The metabolism of 3H-moulting hormone in Calliphora erythrocephala during larval development

The activity in whole insects for converting ³H-α-ecdysone to ³H-β-ecdysone after injection is low (half-maximal) in young last instar larvae, maximal in mature larvae, and minimal (fourth-maximal) at the white puparial stage. Because moulting hormone titre is low throughout the last larval instar and increases at the formation of the puparium it appears that hydroxylation at C-20 is not a key step in regulating β-ecdysone biosynthesis during larval development.The activity for catabolizing ³H-β-ecdysone is maximal in second instar larvae, about thirdmaximal throughout most of the third instar, and minimal at pupariation (thirtieth-maximal). Thus inactivation may play a rôle in regulating moulting hormone titre during larval development.     

Normal and experimentally induced lysosomal activity in the larval fat body of Calliphora erythrocephala Meigen

Summary Acid phosphatase activity was demonstrated by EM-cytochemistry in 4 day old third instar larvae of the fly Calliphora erythrocephala Meigen, but not in younger stages. During larval development, the activity increased, reaching a maximum at the onset of pupariation. The reaction product was localized in Golgi vesicles and sacculi, in vacuoles and in protein granules of varying size and composition, confirming the autophagic character of the protein granules. Throughout larval development, the reaction product was restricted to membrane-bound structures and no indications of free cytoplasmic activity that might be related to cytolysis were found.Enzyme activity could be evoked by transplanting inactive fat body lobes into host larvae of a later developmental stage. High enzyme activity was induced in these transplants within 18h. The sites of activity were roughly the same, but a portion of the activity in the transplants was found in the vacuoles. The induction could be inhibited by cycloheximide.     

Reconstructing the duplication history of tandemly repeated genes

We present a novel approach to deal with the problem of reconstructing the duplication history of tandemly repeated genes that are supposed to have arisen from unequal recombination. We first describe the mathematical model of evolution by tandem duplication and introduce duplication histories and duplication trees. We then provide a simple recursive algorithm which determines whether or not a given rooted phylogeny can be a duplication history and another algorithm that simulates the unequal recombination process and searches for the best duplication trees according to the maximum parsimony criterion. We use real data sets of human immunoglobulins and T-cell receptors to validate our methods and algorithms. Identity between most parsimonious duplication trees and most parsimonious phylogenies for the same data, combined with the agreement with additional knowledge about the sequences, such as the presence of polymorphisms, shows strong evidence that our reconstruction procedure provides good insights into the duplication histories of these loci.     

Mapping of serotonin-immunoreactive neurons in the larval nervous system of the flies Calliphora erythrocephala and Sarcophaga bullata

Summary Serotonin-immunoreactive (5-HTi) neurons were mapped in the larval central nervous system (CNS) of the dipterous flies Calliphora erythrocephala and Sarcophaga bullata. Immunocytochemistry was performed on cryostat sections, paraffin sections, and on the entire CNS (whole mounts).The CNS of larvae displays 96–98 5-HTi cell bodies. The location of the cell bodies within the segmental cerebral and ventral ganglia is consistent among individuals. The pattern of immunoreactive fibers in tracts and within neuropil regions of the CNS was resolved in detail. Some 5-HTi neurons in the CNS possess axons that run through peripheral nerves (antenno-labro-frontal nerves).The suboesophagealand thoracico-abdominal ganglia of the adult blowflies were studied for a comparison with the larval ventral ganglia. In the thoracico-abdominal ganglia of adults the same number of 5-HTi cell bodies was found as in the larvae except in the metathoracic ganglion, which in the adult contains two cell bodies less than in the larva. The immunoreactive processes within the neuropil of the adult thoracico-abdominal ganglia form more elaborate patterns than those of the larvae, but the basic organization of major fiber tracts was similar in larval and adult ganglia. Some aspects of postembryonic development are discussed in relation to the transformation of the distribution of 5-HTi neurons and their processes into the adult pattern.     

Serotonin and gastrin/cholecystokinin-like immunorcactive neurons in the larval retrocerebral complex of the blowfly Calliphora erythrocephala

