JH synthesis, it is concluded that the lower rates of JH synthesis by glands with intact nerves to the brain are most likely due to the release of small amounts of allatostatin within the CA.     

Ultrastructure of the retrocerebral complex in the adult midge,chironomus riparius MG (Diptera : Chironomidae)

The organisation of the retrocerebral complex of adult Chironomus riparius Mg. (Diptera : Chironomidae) has previously been compared with that of the larva. The primary objective of the present work was to examine the ultrastructure of the components of the complex in neoimaginal male C. riparius to enable their further comparison with similar structures in other dipterans and determine whether this information supports the contention that the midge has a relatively primitive neuroendocrine system.The hypocerebral ganglion has a complex innervation, is composed of non- neurosecretory neurons and glial cells and, with the adjacent aortic wall, is the major neurohaemal site of the complex. The corpora cardiaca are not intimately associated with the ganglion. They are not apparently neurohaemal but are composed of cells containing granules with a bimodal size distribution. The corpora allata are of the pseudolymphoid type and are devoid of extracellular stromal channels. Peritracheal tissue persists into the neoimaginal midge but is apparently inactive and undergoing degeneration.The post-cerebral glands have been included in all previous accounts of the retrocerebral complex in chironomids but the present work confirms the view that they are not endocrine in nature despite their close proximity to the corpora cardiaca. Their ultrastructural appearance suggests that they may be functionally related to pericardial cells in other insects.It is concluded that the retrocerebral complex is indeed rather primitive both in its organisation and in the structure of its components.     

Mucosal nerves and smooth muscle relationships with gastric glands of the opossum: an ultrastructural and three-dimensional reconstruction study

The precise anatomical relation by which autonomic nerve endings contact gastric epithelial cells to enhance the rate of gastric secretions is not fully understood. The aim of the present study was to clarify this issue by using the technique of serial section reconstruction of areas of the gastric mucosa. The work also explored the possibility of a functional role for a system of smooth muscle strands in the gastric mucosa that emanate from the muscularis mucosa, run in the lamina propria, and are associated in a unique manner with the gastric glands. Electron microscopic serial sections of the gastric mucosa were performed to visualize the entire limiting membrane of gastric epithelial cells to determine any nerve associations (especially varicose endings) with these cells. Evaluation of serial sections of five separate parietal cells showed that their basal membrane did not come in close contact (nearest distance 500 nm) with any nerve axon or varicosity. Moreover, the axons passing in the area of these cells ultimately showed varicose endings associated with smooth muscle cells in the adjacent connective tissue (often separated by only 20 nm), with mast cells or with vascular elements. Additionally, the lateral membrane of these five parietal cells did not contact any endocrine cell in the epithelium, although other parietal cells in the area were adjacent to endocrine cells. Chief cells in the immediate area also did not form any close associations with nerve varicosities. Random analysis of 5,000 additional epithelial cells in these sections showed no close associations to nerve elements with significant accumulations of neurosecretory vesicles (varicosities). Because of the observed existence of innervation to the smooth muscle strands in the area of the gastric glands, serial 1-micron epoxy sections of the gastric mucosa were prepared, and profiles of smooth muscle and gastric glands were entered into a computer-assisted reconstruction system. Three-dimensional reconstruction techniques were employed to reveal the existence of a unique association between the mucosal smooth muscle strands and the gastric glands. The muscle strands arose from the muscularis mucosa at regular intervals and became branched to form an intricate wrap around a series of gastric glands that empty into one gastric pit.(ABSTRACT TRUNCATED AT 400 WORDS)     

Characterization of three neurosecretory proteins from the A median neurosecretory cells of Locusta migratoria by coupled chromatographic,electrophoretic and isoelectrofocusing methods

Proteins from the nervous corpora cardiaca (N-CC) of Locusta migratoria were analysed using a combination of chromatography, electrophoresis and electrofocusing. Three major cysteine or/and cystine-rich proteins were identified as neurosecretory proteins of the median neurosecretory cells (M-NSC) by comparing the pattern of separated proteins of (1) intact N-CC and (2) depleted N-CC after intracerebral axotomy of the M-NSC.These three neurosecretory proteins are: a trimer, a dimer and a monomer. The trimer and the monomer are composed of apparent 18,000 subunits and 9000 polypeptide chains. The dimer is composed of apparent 7000 subunits composed of putative 4000 polypeptide chains. The three neurosecretory proteins are acidic (pH_i approx. 5.6 for the trimer, 5.1 for the monomer and 4.0 for the dimer). Their relationship to the neurophysins and to the neurosecretory protein isolated from brain and corpora cardiaca of the locust by Friedel et al. (1980) (Gen. comp. Endocr.41, 487–498) is discussed. The role of these three neurosecretory proteins (carrier protein, neurohormone or precursor of neurohormone) is as yet unknown.     

