Distribution of F-actin in the compound eye of the blowfly,Calliphora erythrocephala (Diptera,Insecta)

Summary Sexual stimulation of males has been reported to affect hypothalamic oxytocinergic systems. In the present study we used radioimmunoassays of micro-dissected forebrain regions and immunocytochemical analysis of Vibratome sections to study the oxytocin systems of naive males, males killed after one mating, and males mated daily with different receptive females for 3 weeks. In males that had mated once, less oxytocin-immunoreactive neurons were observed in the paraventricular (PVN), supraoptic (SON) and periventricular (NPE) nuclei than in naive males. However, after repeated matings, the number of immunoreactive neurons and their staining intensity was increased in these regions. Furthermore, additional oxytocinergic neurons could be found in the lateral subcommissural nucleus, the zona incerta and the ansa lenticularis of repeatedly mated males. Oxytocin-immunoreactive neurons were only occasionally seen in these areas in unmated males or in animals that had been killed after initial mating. Radio-immunoassays of microdissected PVN, SON, NPE and the lateral hypothalamus confirmed the reduction in oxytocin-immunoreactive levels after a first mating by a male and the increase after repeated matings. It is likely that oxytocin secretion into peripheral and portal circulation is stimulated by the endocrine conditions associated with initial mating. These immediate effects may be followed by the activation of synthesis in oxytocin neurons in several sites of the basal forebrain.     

Ultrastructure and ontogeny of the hair sensilla on the funicle of Calliphora erythrocephala (Insecta,Diptera)

Summary Four envelope cells are responsible for the formation of the basiconical sensilla of Calliphora. They are the thecogen, trichogen, and tormogen cells, and envelope cell 4. In early stages of development the still subepithelial sensory cilia are completely enclosed by the innermost thecogen cell. The first formation movements are initiated by a growth thrust of the hair-forming cell into the exuvial space. The sensory cilia only begin to grow into the hair anlage when the hair-forming cell has almost reached its final length. As soon as growth is completed the trichogen cell, tormogen cell, and envelope cell 4 start to excrete cuticular material. The trichogen cell forms the perforated part of the hair shaft and the stimulus-conducting system consisting of the pore tubules. The tormogen cell is responsible for the excretion of the basal non-perforated hair shaft and sheath cell 4 forms the proximal part of the socket region. The thecogen cell only begin to produce dendritic sheath material when the sensory hair is almost complete.Approximately 7–8 days after pupation the tormogen cell degenerates, having, by this time, produced about two-thirds of the sensilla cuticle. The surrounding envelope cells incorporate cell fragments of the tormogen cell. The trichogen cell continues the secretion where the tormogen cell left off. When the secretion of cuticle is finished the sheath cells begin to withdraw towards the proximal direction and to form microvilli on the apical membrane. The resulting outer receptor lymph space is bordered by envelope cell 4 and the trichogen and thecogen cells. The tormogen cell is absent in the sensilla of the imago.Abbreviations DS dendritic sheath - E4 envelope cell 4 - Ex exuvial space - G glial cell - iD inner dendritic segment - iRL inner receptor lymph space - oRL outer receptor lymph space - oD outer dendritic segment - P pore - PT pore tubules - S sensory cell - T thecogen cell - TO tormogen cell - TR trichogen cell Part 1 of a dissertation accepted by the Faculty of Bio- and Geosciences, University of Karlsruhe     

Campaniform sensilla of Calliphora vicina (Insecta,Diptera)

Summary A classification scheme of campaniform sensilla using morphological criteria was developed. All variations of the two most important outer structural elements, the cuticular cap and the cuticular collar, were taken into consideration: (a) the external shape of the cuticular cap; (b) the position of the cuticular cap in relation to the remaining cuticle; (c) the position of the cuticular collar in relation to the cuticular cap. This resulted in a classification of campaniform sensilla into 24 types. This typology was applied to the campaniform sensilla of Calliphora, which show considerable variations in their outer structures. According to SEM (scanning electron microscope) pictures and TEM (transmission electron microscope) sections we found only 9 out of 24 different types of campaniform sensilla in the fly.     

