Immuno-electron microscopy of formation,degradation and exocytosis of the ovulation neurohormone in Lymnaea stagnalis

Summary The cerebral caudodorsal cells (CDC) of the pulmonate snail Lymnaea stagnalis are involved in the control of egg laying and associated behaviour by releasing various peptides. One of these is the ovulation hormone (CDCH). The cellular dynamics of this peptide have been studied using an antiserum raised to a synthetic portion of CDCH comprising the 20–36 amino acid sequence. With the secondary antibody-immunogold technique, specific immunoreactivity was found in all CDC. Rough endoplasmic reticulum and Golgi apparatus showed very little reactivity as did secretory granules that were in the process of being budded off from the Golgi apparatus. However, secretory granules that were being discharged from the Golgi apparatus, were strongly reactive. Secretory granules within lysosomal structures revealed various degrees of immunoreactivity, indicating their graded breakdown. Large electrondense granules, formed by the Golgi apparatus and thought to be involved in intracellular degradation of secretory material, were only slightly reactive. In the axon terminals secretory granules released their contents into the haemolymph by the process of exocytosis. The exteriorized contents were in most cases clearly immunopositive.The possibility has been discussed that CDCH is cleaved from its polypeptide precursor within secretory granules during granule discharge from the Golgi apparatus; subsequently, the mature secretory granules would be transported towards the neurohaemal axon terminals where they release CDCH into the haemolymph. Superfluous secretory material would be degraded by the lysosomal system including the large electron-dense granules.     

Immuno-electron microscopy of sorting and release of neuropeptides in Lymnaea stagnalis

Summary The cerebral caudodorsal cells of the pulmonate snail Lymnaea stagnalis control egg laying and egglaying behavior by releasing various peptides derived from two precursors. The biosynthesis, storage, intracellular breakdown and release of three caudodorsal cell peptides were studied by means of immuno-electron microscopy using antisera raised to fragments of these peptides: (1) Caudodorsal Cell Hormone-I (CDCH-I; derived from precursor I), (2) Caudodorsal Cell Hormone-II (CDCH-II; from precursor II), and (3) -Caudodorsal Cell Peptide ( CDCP; from both precursors). After affinity purification of the antisera, the specificity of the sera was confirmed with dotting immunobinding assays. From the ultrastructural immunocytochemical data it has been concluded that the precursor molecules are cleaved at the level of the Golgi apparatus after which the C-terminal parts (containing CDCP) and N-terminal parts (containing CDCH-I or CDCH-II) are sorted and preferentially packaged into large electron-dense granules (MD 150 nm), respectively. Very probably, the content of the large electron-dense granules is degraded within the cell body. The immunoreactivity of the secretory granules increases during discharge from the Golgi apparatus, indicating further processing. At least a portion of the secretory granules contains all three peptides, as shown by double and triple immunopositive stainings whereas other granules appear to contain only one or two of these peptides. The caudodorsal cells release multiple peptides via exocytosis from neurohemal axon terminals into the hemolymph and from blindly ending axon collaterals into the intercellular space of the cerebral commissure (nonsynaptic release).     

Ultrastructural demonstration of exocytosis of neural,neuroendocrine and endocrine secretions with an in vitro tannic acid (TARI-) method

Summary The release of neural, neuroendocrine, and endocrine secretory products by exocytosis was ultrastructurally studied by means of tissue incubation in Ringer containing tannic acid (Tannic Acid Ringer Incubation-method; TARI-method), followed by conventional fixation. Tannic acid strongly enhances the electron density of extracellular (secretory) substances. During TARI-treatment of tissues exocytosis proceeds, but the exteriorized contents of the secretory granules are immediately fixed by tannic acid and do not diffuse away into the extracellular space. In this way detection of exocytosis is markedly facilitated since the number of exocytosis phenomena visible at the ultrastructural level considerably increases with progressing incubation time. Studies of the central nervous system of the mollusc Lymnaea stagnalis show that the occurrence of exocytosis during TARI-treatment is calcium-dependent. With the TARI-method exocytosis has been clearly demonstrated in a variety of structures (endocrine cells, neurohaemal axon terminals, synapses) of L. stagnalis, the insect Locusta migratoria, and the rat, including cell types where exocytotic release had not been shown before.     

Immuno-localization of ferritin polypeptides in oocytes and somatic tissue of the freshwater snails Lymnaea stagnalis L. and Planorbarius corneus L.

