Some observations on the fine structure of the sinus gland of a land crab,Gecarcinus lateralis

The dilated axon endings of the sinus glands of the brachyuran crab, Gecarcinus lateralis, are filled with homogeneously dense granules, each granule being bounded by a delicate membrane. The granules are of two orders of magnitude: 0.05 to 0.1 micro and 0.15 to 0.2 micro in diameter. Each axon ending contains granules of a nearly uniform size. Endings with granules of the larger size range predominate. Non-nervous cells endogenous to the sinus gland are scattered among the nerve endings. The cell contours are irregular, and cytoplasmic processes ramify between endings. The axons are unmyelinated, having only thin limiting membranes, and they possess many neurofibrils. Granules in preterminal portions of the axons tend to lie at the periphery of the fiber, and in some cases in chains at the core of the fiber. The granules appear to be storage and release centers for neurosecretory substances or their precursors.     

Some Observations on the Fine Structure of the Sinus Gland of a Land Crab, Gecarcinus lateralis

The dilated axon endings of the sinus glands of the brachyuran crab, Gecarcinus lateralis, are filled with homogeneously dense granules, each granule being bounded by a delicate membrane. The granules are of two orders of magnitude: 0.05 to 0.1 µ and 0.15 to 0.2 µ in diameter. Each axon ending contains granules of a nearly uniform size. Endings with granules of the larger size range predominate. Non-nervous cells endogenous to the sinus gland are scattered among the nerve endings. The cell contours are irregular, and cytoplasmic processes ramify between endings. The axons are unmyelinated, having only thin limiting membranes, and they possess many neurofibrils. Granules in preterminal portions of the axons tend to lie at the periphery of the fiber, and in some cases in chains at the core of the fiber. The granules appear to be storage and release centers for neurosecretory substances or their precursors.     

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．     

Possible sites of release of neurosecretory granules in the sinus gland of the crayfish,Orconectes nais

Summary The sinus gland is a neurohemal organ located in the crayfish eyestalk and represents a storage site for neurohormones prior to their release into the circulation. The sinus gland contains three classes of electron dense, membrane-limited granules. Class 3 granules are the largest and most electron dense of the granules found in the sinus gland. Granules of class 1 are the smallest, while those of class 2 are the most abundant. Generally, all granules undergo similar changes during their release.Release of neurosecretory material may be initiated by a preliminary fragmentation of the parent granules into smaller granules. Following the formation of numerous smaller granules, these move to the plasma membrane and their limiting membrane apparently fuses with it thus releasing its contents into the external lamina which is applied to the sinusoidal surface of the axon terminals. Granule release does not appear to occur along the entire plasma membrane adjacent to the blood sinus but, instead, probably occurs only at specific active sites on the membrane. The active sites are characterized in part by an accumulation of small granules and clear vesicles against the cytoplasmic side of the plasma membrane. At the site of release of the neurohormone, there is often an accumulation of dense homogeneous material beneath the axolemma.Occasionally, axon endings filled with large, electron lucent vesicles are seen. These clear granules vary from 1150–1750 Å in diameter and often exhibit broken limiting membranes. Few small vesicles are seen near the plasma membrane of these endings; however, instances of invaginations of the plasma membrane occur. The significance of endings filled with clear granules is discussed.Supported by a grant from the National Research Council of Canada (No. A-4675).     

