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．     

Ultrastructure and distribution of identified neurosecretory terminals in the sinus gland of the terrestrial isopod Oniscus asellus

An ultrastructural study of the sinus gland of the terrestrial isopod, Oniscus asellus, reveals that this structure consists of two regions: the bulb, which is attached by a narrow stalk to the optic lobe, and the lateral extension, which extends from the bulb along the optic tract to the compound eye. The bulb has a distal region containing only neurosecretory terminals, and a proximal region containing terminals, glial cells, and axons that give rise to the distally located terminals. In total, the sinus gland contains five types of terminals which can be distinguished by their location and the appearance of their neurosecretory granules. Three terminal types are located in the bulb and two in the lateral extension. The size of the terminals in the bulb varies among the three types, but the number of terminals is approximately the same for each type. Conversely, the two terminal types in the lateral extension are similar in size, but differ in number. Axons of two terminal types in the bulb can be traced to the central region of the protocerebrum; axons of one terminal type in the bulb and of terminals in the lateral extension can be traced to the optic lobe.     

The ultrastructure of the sinus gland of the crayfish Astacus leptodactylus (Nordmann)

Summary An ultrastructural study of the sinus gland of the crayfish Astacus leptodactylus demonstrates that this gland is mainly composed of glial cells, axons and axon terminals. On the basis of the size, shape and electron density of the neurosecretory granules, we could distinguish five different types of axon terminals.     

中华绒螯蟹窦腺神经末梢及X-器官神经分泌细胞的类型

在电子显微镜下观察了性未成熟的中华绒螯蟹黄蟹的窦腺及X－器官的超微结构。X－器官位于眼柄神经节终髓的腹外侧,与窦腺位置斜相对,窦腺主要由神经分泌细胞的末梢和胶质细胞组成。神经末梢含有大量的膜结构包围的颗粒、线粒体、粗面内质网和许多电子透明的小泡,末梢外周有时可见指状突起。依据颗粒的大小、形状、电子致密度以及胞质特征,可区分出6种类型的窦腺神经末梢及7种X－器官神经分泌细胞。观察了末梢中神经分泌颗粒的胞吐作用方式的释放过程,并且尝试对窦腺不同末梢中的颗粒及X－器官神经分泌细胞中的颗粒作了比较,发现二者之间具有较好的对应性,即电子致密度无大的变化,形态特征相似,只是大小稍有增加。     

Neurosecretion in the sinus gland of the fiddler crab,Uca pugnax

The ultrastructure of the sinus gland of the fiddler crab, Uca pugnax, was investigated and found to be similar to that in other crustaceans. Five types of neurosecretory axon terminals were tentatively identified on the basis of the size, shape, and electron density of granules within the axons. Release of neuro-secretory material appears to be by exocytosis.     

Depletion of neurosecretory granules and membrane retrieval in the sinus gland of the crab

Summary Ultrastructural aspects of hormone release from the sinus gland of the crab Carcinus maenas, have been studied by incubation of glands in vitro (i) in high potassium-containing media to induce hormone release; (ii) in a high potassium-containing calcium-free medium in which depolarisation but no hormone release would be expected; and (iii) in control saline. Uptake of horseradish peroxidase into subcellular organelles was also studied.Many neurosecretory granules could be found in the nerve terminals but, in contrast to mammalian neurosecretory systems, structures resembling microvesicles were extremely scarce. High potassium stimulation in the presence of calcium caused an 18 % loss of granules from the nerve terminals associated with images of single and multiple exocytosis. It further caused an increase in vacuoles which could have accounted for 33 % of the membrane of the granules exocytosed. After incubation in high potassium-containing, calcium-free media there was no evidence either of exocytosis of granules or of an increase in the vacuole population. The population of sparse microvesicle-like structures was not significantly altered by incubation in either high potassium medium. Horseradish peroxidase reaction product could be found only in vacuoles of tissues stimulated by high potassium concentrations in the presence of calcium. It is concluded that this depolarising stimulus produces, in the presence of calcium, the release by exocytosis of about one sixth of all the granules in the sinus gland, and that vacuoles are the organelle responsible for the recapture of membrane after the exocytosis.     