The haemocytes of Calliphora erythrocephala (Meig.) (Diptera)

Summary The haemocytes of larvae and young pupae of Calliphora erythrocephala are studied by phase contrast and electron microscopy and three cell lineages are distinguished: plasmatocytes, thrombocytoids and oenocytoids. The plasmatocytes show important modifications during larval development and at the time of histolysis, which are described and discussed in relation to the function of these cells in the physiology of Calliphora. The thrombocytoids, haemocytes which had not been recorded so far, are characterized by a strong tendency to fragmentation, this process leading to the formation of the anucleated cytoplasmic fragments and the naked nuclei referred to by earlier authors. The ability of the cell fragments, which retain normal cytological characteristics, to agglutinate and form intricate networks, is discussed in relation to haemostasis in Calliphora.The ultrastructural study of the haemocyte accumulations in the vicinity of the posterior part of the dorsal vessel reveals the basic organization of haemocytopoetic tissue, as described recently in orthopteran insects. The functional importance of this tissue in the production of haemocytes is demonstrated by X-irradiation and ligation experiments in larvae of Calliphora.

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Résumé L'étude en microscopie en contraste de phase et au microscope électronique permet de distinguer dans le sang circulant de larves et de jeunes pupes de Calliphora erythrocephala trois lignées cellulaires: les plasmatocytes, les thrombocytoïdes et les oenocytoïdes. Les plasmatocytes, numériquement les plus importants, présentent au cours du développement larvaire et chez les pupes des modifications considérables, qui sont décrites et discutées en rapport avec la fonction évidente de ces hémocytes chez Calliphora. Les thrombocytoïdes, inconnus dans la littérature, se caractérisent par une forte tendance à la fragmentation, qui aboutit à la formation des «fragments cytoplasmiques anucléés» et des «noyaux nus» signalés par divers auteurs. Les phénomènes d'agglutination des «fragments cytoplasmiques anucléés», dont les caractères cytologiques restent normaux, sont discutés en rapport avec le problème de l'hémostase chez cet insecte.L'étude ultrastructurale des accumulations hémocytaires autour du vaisseau dorsal dans la partie postérieure de l'abdomen montre une organisation de base comparable à celle décrite dans les organes hématopoïétiques des Insectes Orthoptères. L'importance fonctionelle de ce tissu hématopoïétique de Calliphora dans la production des hémocytes au cours de la vie larvaire est démontrée par des irradiations de ce tissu et par des ligatures de la partie postérieure de l'abdomen.

     

Functional-morphological investigations on the flight muscles and their insertion points in the blowfly Calliphora erythrocephala (Insecta,Diptera)

Summary In flies, for example the blowfly Calliphora erythrocephala, the thorax has fused to form a chitinous capsule. In it we find three functional types of flight muscles, the indirect flight muscles, the direct, and the tension muscles. The indirect or wing beat muscles transfer their power to the capsule which is capable of oscillating. They are suspended nearly horizontally and vertically. The direct muscles used for steering insert laterally on the capsule and go to the wing joint. The third functional type of flight muscle serves to put the lateral walls of the thorax under tension. The site and morphology of the flight muscles are described in detail, making use of 3-dimensional drawings. The flight muscles of Calliphora erythrocephala (Heide 1968) and their functions are compared with those of other dipterans described by different authors.With support of the Deutsche Forschungsgemeinschaft to Professor Nachtigall     

Ultrastructure of the myocardial cell and its membrane systems in the adult fly Calliphora erythrocephala (Insecta: Diptera)

Summary Calliphora erythrocephala has cross-striated cardiac muscle cells with A, I and Z-bands. The diameters of the myosin and actin filaments are 200–250 Å and 85 Å respectively and the length of the myosin filaments (A-band) is approximately 1.5 . Usually 8–10 actin filaments surround each myosin filament.The myocardial cells show a well-developed membrane system and interior couplings. A perforated sheet of SR envelopes the myofibrils at the A-band, dilates into flattened cisternae at both A-I band levels before it merges into a three-dimensional net-work between the actin filaments of the I-bands and between the dense bodies of the discontinuous Z-discs. The T-system consists of broad flattened tubules running between the myofibrils at the A-I band levels forming dyads with the SR-cisternae. Longitudinal connections between the transverse (T-) tubules often occur.It is suggested that this well-developed SR may be an adaptation to facilitate a rapid contraction/relaxation frequency by an effective Ca²⁺ uptake.     