Neurosecretory granule formation in ligated axons: additional arguments for a local differentiation from a Golgi apparatus extension

The sorting domain for the different types of granules and small synaptic vesicles in neurosecretion is still largely a matter of debate. Some authors state that an exocytotic process has to precede granule formation. In previous studies, we favoured the idea that neurosecretory packages in terminals are assembled from axonal reticulum membranes simply by differentiation at the axon ending, the axonal reticulum being an extension of the Golgi apparatus. By ligating bovine splenic nerve, a de novo differentiation can be induced. After ligation, granules and granulo-tubular complexes appear. They were immunoreactive for SV2, VMAT2 and synaptobrevin II, which are all known to be highly enriched in large dense granules. Previously the granulo-tubular structures have already been recognized as precursor stadia of neurosecretory granules.It is concluded that at a de novo differentiation, a sorting out and aggregation is taking place of molecules typical for large dense granules. The small dense granules and tubules can be considered unripe, precursor forms of the large dense granules. All this occurs in the absence of signs of exocytosis. The present findings corroborate the view that granule formation occurs via local differentiation at an axon ending.     

Ultrastructure of neurosecretory granule exocytosis by crayfish sinus gland induced with ionic manipulations

Neurosecretory granule exocytosis from axon terminals in the crayfish (Orconectes virilis) sinus gland can be effected by alterations in intracellular ionic concentrations through modification of the bathing medium or by electrical stimulation. This may result in increased numbers of exocytotic profiles involving one granule (single exocytosis) or several granules (compound exocytosis), which we interpret as evidence of stimulated neurosecretion. Our results suggest that increased free intracellular Ca⁺⁺ together with a decrease in intracellular K⁺ are prerequisite for and sufficient to elicit increased exocytosis from sinus gland terminals. Similar release, stimulated by horseradish peroxidase, indicates that local surface permeability changes are involved. A minor response to high-K⁺-Ringer, and secretion via compound exocytosis, are uncharacteristic of cells with a neural ancestry.     

Neurosecretory centers from the eyestalk of Siriella armata M. Edw. (Crustacea: Mysidacea): ultrastructural variations during normal and experimentally inhibited molt cycle

Summary The ultrastructure of the medulla interna-medulla externa X-organ (MI-ME Xo)-sinus gland (SG) complex in the eyestalk of Siriella armata is described during the normal and the experimentally inhibited molt cycle. In the normal SG, four types of neurosecretory axon terminals, each containing distinguishable neurosecretory granules, can be described. Thus, type-2 granules are synthesized by G1 neurons forming the MI-ME Xo. The cell bodies and axonal endings of these cells in the sinus gland have been examined at the following molt stages: intermolt (stage C4), premolt (D0 and D2), and postmolt (A1, A2 and B). Changes in ultrastructure of the G1 cells have been monitored and correlated to inhibitions of the molt-and reproductive cycle produced by electrocauterization of the MI-ME Xo. The results obtained suggest that the neurosecretion from the G1 cells exerts a positive influence on molt and brood preparation. The occurrence of a distal group of G1 cells whose axons terminate at a different site from the SG suggests that the neural factors of the MI-ME Xo are diverse and control different physiological activities.     

Fine structure of the neurohemal sinus gland of the shore crab,Carcinus maenas,and immuno-electron-microscopic identification of neurosecretory endings according to their neuropeptide contents

Summary The sinus gland of the shore crab, Carcinus maenas, is a compact assembly of interdigitating neurosecretory axon endings abutting upon the thin basal lamina of a central hemolymph lacuna. Four types of axon endings are distinguishable by the size distribution, shape, electron density and core structure of their neurosecretory granules. One additional type of axon ending is characterized by electron-lucent vacuoles and vesicles. The axon profiles are surrounded by astrocyte-like glial cells. Various fixations followed by epoxy- or Lowicrylembedding were compared in order to optimize the preservation of the fine structure of the granule types and the antigenicity of their peptide hormone contents. By use of specific rabbit antisera, the crustacean hyperglycemic, molt-inhibiting, pigment-dispersing, and red-pigment-concentrating hormones were assigned to the four distinct granule types which showed no overlap of immunostaining. Epi-polarization microscopy and ultrathin section analysis of immunogold-stained Lowicrylembedded specimens revealed that immunoreactivity to Leu-enkephalin and proctolin is co-localized with moltinhibiting hormone immunoreactivity in the same type of granule. The size and core structure of the immunocytochemically identified granule types vary little with the different pretreatments but, in some cases, to a statistically significant extent. The present results are compared with those from earlier studies of sinus glands in different crustaceans. The methods of granule identification used in this study supplement the classical approach in granule typing; they are easier to perform and more reliable for the analysis of release phenomena in identified secretory neurons supplying the neurohemal sinus gland.     