Summary The presence and distribution of neurons immunoreactive against antibodies to serotonin (5-HT) and gastrin/cholecystokinin (gastrin/CCK) has been studied in the larval retrocerebral complex of the blowfly Calliphora erythrocephala, a composite structure which consists of the corpus cardiacum, the corpus allatum, the thoracic gland and a portion of the cephalic aorta. Immunoreactive material was found in all these elements except in the corpus allatum. Six to eight cell bodies in the corpus cardiacum and four to eight cell bodies in the thoracic gland were 5-HT immunoreactive (5-HTi). These 5-HTi cell bodies send processes to the neuropil of the corpus cardiacum and to neurohemal sites in the cephalic aorta, corpus cardiacum and ventral part of the thoracic gland. Six to eight cell bodies in the corpus cardiacum and four to six cell bodies in the thoracic gland reacted with antibodies against gastrin/CCK. These cell bodies send processes to the neuropil of the corpus cardiacum and to neurohemal sites in the corpus cardiacum and the cephalic aorta in a pattern resembling that of the 5-HTi fibers. Additional gastrin/CCK-like immunoreactive fibers were shown to come from the central nervous system via the two nervi corporis cardiaci. An electron-microscopical analysis was performed to analyze further the morphological features revealed by the light-microscopic immunocytochemical technique. This confirmed the existence of neurosecretory-like terminals among the gland cells of the thoracic glands and the existence of neurohemal sites in several regions of the larval retrocerebral complex. Some functional aspects of the retrocerebral complex are discussed on the basis of the presented data.     

Restriction analysis of tandemly repeated yeast ribosomal RNA genes

Summary Ribosomal RNA (rRNA) genes of Saccharomyces cerevisiae are clustered in a DNA repeat unit of 5.9 megadaltons with the gene order 5S-18S-5.8S-25S rRNA (Nath and Bollon, 1977). By using two restriction endonucleases, EcoRII and HindII, which generate DNA fragments that span contiguous portions of two repeat units, we report that the rRNA gene clusters are tandemly repeated without the intervention of additional spacer DNA.The treatment of yeast DNA with the restriction endonucleases EcoRII and HindII result in the generation of 4 different DNA fragments that are of varying sizes and which hybridize with rRNA. The largest DNA fragments, 3.30 megadaltons in the case of HindII and 3.67 megadaltons in the case of EcoRII, encompass regions that code for the two opposite end regions of the 35S precuursor-rRNA. These two end regions are joined by a constant DNA segment of about 0.9 megadaltons in size of which a 0.08 megadalton segment codes for 5S rRNA. Since the 35S precursor-rRNA includes the 5.8S, 18S and 25S rRNA most of the repeat units containing the 4 rRNA coding genes in yeast are linked to each other contiguously without any intervening spacer DNA.A composite map of the DNA restriction fragments obtained by the action of the restriction endonucleases EcoRI, EcoRII, HindII and HindIII on the 5.9 megadalton repeat unit is presented. Some striking features concerning the location of the restriction sites are noted. Of the total 17 DNA restriction sites present on each repeat unit, 9 are located at or near the 3 transcribed spacer regions contained in the 5 megadalton DNA segment that codes for the 35S precursor-rRNA. The 3 transcribed spacer regions in the 35S precursor-rRNA include the two external transcribed spacer regions and an internal transcribed spacer region, the latter representing the 5.8S rRNA.     

Duplication and inversion history of a tandemly repeated genes family.

Given a phylogenetic tree for a family of tandemly repeated genes and their signed order on the chromosome, we aim to find the minimum number of inversions compatible with an evolutionary history of this family. This is the first attempt to account for inversions in an evolutionary model of tandemly repeated genes. We present a branch-and-bound algorithm that finds the exact solution, and a polynomial-time heuristic based on the breakpoint distance. We show, on simulated data, that those algorithms can be used to improve phylogenetic inference of tandemly repeated gene families. An application on a published phylogeny of KRAB zinc finger genes is presented.     

The neurosecretory system of the adult Calliphora erythrocephala

Summary Neurosecretory cells in the brain and suboesophageal ganglion of the adult female Calliphora erythrocephala have been studied in the light microscope. The paraldehydefuchsin stain (PAF) gave by far the clearest pictures.The medial neurosecretory cells of the protocerebrum (m.n.c.) show definite cyclic changes as to the size of the nuclei and the content of secretory material. The cytological changes depend on the age of the fly and the diet given and are correlated with ovarian development.The nuclear size is held to express the metabolic activity of the cells. Cells with large nuclei, as found in young sugar-flies (S1D) and meat-fed flies with developing ovaries (S4D/M2D), contain less secretory material which is released through the axons, while the m.n.c. of old sugar-flies (S6D) have small nuclei and are stuffed with secretory material which is stored in the perikarya.These results confirm those obtained by darkfield microscopy of living m.n.c. by Lea and E.Thomsen (1962 and unpublished).No really convincing evidence for the existence of more than one type of m.n.c. was found.Two small groups of lateral cells were observed. Possibly neurosecretory are further: 1-(2) cells at the base of each optic lobe, two groups of 2–3 cells on the caudal side of the brain, and 2 cells ventrally in the suboesophageal ganglion.Giant neurons of unknown function are situated very near the m.n.c. Their axons join those from the m.n.c., but end in the suboesophageal ganglion.The same region comprises a number of peculiar cells, each containing a large, fluid-filled vacuole (the vacuolated cells). Similar cells are associated with the possibly neurosecretory cells on the caudal side of the brain.My sincere thanks are due to my wife Dr. Ellen Thomsen, who made all the excisions of the brains and the measurements of the nuclei, to T.C.Normann for valuable assistance with the photographic work, and to Mrs. K. Bahnert for technical help with the gallocyanin method. The Carlsberg Foundation has supported the work with grants.     