Development of labellar taste hairs in the blowfly,Calliphora vicina (Insecta,Diptera)

Summary The early development of taste sensilla has been studied with special emphasis on cilia, dendrite, and pore formation.In the 39-h stage (the first stage investigated) differentiation of sensilla is already under way. The mechanisms of differentiation of dendrites (39–48 h) deviate from the mechanisms described for differentiation of true cilia. In taste hairs the centrioles meet in the tip of the narrowed apical region of the sensory neuron. Together they sink deeper into this region and line up coaxially, thus forming the basal body complex. Thereafter, lateral contacts between this complex and the plasma membrane of the neuron are established. Formation of open connections between the trichogen lumen of the hair and the environment, or the dendrite lumen, was not observed.Electrophysiological data indicate that the sensilla become functional from 3 days before emergence onwards.List of Abbreviations B Basal body complex - bc Basal compartment - bs Basal sheath - bl Basement lamina - D Dendrite(s) - EPC Non-sensillar epithelial cells - ES Ecdysial sheath - GERL Granular endoplasmatic reticulum-lysosomes - HS Hemolymph space - P Protrusions - PRN Prospective receptor neuron - RER Rough endoplasmatic reticulum - RN Receptor neuron - n Neck - THC Thecogen cell - TOC Tormogen cell - TRC Trichogen cell - TRS Trichogen sprout     

Cyst geometry in the egg chambers of Calliphora erythrocephala Mg. (Diptera: Calliphoridae) ovaries

In the germarium of polytrophic ovarioles of Calliphora erythrocephala (Mg.) fly, four mitotic divisions of cystoblasts give rise to 16-cell germ-line cysts. One cell differentiates into an oocyte, while the remaining 15 cells become nurse cells. Concomitantly actin-rich ring canals are formed at the intercellular junctions. The present study considers a mutual arrangement of the ring canals formed after the second to fourth mitoses relative to the ring canal formed after the first mitotic division in different regions of the germarium and egg chambers. During the cyst formation and its movement to the posterior end of the germarium, the ring canals are displaced relative to one another, thereby giving different branching variants of the cyst. The pattern of cell interconnections becomes stable in germarium region 2b and does not change during the cyst movement along the ovariole despite the cyst polarizes and increases in size.     

A quantitative analysis of mitotic gradients during early development in Calliphora erythrocephala Meig. (Diptera)

Mitotic waves during superficial cleavage and early gastrulation were analyzed quantitatively in Calliphora. Three consecutive patterns are present: (1) a monotonic anterioposterior mitotic gradient during early superficial cleavage; (2) a double mitotic gradient from the anterior and posterior poles during superficial cleavage, especially toward the end of the period; and (3) more complicated patterns with intermediate mitotic centers during the last superficial cleavage division and during early gastrulation. Mitotic gradients are absent in many eggs during early superficial cleavage, but they then become ubiquitous. The gradients are longitudinal; no transverse component was detected before gastrulation. Anterior and posterior gradient patterns are not mirror images of each other; mitotic activity always starts earlier anteriorly. The gradients are accompanied by a pronounced increase in interphase length. The mitotic gradients are compared with the morphogenetic gradients predicted in a current model for pattern specification in insect eggs.     

Intranuclear dynamics of chromosome 6 in nurse cells of Calliphora erythrocephala Mg. (Diptera: Calliphoridae)

Intranuclear dynamics of chromosome 6 in nurse cell nuclei of Calliphora erythrocephala Mg. (Diptera: Calliphoridae) was studied. The 3D FISH method was used for the first time to study chromosome territories in highly polyploid nuclei whose chromosomes undergo morphological changes. A considerable change in the intranuclear location of chromosome 6 and a morphological alteration of the chromosome territory in the course of chromatin polytenization were revealed.     

Localisation of pancreatic polypeptide (PP)-like immunoreactive material in neurones of the brain of the blowfly,Calliphora erythrocephala (Diptera)

Summary The brain of the blowfly, Calliphora erythrocephala, has been studied by means of the peroxidase-antiperoxidase immunocytochemical method, with the use of antibodies to bovine pancreatic polypeptide (BPP). A number of immunoreactive neurones have been localised, some corresponding to neurones previously identified tentatively as neurosecretory. This finding is further evidence that biologically active peptides, previously considered to be vertebrate, also exist in invertebrates. It also supports the concept of their evolutionary origin in nervous tissue.     

Chromosome Organization and Differential Banding in Endomitotic Nuclei of Nurse Cells of Calliphora erythrocephala (Diptera: Calliphoridae)

The structure of primary polytene chromosomes and general architecture of nurse cell nuclei was studied in Calliphora erythrocephala using various methods of differential chromosome banding(G-, R-, C-banding; Ag-, and DAPI staining), chromospecific DNA probes and fluorescence in situ hybridization. This analysis revealed differential compaction of particular chromosome regions. The localization of material of polytene chromosome 6 is retained after its rearrangement and the formation of the internal reticular structure of the nucleus. Polytene chromosomes of ovarian nurse cells were shown to have blocks of dense compact material; some of them were more intensely stained by AgNO₃. The dynamics of the nucleolus formation was traces at all stages of chromosome polytenization in the C. erythrocephala nurse cells.     