A freeze-fracture study of membrane events during neurohypophysial secretion

Freeze-fracture was used to study the membrane events taking place during neurosecretory granule discharge (exocytosis) and subsequent membrane internalization (endocytosis) in axons of neurohypophyses from control and water-deprived rats. En face views of the cytoplasmic leaflet (P face) of the split axolemma reveal circular depressions that represent the secretory granule membranes fused with the plasma membrane during exocytosis. These depressions often contain granule core material in the process of extrusion into the extracellular space. The membrane surrounding some of the exocytotic openings shows a decreased number of intramembrane particles (mean diameter, 8 nm) which are elsewhere more numerous and evenly distrubuted on the fracture face. Endocytotic sites appear as smaller plasma membrane invaginations, with associated intramembrane particles. Moreover, such invaginations often contain large particles (mean diameter, 12 nm) that appear as clusters on en face views of the membrane leaflet. Quantitative analysis indicates that the number of exocytotic images increases significantly in glands from water-deprived rats. Concomitantly, the number of endocytotic figures per unit area of membrane is raised as is the number of clusters of large particles. The observations demonstrate that, in the neurohypophysis, it is possible to distinguish exocytosis morphologically from endocytosis and that the two events can be assessed quantitatively.     

Age-dependent neurosecretion release induced by dopamine in the corpora cardiaca of Blattella germanica (L.) (Dictyoptera : Blattellidae)

In addition to glial cells, intrinsic glandular cells and ordinary axons, the corpora cardiaca of Blattella germanica (L.) (Dictyoptera : Blattellidae) contain 4 types of neurosecretory fibers originating from the brain (types 1, 2, 3, and 4), which can be recognized on the basis of the size, form, and electron density of their neurosecretory granules. A comparative ultrastructural study of the corpora cardiaca from normal females and from dopamine-treated (1 μg) females has been carried out at different stages within the first ovarian cycle (freshly emerged: day 0; 2-day-old: pre-vitellogenesis; 4-day-old: beginning of vitellogenesis; 6-day-old: full vitellogenesis; 8-day-old: post-vitellogenesis, period of ootheca transport). Quantitative data on the exocytotic configurations observed in each type of fiber (1–4) have led to the following conclusions: (a) the exocytotic configurations in control specimens are too infrequent to prompt any inference about the dynamics of neurosecretion release in the different types of fibers; (b) dopamine treatment induces a stimulation of the exocytotis phenomenon, whose extent depends on the specimen age and on the type of fiber. Therefore, on days 2 and 6, dopamine: preferentially stimulates neurosecretion release in the fibers of types 3 and 4 respectively.     

Cellular and Subcellular Aquaporin-4 Distribution in the Mouse Neurohypophysis and the Effects of Osmotic Stimulation

Water channel aquaporin-4 (AQP4) is the most abundant water channel in the rodent brain and is mainly expressed in cerebral areas involved in central osmoreception and osmoregulation. The neurohypophysis is the release site of hypothalamic neurohormones vasopressin and oxytocin, which are involved in the regulation of the water balance. The authors investigated the cellular and subcellular distribution of AQP4 in the mouse neurohypophysis before and after chronic osmotic stimulation, using immunofluorescence microscopy and immunoperoxidase electron microscopy. They showed that AQP4 was abundant in the mouse hypophysis, mainly in the neural lobe. AQP4 was discontinuously distributed along pituicytes plasma membranes, in the dense neurosecretory granules and microvesicles of nerve endings and fibers, and along the luminal and abluminal membranes of fenestrated capillary endothelial cells. After chronic osmotic stimulation, AQP4 immunolabeling was enhanced. Taken together, these results suggest that AQP4 could be involved in the pituicyte sensor effect during osmoregulation, the modification and/or maturation mechanism of neurosecretory granules during neurohormone release, and the blood perfusion of the hypophysis.     