Summary Antibodies were raised in rabbits against the 19000 Mr and 24000 Mr polypeptides of snail ferritin from Lymnaea stagnalis L. Anti-24000 Mr polypeptide antibodies were purified by an affinity-purification step and were made monospecific for their antigen by preabsorption with the 19000 Mr antigen. These purified antibodies were then used for in situ detection of their respective antigens by the indirect immunofluorescence method. The 19000 Mr polypeptide was found widely distributed in tissues of both pulmonate snails investigated (Lymnaea stagnalis L. and Planorbarius corneus L.) with the most intense antigen-directed fluorescence in certain connective tissue cells, secretory cells of the midgut gland and Sertoli cells and epithelia of the gonadal acini. In contrast, the 24000 Mr polypeptide could be detected only in yolk platelets of vitellogenic oocytes. The results indicate that yolk and somatic cell ferritins differ in immunoreactivity and structure and, accordingly may differ in function.This investigation was supported by the Deutsche Forschungsgemeinschaft. I greatly appreciate the advice given to me by Drs. U. Mays and V. Riedel, Münster.     

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.     

Immunohistochemical localization of some vertebrate-like neuropeptides (SP,NPY, CGRP,CCK) in the central nervous system of the freshwater snail Planorbarius corneus

Summary The localization of the vertebrate-like neuropeptides substance P (SP), neuropeptide Y (NPY), calcitonin gene-related peptide (CGRP), and cholecystokinin (CCK8) in the central nervous system of the freshwater snail Planorbarius corneus has been studied using specific antisera and single and double immunohistochemistry. A widespread but precise distribution of immunore-activity (IR) in neurons and fibers of almost all the ganglia is observed for each antiserum. A comparison of the IR with classical neurosecretory staining (AB/AY) shows a partial overlap only for CGRP and CCK8. Whereas CGRP-IR is found in some Yellow Cells in the left parietal ganglion, CCK8-IR is found in Yellow Green, Green and Brown Cells in the viscero-parietal complex. Studies employing double-sequential methods or simultaneous immunofluorescence have shown that, with regard to the tested antisera, CCK8- and NPY-IR are colocalized in a limited number of cells and fibers in the buccal and visceral ganglia, whereas CCK8- and SP-IR are colocalized only rarely in neurons in the left cerebral ganglion. The possible roles in P. corneus of the investigated neuropeptides and the contribution that molluscan models may offer to the knowledge of the basic properties of neuropeptides are discussed.     

Structure of visual pathways in the nervous system of freshwater pulmonate molluscs

Central nervous system of freshwater pulmonate molluscs Lymnaea stagnalis and Planorbarius corneus was stained using retrograde transport of neurobiotin in the optic tract fibers. In both species, perikarya and fibers of the stained neurons are found in all ganglia except the buccal ones. Afferent fibers of the optic nerve form dense sensory neuropil located in relatively small volume of cerebral ganglia. Typical neuronal groups sending their processes into the optic nerves of ipsilateral and contralateral body halves are described. Among them, neurons of visceral and parietal ganglia innervating both eyes concurrently as well as sending projections into peripheral nerves are revealed. These neurons, supposedly, have a function to integrate sensory signals, which may be a basis for regulation of light sensitivity of retina and functioning of peripheral organs. Bilateral links of the molluscan eye with the pedal ganglia cells and statocysts are found, which is, likely, a structural basis of certain known behavioral patterns related to stimulation of visual inputs in the studied gastropod molluscs.     

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．     

Morphological studies of possible neuroendocrine structures in Helisoma tenue (Gastropoda: Pulmonata)

Summary Studies of possible neuroendocrine structures in the pulmonate gastropod Helisoma tenue show that cerebral fuchsinophilic neurons with electron-dense granules (mean diameter 1,500 Å) apparently release their secretory content in an intercerebral commissure neurohemal area near the mediodorsal bodies (MDB) or in the median labial nerve neurohemal area.The MDB cells have axon-like processes which branch and end at the cerebral surface, separated by a thin capsule from the cerebral fuchsinophilic cells. The presence of granules (mean diameter 800 Å) in the terminals of the MDB cells suggests cell body origin, distal transport and release of the granular secretory material. The secretory product may have an influence on cerebral fuchsinophilic neurons.Electron microscopy reveals the presence of granules of different sizes and densities in expanded neurites at the periphery of the intestinal nerve of the visceral ganglion which may indicate the presence of a neurohemal area. However, the granules in the intestinal nerve neurites and in the visceral ganglion fuchsinophilic cells are similar to granules found in the heart which also suggests that the granules may carry a neurotransmitter.This study was supported by NTH traineship USPHS T1 CA 5045 and NSF grant GB-6424X. The author would like to thank Professor Howard A. Bern for guidance and support during the course of this work, Mr. John Underhill and Mr. Albert Blaker for photographic assistance, and Mrs. Emily Reid for preparation of the diagram in Fig. 16.     

