Isolation and characterization of gap junctions from Drosophila melanogaster

Summary A procedure has been developed to isolate gap junction-enriched subcellular fractions from Drosophila. Crude membranes from larval homogenates were extracted with 1% N-lauroyl sarcosine in 6 M urea and the gap junctions were collected by centrifugation. The major proteins were separated by SDS PAGE and purified by electro-elution. Electron microscopy revealed structurally pleiomorphic gap junctions in the fractions which included (1) conventional, 16–18 nm-wide septalaminar, (2) collapsed, 13–15 nm-wide pentalaminar, (3) split, and (4) aggregated forms. The fractions contained five major proteins with apparent molecular weights of 18, 26, 36, 52 and 54 kD. Evidence based on (1) the degradation and aggregation behavior of the major proteins following electro-elution and reelectrophoresis, (2) immunological cross-reactivities by affinity-purified antibodies against the major proteins on immunoblots, and (3) immunofluorescent staining of presumptive gap junctions in Drosophila imaginal discs at the light-microscopic level and immunogold staining of purified gap junctions at the electron-microscopic level suggests that the major proteins are interrelated and of gap-junction origin.     

Serotonin-immunoreactive neurons in the median protocerebrum and suboesophageal ganglion of the sphinx moth Manduca sexta

Summary Serotonin-immunoreactive neurons in the median protocerebrum and suboesophageal ganglion of the sphinx moth Manduca sexta were individually reconstructed. Serotonin immunoreactivity was detected in 19–20 bilaterally symmetrical pairs of interneurons in the midbrain and 10 pairs in the suboesophageal ganglion. These neurons were also immunoreactive with antisera against DOPA decarboxylase. All major neuropil regions except the protocerebral bridge are innervated by these neurons. In addition, efferent cells are serotonin-immunoreactive in the frontal ganglion (5 neurons) and the suboesophageal ganglion (2 pairs of neurons). The latter cells probably give rise to an extensive network of immunoreactive terminals on the surface of the suboesophageal ganglion and suboesophageal nerves. Most of the serotonin-immunoreactive neurons show a gradient in the intensity of immunoreactive staining, suggesting low levels of serotonin in cell bodies and dendritic arbors and highest concentrations in axonal terminals. Serotonin-immunoreactive cells often occur in pairs with similar morphological features. With one exception, all serotonin-immunoreactive neurons have bilateral projections with at least some arborizations in identical neuropil areas in both hemispheres. The morphology of several neurons suggests that they are part of neuronal feedback circuits. The similarity in the arborization patterns of serotonin-immunoreactive neurons raises the possibility that their outgrowing neurites experienced similar forces during embryonic development. The morphological similarities further suggest that serotonin-immunoreactive interneurons in the midbrain and suboesophageal ganglion share physiological characteristics.Abbreviations CNS central nervous system - DDC DOPA decarboxylase - LAL lateral accessory lobe - SLI serotonin-like immunoreactivity - SOG suboesophageal ganglion - VLP ventro-lateral protocerebrum     

Metamorphic changes in the central projects of hair sensilla inTenebrio molitor L. (Insecta: Coleoptera)

Summary This paper describes the afferent projections of hair sensilla of the pro- and mesothoracic legs and the lateral thoracic sclerites of larval and adultTenebrio molitor and the corresponding set of pupal hair sensilla. The sensory neurons that innervate the hair sensilla of larval or adult insects project somatotopically into the thoracic neuropil. Different types of sensilla on the same region of the body surface project to the same zone of the ipsilateral thoracic ventral neuropil but exhibit different arborization patterns. Although there is a profound reorganization of body surface sensilla, the basic somatotopic layout of the larva is maintained in the adult. The sensory neurons that innervate the pupal hair sensilla possess central projections similar to those of the corresponding adult sensory neurons. The central projections of pupal sensory neurons are somatotopically oriented. Their projection pattern is serially homologous in the thoracic and the abdominal ganglia. The central projection pattern of the described pupal sensory neurons is constant throughout pupation. MAb 22C10 immunoreactivity allows an estimate of the timing of the early differentiation of the imaginal sensory neurons originating during pupation. Ablation experiments indicate that pupal sensory neurons influence the central projection pattern of the differentiating imaginal sensory neurons.     