Ultrastructural organization of actin filaments in neurosecretory axons of the rat

Summary The ultrastructural organization of actin filaments was studied in the neurohypophysial system of the rat after heavy meromyosin (HMM) labeling. This structural pattern is characterized by (1) a straight arrangement of the filaments parallel to the axonal axis in the proximal nondilated parts of axons, (2) a central location within axonal dilatations, and (3) a higher concentration within axonal endings where the filaments form a complex three-dimensional network. The relationships of the filaments to other axonal structures and organelles was further studied by use of electron microscopic stereoscopy. The actin filaments frequently appear anchored to the axolemma with either polar arrangements of the arrowhead decoration (i) at structurally undifferentiated sites, and (ii) more particularly within perivascular endings, at sites with electron-dense thickenings. In all axonal divisions actin filaments are also found to bind to filamentous material surrounding the microtubules and to various organelles. Within the terminal portions of the axons actin filaments exhibit close relationships to neurosecretory granules and to the numerous smooth microvesicles found in this region. Such preferential relationships are particularly observed both in axon terminals and in pituicytes, with coated vesicles frequently binding actin filaments. In water-deprived rats, the concentration of actin filaments is conspicuously increased along the axons and more clearly in the axonal swellings and endings, where they form a more complex and interconnected network. These data are discussed in the light of a possible involvement of contractile proteins in the mechanisms of axonal transport and terminal release of neurosecretory products.     

Neurosecretion

Summary Protrusions of bounding membranes of neurosecretory granules, comparable to those demonstrated by Castel (1977) in the mammalian neurohypophysis, were observed under various experimental conditions in the corpora cardiaca of the insects Leucophaea maderae and Periplaneta americana. Electrical stimulation in vitro of the nervus corporis cardiaci I, which elicited a marked rise in the amount of neurohormone discharged, as determined by bioassay, also yielded a significantly larger number of membrane protrusions than were observed in unstimulated controls. However, no comparable response was obtained in glands subjected to stimulation of hormone release by exposure to serotonin or high potassium concentrations. On the other hand, membrane protrusions were numerous under certain conditions not expected to stimulate neurohormone release, i.e., in tissue exposed to a zinc iodide mixture without prior fixation. The present results support the conclusion drawn by Castel that these configurations appear to be related to the process by which neurosecretory material is discharged. Too transient to be much in evidence under physiological conditions, they become more prominent not only after appropriate acceleration of the rate of release, but also when such membrane arrangements are frozen by procedures that interfere with the regular milieu.Dedicated to Professor Pierre Drach in recognition of his many contributions to arthropod biology. — Supported by research grants NB-05219, NB-00840, and 5 PO1-NS-07512 from the U.S.P.H.S. and by N.S.F. grant BMS74-12456     

中华绒螯蟹窦腺的显微和超微结构

借助光学和电子显微镜观察了养殖河蟹 1龄蟹种、早熟蟹种和 2龄成蟹窦腺的形态结构和神经分泌物质释放方式。河蟹窦腺位于眼柄视神经节内髓与终髓交界处背侧 ,活体为乳白色 ,扁球状 ,大小约为 0 5 5mm×0 45mm× 0 2 3mm。窦腺呈囊状 ,腺体壁由膨大的神经分泌细胞末梢和胶质细胞组成 ,神经末梢内充满电子致密的分泌颗粒。根据颗粒的大小、形态和电子致密度等特征 ,区分出 6种不同类型的神经分泌末梢。河蟹窦腺中的神经分泌物质以胞吐作用方式释放 ,一些现象表明 ,神经胶质细胞参与神经分泌颗粒的释放。 1龄蟹种、早熟蟹种和 2龄成蟹窦腺的形态、结构无明显差异 ,但神经激素颗粒释放情况明显不同 ,从形态结构上证实了窦腺对养殖河蟹性腺发育的调控作用。     