The neurosecretory system of the adult Calliphora erythrocephala

Summary The histology of the corpus cardiacum (c. card.) and the hypocerebral ganglion of Calliphora has been described from sections mainly stained with paraldehyde-fuchsin (PAF) and counterstained with Halmi's mixture. Concurrently the nervous connections of these organs with the neurosecretory system and the stomatogastric nervous system were studied.Neurosecretory material from the medial neurosecretory cells of the brain (m.n.c.) could be traced through the cardiac-recurrent nerve, and passing through the c. card. it was seen to be abundantly present in the wall of the aorta and the two pairs of nerves leaving the c. card.-hypocerebral ganglion complex posteriorly, i.e. the aortic and the oesophageal nerves. However, in some old, fed flies a considerable amount of neurosecretory material was also observed in anastomosing branches of the cardiac-recurrent nerve inside the c. card. Thus storage of neurosecretory material originating in the m.n.c. may take place both in the aorta wall and in the c. card. This observation is relevant to the interpretation of previous experiments of E. Thomsen (1952).The c. card. cells proper (the c.n.c.) were not stained by the PAF, although they are known to be neurosecretory.This work was supported by grants from the Carlsberg Foundation. I am grateful to Professor C. Overgaard Nielsen for laboratory facilities.     

The neurosecretory system of the adult Calliphora erythrocephala

Summary In continuation of previous light microscopical investigations using darkfield microscopy of the living cells and sections stained with paraldehyde-fuchsin, an electron microscopical study of the medial neurosecretory cells (m.n.c.) of virgin females of Calliphora has been performed. The neurosecretory material consists of elementary granules corresponding in quantity to the amount of secretory material found by the two other methods in flies of the same age and kept on the same diet. The majority of the cells (m.n.c. I) contain granules measuring c. 2000–3000 Å, while fewer cells (m.n.c. II) show a smaller granular diameter (c. 1000–1500 Å). Due to the Tyndall effect the elementary granules are visible when using darkfield microscopy.The granules were seen to be pinched off from the Golgi complexes. These are numerous and well-developed, except in the less active m.n.c. I of the six days old sugar-flies. The reticulum and mitochondria are described. Axoplasmic channels were observed in the m.n.c. I, probably corresponding to structures found by Wigglesworth (1959 and 1960) in other insect neurons with another technique.The fine structure of the giant neurons and the vacuolated cells has been studied, the observations supporting the conclusions of M. Thomsen in a light microscopical study (1965). Lacunae in the ramifying glia are interpreted as belonging to the glial lacunar system described by Wigglesworth (1960).Dedicated to the memory of Ernst Scharrer (1905–1965), pioneer in the study of neurosecretion.We are grateful to the Carlsberg Foundation and the State General Scientific Foundation for financial support.     