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。     

Ultrastructural appearance of neurosecretory granules in the sinus gland of the crab after different fixation procedures

Summary The appearance of neurosecretory granules in the crab sinus gland was studied after fixation at different pHs. Whereas at pH 7.0 the neurosecretory granules were pleomorphic with respect to electron density, at pH 5.0 or 6.0 all the granules remained electron dense. The possible role of maturation as an explanation of this observation is discussed.ERA 493 CNRS     

Autoradiographic evidence that transport of newly synthesized neuropeptides is directed to release sites in the X-organsinus gland of Cardisoma carnifex

Summary Sections of isolated X-organ — sinus gland neurosecretory systems of the crab, Cardisoma carnifex, were studied by light-and electron microscopy with conventional and autoradiographic procedures. The somata only were exposed to a pulse of ³H-leucine (5 min-5 h) and the entire system perfused with chase medium for various times (1–72 h) before fixation. Within 1 h, radiolabel is concentrated in Golgi complexes and nascent granules of both large and small somata. Label is undetectable in the terminal region following a 10 h chase. It is found in the nerve tract near terminals at 14 h, while after a 19 h chase, label is concentrated in terminal profiles abutting blood sinuses of the neurohemal organ (sinus gland). Following a 72 h chase, label is distributed throughout the terminal region. Each of the six morphologically distinguishable terminal types shows labelling. These observations show that the vast majority of newly formed granules are initially transported to release sites of the perisinus terminals. They thus provide an explanation for previous analyses indicating that newly synthesized peptides are preferentially secreted.     

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.     

Ultrastructural changes in isolated peptidergic nerve terminals induced by digitonin permeabilization and K+ stimulation in the sinus gland of the crab,Cardisoma carnifex

Summary The preparation of isolated peptidergic nerve terminals from the sinus gland (a neurohemal organ) of the crab (Cardisoma carnifex) is described. In this species the nerve endings can have diameters up to 30 m. They release neurosecretory material as judged by the decrease in the volumetric density of granules upon depolarization with potassium. Similar results were obtained after permeabilization of the nerve terminals with digitonin, but only in the presence of micromolar concentrations of calcium. This preparation should prove useful in correlating electrical events with other cellular processes involved in stimulus-secretion coupling.     

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.     

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     

Two-dimensional gel electrophoresis of neurosecretory polypeptides in crustacean eyestalk

Summary A knowledge of the precise location of neurosecretory cell bodies is a prerequisite for studying the synthesis and subsequent processing of neurosecretory polypeptides stored in axon terminals comprising the sinus gland of the crustacean eyestalk. Structural data establish that the X organ in the medulla terminalis ganglion (mtXo) of the crayfish eyestalk represents 90–95% of the cell bodies actively synthesizing neurosecretory vesicles stored in the neurohemal sinus gland (Fig. 4). These cell bodies transport rather than accumulate neurosecretory vesicles as judged by light and electron microscopy suggesting that neurohormone precursors, but not subsequently stored products, might be found there. Two-dimensional electrophoresis of sinus gland and mtXo homogenates support this hypothesis. In crayfish, lobster and blue crab, stained two-dimensional gels display a number of sinus gland-specific polypeptides whose high concentrations and low molecular weights are consistent with stored neurosecretory material (Table 1). These neuropeptides are not detected in mtXo homogenates or in non-neurosecretory neural tissue with Coomassie Blue staining. By decreasing the porosity of the second dimension, the two-dimensional gel technique has proven useful in determining the molecular weights of a variety of neurosecretory polypeptides stored in the sinus gland. The crayfish and lobster store several polypeptides of ca. 7,000 Dalton. The blue crab stores two 7,000, two 13,000 and three 20,000 Dalton sinus gland polypeptides detected in stained gels.Following a 4 h incubation in³H-labelled amino acids, predominantly labelled 19,000–21,000 Dalton polypeptides are detected in crayfish mtXo homogenates by 2-D gel autoradiography (Fig. 12). Concomitantly, three labelled polypeptides (4,000–10,000 Dalton) appear in the sinus gland (Fig. 13), suggesting that they are cleaved from 19,000–21,000 Dalton molecules. This study is the first to examine neurosecretory precursors and their putative cleavage products in the Crustacea.Abbreviations mtXo medulla terminalis X organ - NEPHGE non-equilibrium pH gradient electrophoresis - PAF paraldehyde fuchsin - SDS sodium dodecylsulfate     

Localization of crustacean hyperglycemic hormone (CHH) in the X-Organ sinus gland complex in the eyestalk of the crayfish,Astacus leptodactylus (Nordmann, 1842)

The eyestalk of Astacus leptodactylus is investigated immunocytochemically by light, fluorescence, and electron microscopy, using an antiserum raised against purified crustacean hyperglycemic hormone (CHH). CHH can be visualized in a group of neurosecretory perikarya on the medualla terminalis (medulla terminalis ganglionic X-organ: MTGX), in fibers forming part of the MTGX-sinus gland tractus, and in a considerable part of the axon terminals composing the sinus gland. Immunocytochemical combined with ultrastructural investigations led to the identification of the CHH-producing cells and the CHH-containing neurosecretory granule type.     