Identification of a novel prothoracicostatic hormone and its receptor in the silkworm Bombyx mori

The insect brain regulates the activity of the prothoracic glands to secrete ecdysteroids, which affect growth, molting, and metamorphosis. Here we report the identification of a novel prothoracicostatic factor and its receptor in the silkworm Bombyx mori. The prothoracicostatic factor purified from pupal brains of B. mori is a decapeptide with the conserved structure of an insect myosuppressin and thus named Bommo-myosuppressin. Bommo-myosuppressin dose dependently suppressed the cAMP level and inhibited ecdysteroidogenesis in the larval prothoracic glands at much lower concentrations than the prothoracicostatic peptide, the other prothoracicostatic factor reported previously. In vitro analyses using a prothoracic gland incubation method revealed that Bommo-myosuppressin and prothoracicostatic peptide regulate the prothoracic gland activity via different receptors. In situ hybridization and immunohistochemistry revealed the existence of Bommo-myosuppressin in the brain neurosecretory cells projecting to neurohemal organs in which it is stored. We also identified and functionally characterized a specific receptor for Bommo-myosuppressin and showed its high expression in the prothoracic glands. All these results suggest that Bommo-myosuppressin functions as a prothoracicostatic hormone and plays an important role in controlling insect development.     

Muscles and innervation of the genital and postgenital abdominal segments of the female american cockroach Periplaneta Americana (L.) (Dictyoptera : Blattidae)

The locations of skeletal muscles in abdominal segments 7–10 of female Periplaneta americana (Dictyoptera : Blattidae) are described, and the action of some of those attached to the gonapophyses is hypothesized. The muscles are innervated from a terminal synganglion, a composite formed by fusion of embryonic neuromeres of abdominal segments 7–11. Pathways of the 5 pairs of segmental nerves and 3 pairs of transverse nerves that issue from the synganglion are documented. In addition to supplying skeletal muscles, certain of the nerves can be traced to the oviducts, spermatheca, colleterial glands, ventral glands, hindgut, and apparently, to sensilla of the cerci, gonapophyses, paraprocts, tergum, pleura, and sternum. Homologous relationships of the nerves are proposed, and the observations are compared to those reported by others who have, for the most part, examined males only. Putative neurosecretory somata occur in abdominal segments 7 and 8, at the junction of the transverse and segmental nerves. The association may be comparable to the “link nerve” complex described by others.     

The projections of neurosecretory cells in the brain of the North-American medicinal leech,Macrobdella decora,using intracellular injection of horseradish peroxidase

The projections of four anatomically distinct groups of putative neurosecretory cells found within the supra-oesophageal ganglion of the leech Macrobdella decora were studied by intracellular injection of horseradish peroxidase. All four groups have their own characteristic branching pattern while sharing the common feature of possessing primary branches that project into the dorsal commissure. Numerous secondary processes extend from these primary branches to terminate within the neural lamella, as well as within the neuropile. Electron microscopy of the regions into which these secondary processes project reveals numerous neurosecretory terminals. The data suggests that the midregion of the dorsal commissure constitues a neurohemal complex. These observations strengthen the argument that the four groups of identified cells are indeed neurosecretory.     

Isolation and amino acid sequence of crustacean hyperglycemic hormone precursor-related peptides.

The crustacean hyperglycemic hormone (CHH) is synthesized as part of a larger preprohormone in which the sequence of CHH is N-terminally flanked by a peptide for which the name CPRP (CHH precursor-related peptide) is proposed. Both CHH and CPRP are present in the sinus gland, the neurohemal organ of neurosecretory cells located in the eyestalk of decapod crustaceans. This paper describes the isolation and sequence analysis of CPRPs isolated from sinus glands of the crab Carcinus maenas, the crayfish Orconectes limosus and the lobster Homarus americanus. The published sequence of "peptide H" isolated from the land crab, Cardisoma carnifex, has now been recognized as a CPRP in this species. Sequence comparison reveals a high level of identity for the N-terminal region (residues 1-13) between all four peptides, while identity in the C-terminal domain is high between lobster and crayfish CPRP on the one hand, and between both crab species on the other. Conserved N-terminal residues include a putative monobasic processing site at position 11, which suggests that CPRP may be a biosynthetic intermediate from which a potentially bioactive decapeptide can be derived.