Co-localization of the adipokinetic hormones I and II in the same glandular cells and in the same secretory granules of corpus cardiacum of Locusta migratoria and Schistocerca gregaria

Summary The immunocytochemical reactivity of the glandular cells of the corpus cardiacum (CCG-cells) of Locusta migratoria and Schistocerca gregaria was investigated at the electron-microscopic level, using the protein A-gold method, with three antisera against fragments of the adipokinetic hormones AKH I and AKH II. This combination of antisera permitted discrimination between anti-AKH I and anti-AKH II immunoreactivity. Fixation in a mixture of 2% glutaraldehyde and 2% formaldehyde, in combination with low-temperature embedding in Lowicryl K₄M, produced the highest and most consistent selective immunogold labelling of the secretory and ergastoplasmic granules. All secretory granules in all CCG-cells investigated possessed a distinct anti-AKH I-immunopositive reaction, whereas most secretory granules showed a weaker anti-AKH II immunoreaction. Ergastoplasmic granules reacted similar to the secretory granules. The average immunolabelling of the secretory granules was higher in the processes than in the cell bodies of the CCG-cells. The results in Schistocerca gregaria were essentially similar to those in Locusta migratoria. It is concluded that (i) the individual CCG-cells synthesize AKH I as well as AKH II; (ii) these hormones coexist in the same ergastoplasmic and secretory granules; and (iii) these granules contain a higher content of AKH I than AKH II.     

Further Evidence that Synaptic and Synaptoid Vesicles Constitute a Single Category of Inclusions: Dense-cored Synaptic and Synaptoid Vesicles in Helix Discharge their Contents by Exocytosis

In the pulmonate mollusc Helix, neurosecretory cells have perikarya that form neurohaemal complexes peripherally beneath the inner surface of the neural lamella and give rise to axons with varicosities in the neuropile. Two categories of secretory inclusions are present throughout the cytoplasm and these accumulate adjacent to sites of release. Secretory granules invariably have electron-dense contents, whereas smaller vesicles have fairly lucent contents following fixation in O_sO₄, but are dense-cored in material fixed initially with aldehyde. Vesicles (‘synaptic vesicles’) at central sites appear identical to those (‘synaptoid vesicles’) at peripheral, neurohaemal locations. At both neurohaemal and central sites, both granules and vesicles discharge their contents by exocytosis, this process being most clearly visualized in tissues treated with tannic acid.     

Investigations of the Diurnal Activity of the Endocrine Dorsal bodies in Helix aspersa

Summary

The activity of the endocrine dorsal bodies (DB) of the adult land snail Helix aspersa living in the field shows striking fluctuations during a 24 hr cycle. Quantitative electron microscopical data revealed that the number of secretory granules, the volume of the Golgi apparatus and the number of Golgi saccules containing electron-dense material were maximal at 1 am and minimal at 1 pm. The use of tannic acid indicated the exocytosis of secretory material was intense around 1 pm and only moderate at 1 am. The results suggest that, under natural conditions, the DB have a diurnal rhythm of activity, packaging secretory material into secretory granules mainly during the night and releasing it during the afternoon.     

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.     

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.     

‘Neurosecretion’ by a classic cholinergic innervation apparatus

Summary Nerve terminals forming typical synapses with adrenal chromaffin tissues have been examined in the goldfish, frog (Rana pipiens), hamster and rat. Presumptive secretory inclusions present in the terminals are of two distinct types. Electron-lucent synaptic vesicles 30–50 nm in diameter are densely clustered adjacent to membrane thickenings and presumably discharge their contents into the synaptic clefts. Secretory granules (i.e. large dense-cored vesicles) 60–100 nm in diameter are more abundant in other parts of the terminals. Sites of granule exocytosis have been observed in each of the animals investigated. They are usually encountered within apparently undifferentiated areas of plasmalemma and only rarely occur within synaptic thickenings. Granule exocytosis from within synaptic terminals and chromaffin gland cells is most readily observed in specimens exposed, prior to fixation, to saline solutions containing both tannic acid, and 4-aminopyridine and/or elevated levels of K⁺. These findings show that the pattern of secretory discharge, involving both synaptic and non-synaptic release, which is widespread in invertebrate central nervous systems, is also characteristic of vertebrate, peripheral cholinergic terminals.     

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.     

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.     