Exocytosis of neurosecretory granules from the crustacean sinus gland in freeze-fracture

Exocytosis is clearly shown in freeze-fracture preparations to be the mechanism for neurosecretion granule release from axon endings in the crayfish sinus gland. The cytoplasmic leaflet (A-face) of axon ending membrane is characterized by randomly situated depressions representing invaginations of the axolemma, which are in contact with limiting membranes of neurohormone granules in the subjacent cytoplasm. The extracellular leaflet (B-face) of the axolemma at release sites exhibits complementary volcano-shaped protrusions which are cross-fractures through necks of channels formed by invaginating plasma membrane in contact with underlying neurosecretion granules. Structural variation in B-face protrusions is consistent with a spectrum of exocytotic profiles in various stages of formation, and with granules at different stages of passage out of the endings. Evidence in this study suggests that formation of exocytotic structures may begin by alteration of axon membrane structure at the neurosecretory ending-hemolymph interface prior to contact of the neurohormone granules with the axolemma. Limiting membranes of neurosecretory granules exhibit protrusions which appear to interconnect granules adjacent to release sites and to attach granules to the axolemma. Freeze-fracture is clearly shown to be an invaluable tool for monitoring the degree of exocytosis exhibited by sinus glands under normal conditions and under experimental acceleration of hormone release. This technique is capable therefore, of detecting slight increases in numbers of exocytotic profiles much more quickly and accurately than the examination of random thin sections.     

Ultrastructure of retrocerebral complex of the earwig, Euborellia annulipes, and rôle of aorta as a neurohaemal organ

The ultrastructure of the retrocerebral endocrine-aortal complex of the earwig, Euborellia annulipes has been studied. The space between the inner and outer stromal layers of the aorta is occupied by numerous axon terminals and pre-terminals containing large electron dense granules (NS-I) of approximately 100 to 220 nm and a few axon terminals having small granules (NS-II) of approximately 40 to 90 nm; the former appear to belong to medial neurosecretory A-cells, and the latter to the B-cells of the brain. The corpora cardiaca consist of intrinsic cells with mitochondria and multivesicular bodies. Granules of type NS-II and NS-III are observed in the axon terminals and pre-terminals in the corpora cardiaca. The NS-II are identical to those found in the aorta and are probably the secretions of the lateral B-cells. Granules of type NS-III are 40 to 120 nm and electron dense, and are intrinsic in origin. Similar granules occur in the intrinsic cells of the corpora cardiaca. E M studies have confirmed the rôle of the aorta as a neurohaemal organ for the medial neurosecretory cells, and the corpora cardiaca for the lateral neurosecretory cells of the brain. The corpora cardiaca also act as a reservoir for the intrinsic secretion. The corpus allatum is a solid body consisting of parenchymal cells with prominent nuclei, mitochondria, and endoplasmic reticulum. In between its cells are occasional glial cells and also neurosecretory as well as non-neurosecretory axons. The gland is devoid of A-cell NSM.     

Intralamellar neurohemal complexes in the cerebral commissure of the leech Macrobdella decora (Say, 1824): An electron microscope study

Electron microscopy of the cerebral ganglionic commissure of the leech Macrobdella decora (Say, 1824) revealed numerous neurosecretory axons terminating in the neural lamella of both the inner and outer capsules, and in the neural lamella deep within the neuropile. The proximal protions of the terminals, with an investment of glial tissue, contain either numerous large homogeneously electron dense granules, or numerous large granules of varying electron density. The distal portions, often devoid of glia, display numerous infoldings, omega profiles, and electron dense focal sites, and contain numerous neurosecretory granules, small lucent vesicles, and, occasionally, acanthosomes. Statistical analysis of the size distribution and morphology of the neurosecretory granules showed that in many individual terminals the granules are not significantly different from those seen within four groups of neurosecretory cells found in the cerebral ganglion. These terminals, because of their diffuse nature, probably represent a neurohemal complex of a primitive nature. The term “intralamellar complexes” is proposed to describe the form and location of these neurosecretory terminals.     

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.     

Differential localization of leu-enkephalin and hyperglycemic hormone in axon terminals of the sinus gland of the crabsCarcinus maenas,eriocheir sinensis,andUca pugilator

Summary Leu-enkephalin containing secretory granules were demonstrated in axon terminals of immunogoldlabeled electron-microscopic sections of the sinus gland of three brachyuran crustaceans. These granules have a diameter of 120+-15 nm and differ in electron density from those located in adjacent terminals containing hyperglycemic or molt-inhibiting hormone. These neurohormones do not show co-localization with leu-enkephalin. The cross-reactivity of leu-enkephalin antiserum with met-enkephalin is less than 1%. The sinus glands of the three species examined show no immunoreactivity for FMRF-amide. A modulatory activity of endogenous enkephalin by paracrine mechanisms is suggested.