Rhythmische Erregungen in den optischen Zentren von Calliphora erythrocephala

Zusammenfassung Die rhythmischen Aktionspotentiale in den optischen Ganglien der Schmeißfliege (Calliphora erythrocephala) werden untersucht.Wird das Komplexauge von Calliphora belichtet, so können vom Ganglion opticum II schnelle, rhythmische Aktionspotentiale, 'Belichtungsrhythme , abgegriffen werden (Abb. 1). Sie treten im Bereich physiologischer Temperaturen und Lichtintensitäten stets und unabhängig von Schädigungen auf. Sie sind die einzige Form von Erregung, die zwischen dem retinalen Bereich und dem Cerebralganglion nachgewiesen werden kann. Die Belichtungsrhythmen zeigen gesetzmäßige Abhängigkeiten von den Reizgrößen. Es ist daher wahrscheinlich, daß sie in die Kausalkette der bei Belichtung des Auges ablaufenden zentralen Vorgänge eingeschaltet sind.Die optischen Ganglien werden mit einer Doppelmikroelektrode abgetastet. Da die Spannung zwischen zwei eng benachbarten Elektroden in der Nähe der Spannungsquelle am größten sein muß, kann gezeigt werden, daß die Belichtungsrhythmen wahrscheinlich in der äußeren Körnerschicht des Ganglion opticum II entstehen (Abb. 14 und 15).Als Maß für die Größe der Belichtungsrhythmen wird die größte während einer Belichtung auftretende Amplitude gewählt, die 'Maximalamplitud ; sie hängt stetig und reproduzierbar von der Zahl belichteter Ommatidien, von der Lichtintensität und vom Adaptationszustand des Auges ab (Abb. 5, 6, 7, 8, 10, 11 und 12).Die Amplituden der Belichtungsrhythmen klingen bei längerer Belichtung allmählich ab (Helladaptation), (Abb. 1C, Abb. 5). Die Heiladaptationszeit ist der Maximalamplitude proportional (Abb. 6, 8, 9 und 10). Wird die Belichtung vor dem völligen Abklingen der Rhythmen unterbrochen, so werden sie durch den Aus-Effekt des Retinogramms gehemmt und brechen sofort und vollkommen ab (Abb. 1 D). Die Dunkeladaptation ist selbst nach vorangegangener Belichtung mit sehr hohen Lichtintensitäten nach spätestens einer Minute abgeschlossen (Abb. 6 und 7).Die Frequenz der Belichtungsrhythmen liegt zwischen 100 sec^–1 und 250 sec^–1, sie nimmt mit steigender Temperatur zu (Tabelle 1). Die Frequenz ist unabhängig von der Lichtintensität, vom Adaptationszustand d von der Zahl belichteter Ommatidien.Während der einzelnen Belichtung zeigen die Rhythmen ein verschieden starkes Schwanken der Amplitude, eine Amplitudenmodulation. Die Modulation hängt vom Präparat und vom Präparationszustand ab.Durch den Vergleich der verschiedenen Modulationstypen und durch gleichzeitige Ableitung an mehreren Stellen des Ganglions können die physikalischen Überlagerungsvorgänge untersucht werden. Die Einzelschwingungen physiologischer Einheiten überlagern sich am gemeinsamen Ableitwiderstand zwischen den Elektroden. Durch die Art der Überlagerung wird die Modulationsform bestimmt. Sie hängt im besonderen von der Frequenz und der Phasenlage der Einzelrhythmen und von physiologischen Synchronisationsvorgängen ab (Abb. 1, 2 und 16).Auch wenn ein Bereich der Retina gereizt wird, der nur wenige Sinneszellen umfaßt, treten Belichtungsrhythmen wie bei großen Reizflächen auf (Abb. 12). Deshalb wird die Möglichkeit diskutiert, daß bereits die kleinste physiologische Einheit im Ganglion mit rhythmischer Erregung antwortet, die in ihrer Amplitude, nicht aber in ihrer Frequenz vom Reiz abhängt.Herrn Prof. Dr. H. Autrum danke ich für das stete Interesse, das er den Untersuchungen entgegengebracht hat. Die Untersuchungen wurden zum Teil mit Apparaten durchgeführt, die die Deutsche Forschungsgemeinschaft Herrn Prof. Autrum zur Verfügung stellte.     

Salivary gland development in the blowfly,Calliphora erythrocephala

The salivary gland of adult Calliphora erythrocephala is a tubular structure composed of secretory, reabsorptive, and duct regions. Development of these structures has been followed during the six days of larval and ten days of pupal growth. Two small groups of imaginal cells located at the junction between larval gland and duct give rise to the adult gland. These presumptive adult cells divide during all larval stages and appear to be functional components of the larval gland. Shortly after pupation, the larval gland breaks down and the imaginal cells proliferate rapidly, forming sequentially the duct, reabsorptive and secretory regions. Proliferating regions of the developing gland are frequently encrusted with haemocytes. As it elongates the gland establishes intimate contacts first with the basement membrane of the degenerating larval gland, later with an epithelial layer surrounding the main dorsal tracheal trunks, and then with the gut. Cell division continues until about five days after pupation, bu t the gland is unable to secrete fluid in response to 5-hydroxytryptamine stimulation until two hours after the adult fly emerges. The Golgi complex appears to be involved in forming the highly folded membranes of the canaliculi in the secretory region. Presumptive adult salivary gland cells appear to increase in number logarithmically from the time of hatching of the larva until five days after pupation. This contrasts with the development of classical imaginal discs, in which cell division ceases prior to pupation.     

Extracellular ribosomes during metamorphosis in the blowfly Calliphora erythrocephala

During metamorphosis of the blowfly Calliphora erythrocephala extracellular ribosomes, in the form of monosomes, appear in the body fluid. The total number of ribosomes, i.e. intracellular and extracellular, remains approximately constant during this period, whereas the proportion of extracellular ribosomes first rises, plateaus, and then declines in a manner suggesting that their appearance is a result of larval tissue breakdown.