The ultrastructure of the sinus gland of Carcinus maenas (Crustacea: Decapoda)

Summary The sinus gland of Carcinus maenas consists of the swollen axonal endings of the neurosecretory cells of the major ganglia and acts as a storage release centre for the membrane bound neurosecretory material. These neurosecretory granules fall into five different types based on size and electron density. Their contents are released by exocytosis of the primary granules or smaller units budded from the primary granules.I thank Professor E. Naylor for his constant advice and Professor E. W. Knight-Jones, Department of Zoology, University College, Swansea, for the provision of laboratory facilities. I am grateful to the Science Research Council for the financial support. Finally, I thank the Electron Microscope Unit, Southampton General Hospital, where the work was completed.     

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.     

The neurosecretory system of the eyestalk of Carcinus maenas (Crustacea: Decapoda)

The optic ganglia neurosecretory cells of male and female Carcinus maenas during intermoult are distinguishable into six types based on size, location, appearance and method of secretory material release from the perikaryon. Release occurs via the sinus gland and also, in one case, directly into blood capillaries among the neurosecretory cells themselves. The sinus gland consists of axonal extensions of the neurosecretory cells; no secretory granules are produced there and nuclei observed between the axonal endings are those of ill-defined glial cells.     

Neurosecretion of the mediodorsal cells of the central nervous system of the snail Helisoma duryi

Summary The neurosecretory mediodorsal cells that produce a putative growth hormone of the snail Helisoma duryi were studied in fast-growing virgin snails and in slow-growing reproducing snails. There are about 60 mediodorsal cells in clusters on each side of the cerebral commissure of the central nervous system, and they contain dense-cored granules which are 100–200 nm in diameter. The cells of virgin snails have dense Golgi bodies, scattered ER cisternae, and few granules, while those of reproducing snails have pale Golgi bodies, stacked ER cisternae, and numerous granules. Thus the mediodorsal cells of the virgin snails appear to be more active synthetically than those of the reproducing snails. The cells near the endocrine dorsal bodies contain many dorsal body precesses in their membrane interdigitations. There are junction-like interactions between some of the interdigitations. Gap junction-like contacts are seen between mediodorsal cells and glial cells. The axon endings of the mediodorsal cells at the neurohemal area in the labial nerve show more release profiles in virgin snails than in reproducing snails. A daily pattern of release has been observed in reproducing snails, and rates of release are higher in the evening than in the morning.     

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.     

The desmosome: Fine structural studies with freeze-fracture replication and tannic acid staining of sectioned epidermis

Desmosomes of larval and post-metamorphic newt epidermis have been studied by freeze-fracture replication both with and without prior glutaraldehyde fixation. Characteristic particles of a diameter (70-130 A) similar to that of typical membrane associated particles are found clustered on the exposed internal faces of adherent desmosomal membranes. They remain attached to the B-face in unfixed material, but occupy the desmosomal A-face after fixation. Membrane associated particles of nondesmosomal surfaces are found predominantly on the A-face in both fixed and unfixed epidermis. Suitably oriented replicas of unfixed desmosomes reveal profiles of apparent fine filaments extending from the region of tonofilament loops through the desmosomal plaque to traverse the cytoplasmic leaflet of the plasmalemma. They can be traced onto the B-face. Their position correlates to fine linear profiles noted in tannic acid/glutaraldehyde-fixed and sectioned desmosomes. The possibility that these represent a mechanism for anchorage of tonofilaments to the plaque and to the membrane is discussed. These and other fine structural features are compared and contrasted to the properties of hemidesmosomes described in the preceding report.