Segmental peptidergic innervation of abdominal targets in larval and adult dipteran insects revealed with an antiserum against leucokinin I

Summary An antiserum against the cockroach neuropeptide leucokinin I (LKI) was used to study peptidergic neurons and their innervation patterns in larvae and adults of three species of higher dipteran insects, the flies Drosophila melanogaster, Calliphora vomitoria, and Phormia terraenovae, as well as larvae of a primitive dipteran insect, the crane fly Phalacrocera replicata. In the larvae of the higher dipteran flies, the antiserum revealed three pairs of cells in the brain, three pairs of ventro-medial cells in the subesophageal ganglion, and seven pairs of ventro-lateral cells in the abdominal ganglia. Each of these 14 abdominal leucokinin-immunoreactive (LKIR) neurons innervates a single muscle of the abdominal body wall (muscle 8), which is known to degenerate shortly after adult emergence. Conventional electron microscopy demonstrates that this muscle is innervated by at least one axon containing clear vesicles and two axons containing dense-cored vesicles. Electronmicroscopical immunocytochemistry shows that the LKIR axon is one of these two axons with dense-cored vesicles and that it forms terminals on the sarcolemma of its target muscle. The abdominal LKIR neurons appear to survive metamorphosis. In the adult fly, the efferent abdominal LKIR neurons innervate the spiracles, the heart, and neurohemal regions of the abdominal wall. In the crane fly larva, dorso-medial and ventrolateral LKIR cell bodies are located in both thoracic and abdominal ganglia of the ventral nerve cord. As in the larvae of the other flies, the abdominal ventrolateral LKIR neurons form efferent axons. However, in the crane fly larva there are two pairs of efferent LKIR neurons in each of the abdominal ganglia and their peripheral targets include neurohemal regions of the dorsal transverse nerves. An additional difference is that in the crane fly, a caudal pair of LKIR axons originating from the penultimate pair of dorso-median LKIR cells in the terminal ganglion innervate the hindgut.     

Characterisation of multiple immunoreactive neurons in the central nervous system of the pond snail Lymnaea stagnalis with different fixatives and antisera adsorbed with the homologous and the heterologous antigens

Summary In the central nervous system of the pond snail Lymnaea stagnalis a large number of elements (cells and fibers) can be identified with antisera (a-FM) to the molluscan cardioactive tetrapeptide FMRFamide (Phe-Met-Arg-Phe-NH₂). Of these elements some are also reactive to antivasotocin (a-VT) and/or anti-gastrin (a-Gas). These observations suggest that the a-FM positive elements belong to more than one type. Previous results had already indicated that the immunoreactivity of many a-FM positive cells is influenced by the type of fixation. Taking into account the effects of three fixatives on the reactivity of the cells, and their staining characteristics with the two other antisera used, 8 a-FM positive types could be distinguished.Homologous and heterologous adsorptions were carried out to test the specificity of a-FM, a-VT and a-Gas. After homologous adsorptions no staining was obtained. After heterologous adsorptions only part of the multiple staining cells were identified. This indicates that in a-FM, a-VT and a-Gas in addition to (more) selective IgG molecules, less specific IgG molecules occur that can bind to other peptides than those used to raise the antisera (cross-reaction). The (more) selective IgG molecules in a-FM bind to 6 of the a-FM positive types, suggesting that in L. stagnalis a family of FMRFamide-like substances occurs. This conclusion is sustained by results obtained with a-FM adsorbed with fragments of FMRFamide. It appeared that the less selective IgG molecules in a-FM, a-VT and a-Gas cause the multiple stainings of those cells that remain unstained with an antiserum adsorbed with a heterologous antigen. Multiple staining, which can not be abolished by heterologous adsorption, probably is due to the binding of (more) selective IgG molecules to different antigenic determinants present in the cells.The results show that unexpected cross-reactions may occur in immunocytochemical staining procedures. It thus seems precarious to draw conclusions about the chemical structure of a peptide solely on the basis of immunocytochemical studies.     

Fine structure of pars neuro-intermedia of the loach,Misgurnus fossilis L.

Summary Two types of glandular cells are present in the pars intermedia of the loach, Misgurnus fossilis. Basophils are characterized by the presence in their cytoplasm of numerous secretory granules containing electron-dense and homogeneous material and by scarce endoplasmic reticulum. Weak acidophils contain in their cytoplasm abundant endoplasmic reticulum and numerous granules of different electron densities.The distal part of the neurohypophysis is composed of several types of neurosecretory axons, strongly branched pituicytes, numerous capillaries, and connective tissue elements. The axon terminals form the neuroglandular, neurovascular and neurointerstitial contacts. Some axon terminals are closely apposed to the basement membrane separating neurohypophysis from meta-adenohypophysis. At points of absence of continuity of this membrane, some neurosecretory axons become directly contiguous with cytoplasmic membranes of the intermedia cells.The investigation was partly supported by a research grant from the Zoological Committee of the Polish Academy of Sciences.