Distribution and functional significance of Met-enkephalin-Arg6-Phe7-and Met-enkephalin-Arg6-Gly7-Leu8-like peptides in the blowflyCalliphora vomitoria

Summary Neuronal pathways in the retrocerebral complex and thoracico-abdominal ganglionic mass of the blowflyCalliphora vomitoria have been identified immunocytochemically with antisera against the extended-enkephalins, Met-enkephalin-Arg⁶-Phe⁷ (Met-7) and Met-enkephalin-Arg⁶-Gly⁷-Leu⁸ (Met-8). Neurons of the hypocerebral ganglion, immunoreactive to Met-8, have axons in the crop duct nerve and terminals in muscles of the crop and its duct. Certain neurons of the hypocerebral ganglion are also immunoreactive to Met-7, and axons from these cells innervate the heart. Met-8 immunoreactive nerve terminals invest the cells of the corpus allatum. The source of this material is believed to ve a single pair of lateral neurosecretory cells in the brain. There is no Met-7 immunoreactive material in the corpus allatum. In the corpus cardiacum neither Met-7 nor Met-8 immunoreactivity is present in the cells. However, in the neuropil of the gland certain fibres, with their origins elsewhere, do contain Met-8 immunoreactivity. The most prominent neurons in the thoracic ganglion are the Met-7 immunoreactive ventral thoracic neurosecretory cells, axons from which project to neurohaemal areas in the dorsal neural sheath and also, via the ventral connective, to the brain. Co-localisation studies show that the perikarya of these cells are immunoreactive to antisera raised against several vertebrate-type peptides, such as Met-7, gastrin/cholecystokinin and pancreatic polypeptide. However, their axons and terminals show varying amounts of the peptides, suggesting differential transport and utilisation. Only a few cells in the thoracic ganglion are immunoreactive to Met-8 antisera. These lie close to the nerve bundles suppling the legs. In the abdominal ganglion, Met-8 immunoreactive neurons project to the muscles of the hindgut. This study suggests that the extended enkephalin-like peptides ofCalliphora may have a variety of different roles: as neurotransmitter or neuromodulator substances; in the direct innervation of effector organs; and as neurohormones.     

Zum Feinbau des Komplexauges von Stylops spec. (Insecta,Strepsiptera)

Zusammenfassung Unter den Cornealinsen des Komplexauges von Stylops befindet sich ein Kristallkegel vom pseudoconen Typ, der von zahlreichen Pigmentzellen umhüllt wird. An seinem proximalen Ende liegen 6 meist pigmentfreie Zellen (Sempersche Zellen).Das Ommatidium besteht aus etwa 60 Retinulazellen. Ihre distal kranzartig miteinander verbundenen Mikrovillisäume bilden ein einziges offenes Rhabdom, das extrazelluläres (?) granuläres Material und die Basis der Semperschen Zellen umgibt. Stellenweise wird das Rhabdom samt granulärem Material von homogen erscheinenden distalen Ausläufern einzelner Retinulazellen überlagert. Proximad zerfällt das Rhabdom zunehmend in kleinere Rhabdomteile. Im zentralen Teil des Ommatidiums liegen 1–2 auffallend große Retinulazellen, die meist weniger elektronendicht erscheinen und kleinere Pigmentgrana haben.Die einzelnen Ommatidien werden von ungemein zahlreichen, sehr pigmentarmen Stützzellen umhüllt. Diese werden — wie die basalen Teile der Retinulazellen — teilweise durch Gliazellfortsätze isoliert.Bei Stylops, einem Vertreter der Strepsipteren, handelt es sich nicht um ocelläre Komplexaugen (Strohm, 1910), auch nicht um eucone Ommatidien (Kinzelbach, 1967), sondern um Ommatidien vom pseudoconen Typ. Zumindest der Bau des Rhabdoms ähnelt dem des Larvenauges (Stemma), dessen rezeptorischer Teil entgegen den Annahmen früherer Autoren in der Imago nicht reduziert wird.

---

On the fine structure of the compound eye of Stylops spec. (Insecta, Strepsiptera)

Summary In the compound eye of Stylops a crystalline cone of the pseudocone type is found beneath the corneal lens. It is enveloped by several pigment cells. At the proximal part of the cone there are 6 cells (Semper cells) mostly pigment-free.The ommatidium consists of approximately 60 retinula cells. Their rhabdomeres distally rim-like connected to another form a single open rhabdom which encircles extracellular granular material as well as the bases of the Semper cells. Here and there the rhabdom plus granular material is overlain with distal protrusions of single retinula cells which appear to be homogeneous. Towards the proximal part the rhabdom increasingly divides up into smaller rhabdomal segments. One or two conspicuous large retinula cells were found in the central part of the ommatidium, appearing to be less electron-dense and containing pigment granules of a smaller size. Each ommatidium is surrounded by numerous cells (Stützzellen) lacking in pigment. These cells are partially insulated from another—as well as the basal parts of retinula cells—by protrusions of glia cells.Our investigations show that the eyes of Stylops (as a representative of Strepsiptera) are not of the ocellar complex eye type. At least the structure of the rhabdom resembles to that of the larval eye (stemma), the receptor part of which is not reduced in the imago.