Entwicklungsleistungen abdominaler Imaginalscheiben vonCalliphora erythrocephala (Insecta,Diptera). Experimentelle Untersuchungen zur Morphologie des Abdomens

Zusammenfassung Die vorliegende Arbeit befaßt sich mit dem Induktionsvermögen isolierter Dotterplättchen, der Kerne und Pigmentgranula, der Ribosomen und des ribosomenfreien Überstandes aus Ganzkeimhomogenaten der Gastrula vonXenopus laevis.Die subzellularen Fraktionen wurden mit Hilfe differentiellen Zentrifugierens in saccharosehaltigen Medien isoliert und ihre Reinheit elektronenmikroskopisch geprüft.Die Mikrosomenfraktion zeigt archencephal-deuterencephale Induktionsaktivität, die sich nach Extraktion mit Pyrophosphat und mit Phenol erhöht. Die Membranstrukturen dieser Fraktion können partiell von den Ribosomen durch Behandlung mit Desoxycholat abgetrennt werden. Proteine, die deuterencephale und spinocaudale Gewebedifferenzierungen hervorrufen, lassen sich von der mit Desoxycholat behandelten Mikrosomenfraktion mit 1 M NH₄Cl extrahieren.Der ribosomenfreie Überstand besitzt nur schwaches Induktionsvermögen. Nach einer Phenolbehandlung nimmt die archencephal-deutereucephale Aktivität zu, nicht jedoch die spinocaudale.Isolierte Kerne induzieren kleine deuterencephale Gewebestrukturen und einen relativ hohen Prozentsatz an spinocaudalen Differenzierungen. Phenolextraktion erhöht die Rate dieser Induktionen nicht.Die Dotterplättchen weisen in der Hauptsache deuterencephales Induktionsvermögen auf, das größtenteils mit der Außenhülle dieser Partikel assoziiert ist. Proteine, die archenecphal-deuterencephale Gewebedifferenzierungen hervorrufen, können in geringen Mengen aus Plättcten extrahiert werden, deren Außenhülle vorher fast vollständig entfernt worden ist.

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Inducing capacity of subcellular fractions from the gastrula ofXenopus laevis

Summary Isolated yolk platelets, nuclei and pigment granules, ribosomes and the ribosome-free supernatant of homogenates from whole gastrulae ofXenopus laevis were tested for their inducing properties.The subcellular fractions were obtained by differential centrifugation in sucrose media and their purity was checked by electronmicroscopy.The microsomal fraction shows archencephalic and deuterencephalic inducing capacity which is enhanced after extraction with pyrophosphate and with phenol. The membrane structures of this fraction can partially be separated from the ribosomes by treatment with desoxycholate. Proteins with deuterencephalic and spinocaudal inducing activity are extractable from the desoxycholate treated microsomal fraction with 1 M NH₄Cl.The supernatant, free of ribosomes, has a rather weak inducing ability. After extraction with phenol the archencephalic and deuterencephalic activity increases, but not the spinoaudal.Isolated nuclei induce small deuterencephalic structures and a relatively high percentage of spinocaudal differentiations. Extraction with phenol does not enhance the rate of these inductions.The yolk platelets show mainly deuterencephalic inducing activity which is associated essentially with the superficial layer of these particles. Proteins, inducing archencephalic and deuterencephalic tissue differentiations, are extractable in small amounts from the platelets after partial removal of the superficial layer.

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Die Arbeit wurde mit Unterstützung der Deutschen Forschungsgemeinschaft ausgeführt.

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Die elektronenoptischen Aufnahmen wurden von Dr. H. Grunz und G. Arkenberg hergestellt.     

Organization and differential staining of chromosomes from the endomitotic nucleus of trophocytes Calliphora erythrocephala (Diptera: Calliphoridae)

The structure of primary polytene chromosomes and general architecture of nurse cell nuclei was studied in Calliphora erythrocephala using various methods of differential chromosome banding(G-, R-, C-banding; Ag- and DAPI staining), chromospecific DNA probes and fluorescence in situ hybridization. This analysis revealed differential compaction of particular chromosome regions. The localization of material of polytene chromosome 6 is retained after its rearrangement and the formation of the internal reticular structure of the nucleus. Polytene chromosomes of ovarian nurse cells were shown to have blocks of dense compact material; some of them were more intensely stained by AgNO3. The dynamics of the nucleolus formation was traces at all stages of chromosome polytenization in the C. erythrocephala nurse cells.