Herrn Prof. Dr. Helmcke danke ich für die freundliche Unterstützung am Raster-Elektronenmikroskop.     

Ultrastruktur des Pseudoculus vonEosentomon (Protura,Insecta)

Zusammenfassung In der Feinstruktur unterscheidet sich der Pseudoculus vonEosentomon nicht wesentlich von dem der Acerentomiden. Durch einen Endokutikulaporus treten die dendritischen Fortsätze zweier Sinneszellen, jeweils umgeben von einer Hüllzelle, in den Außenraum des Pseudoculus ein. Der Außenraum wird nach distal von einer äußeren Kutikulaschicht — vermutlich Epikutikula — abgeschlossen. Sie vermittelt durch regelmäßig angeordnete lange Spalten die Verbindung zur Außenwelt. Am Grunde der Spalten finden sich Porentubuli, die mit den Hüllzellen oder den distalen Fortsätzen der Dendriten Kontakt haben können. Aus der Feinstruktur kann geschlossen werden, daß der Pseudoculus als Chemo-, Hygro- und/oder Thermorezeptor fungiert.

---

Ultrastructure of the pseudoculus ofEosentomon (Protura, Insecta)

Summary Concerning its fine structure the pseudoculus of Eosentomon is quite similar to that of Acerentomide Protura. There are two sensory cells innervating the organ. From each of them one dendritic process derives, surrounded by one enveloping cell. The processes of these four cells enter the distal cavity of the pseudoculus through a pore in the endocuticular layer. The cuticular layer of the cap seems to consist of epicuticle only. It is furrowed by long clefts connecting the distal cavity of the organ with the outside. Poretubules insert at the base of the clefts and may have contact with the cell membranes of both enveloping cells and dendritic processes. According to its structure the pseudoculus may function as chemo-, hygro- and/or thermoreceptor.

Für technische Mitarbeit danke ich Frau G. Raabe, für die Anfertigung der Zeichnung Frau C. St. Friedemann.     

The vacuolar-type ATPase from insect plasma membrane: immunocytochemical localization in insect sensilla

Summary This comparative immunocytochemical investigation provides evidence that the electrogenic potassium pump of insect sensilla is a vacuolar-type proton ATPase energizing potassium-proton antiport, as was shown recently for the electrogenic potassium pump in the larval midgut of the sphinx moth Manduca sexta. Antennal sensilla of the saturniid moth Antheraea pernyi were probed with antibodies to the midgut vacuolar-type ATPase. The monoclonal antibodies recognized their epitopes in the native and SDS-denatured state, and bound specifically to the subunit with the relative molecular mass (M_r) of 67000 (antibody 86-3) or to the subunits of M_r 28000 and 16000 (antibody 47-5). Both antibodies labelled the apical region of the auxiliary cells, as was demonstrated by immunofluorescence microscopy. Immunogold-electron microscopy localized the binding sites of the 47-5 antibody in the highly folded apical plasma membranes of the auxiliary cells. Labelling was selective and was detected in all types of examined sensilla (S. trichodea, S. styloconica, S. coeloconica). These findings are in agreement with the current view that an electrogenic potassium pump is situated in the apical plasma membrane of the auxiliary cells and that the pump is involved in driving the receptor current. They support the hypothesis that a proton-motive force generated by a vacuolar-type ATPase provides an alternative to the classical Na⁺/K⁺-ATPase to energize animal plasma membranes.     

Immunocytochemical mapping of neuronal pathways from brain to corpora cardiaca/corpora allata in the cockroach Diploptera punctata with antisera against Met-enkephalin-Arg6-Gly7-Leu8

Summary Neuronal circuits in the brain and retrocerebral complex of the cockroach Diploptera punctata have been mapped immunocytochemically with antisera directed against the extended enkephalin, Met-enkephalin-Arg⁶-Gly⁷-Leu⁸ (Met-8). The pathways link median and lateral neurosecretory cells with the corpus cardiacum/corpus allatum complex. In females, nerve fibres penetrate the corpora allata and varicosities or terminals, immunoreactive to Met-8, surround the glandular cells. Males differ in having almost no Met-8 immunoreactivity in the corpora allata. The corpora cardiaca of both males and females are richly supplied with Met-8 immunoreactive material, in particular in the cap regions immediately adjacent to the corpora allata. A similarity in the amino-acid sequences of Met-8 and the C-terminus of the recently characterised allatostatins of D. punctata suggests that the pathways identified with the Met-8 antisera may be the same as those by which the allatostatins are transported from the brain to the corpus allatum. In comparative studies on the blowfly Calliphora vomitoria, similar neuronal pathways have been identified except that no sexual dimophism with respect to amounts of immunoreactive material within the corpus allatum has been observed. These results suggest a possible homology in the neuropeptide regulation of the gland.