Effect of x-irradiation on the formation of the puparium in the fleshfly, Sarcophaga bullata

Post-feeding, pre-critical stage larvae (36 hr before pupariation) of Sarcophaga bullata were exposed to X-rays and the effects on pupariation observed. With doses ranging from 1250 to 10,000 R the prepuparial period was prolonged and the duration of this delay increased with higher doses. Doses above 2500 R inhibited the retraction of anterior segments, longitudinal contraction and cuticular shrinkage resulting in larval-like tanned puparia. With the anterior part of the body shielded during irradiation, normal puparia were formed, but after a delay proportional to the area irradiated. Injection of β-ecdysone counteracted this delay. With the doses used, irradiation had no effect on post-critical stage larvae. This suggested that the CNS has a special mechanism which controls the neuromuscular processes of pupariation, and when this mechanism is damaged by irradiation larval-like puparia are formed. The pupariation delay was attributed to a temporary block in the synthesis, or release, or both of α-ecdysone (in whole-body or anteriorly only irradiated larvae) and its final conversion to β-ecdysone (in posteriorly only irradiated larvae). The fact that post-critical stage larvae are insensitive to irradiation suggests that the neuromuscular and neurosecretory processes which are affected by irradiation are already completed at that stage.     

Disruption of pupariation and eclosion behavior in the flesh fly, Sarcophaga bullata Parker (Diptera: Sarcophagidae), by venom from the ectoparasitic wasp Nasonia vitripennis (Walker) (Hymenoptera: Pteromalidae)

The action of venom from the ectoparasitic wasp, Nasonia vitripennis, was monitored by examining alterations in patterned muscular movements characteristic of pupariation and eclosion behavior in the flesh fly, Sarcophaga bullata. Venom injected into larvae prior to pupariation caused a dose-dependent delay in pupariation. Eventually, such larvae did pupariate, but puparia were abnormally formed. Barographic records revealed that all elements of pupariation behavior were present in venom-injected larvae, but pupariation behavior was not well synchronized with tanning, thus implying that the venom caused disruption in the temporal organization of central motor programs. When larvae were ligated and injected with venom posterior to the ligature, no response was evident in the posterior region, suggesting that the venom does not directly stimulate muscles or neuromuscular junctions. Injection of exogenous ecdysteroid into venom-injected larvae restored some elements of pupariation behavior, consistent with ecdysone's role in stimulating the release of anterior retraction factor and puparium tanning factor, two factors that are released from the CNS to regulate pupariation. When the venom was injected into newly emerged imagoes, the duration of extrication behavior was shortened, whereas all phases of post-eclosion behavior were lengthened. These observations imply that the venom affects CNS centers that regulate the muscular systems engaged in extrication and post-eclosion behavior.     

Haemolymph ecdysteroid titres in diapause- and non-diapause-destined larvae and pupae of Sarcophaga argyrostoma

No differences were observed between the rates of development of larvae and pupae from diapause- and non-diapause-destined lines of Sarcophaga argyrostoma except that those destined for diapause have a longer post-feeding, wandering, larval phase associated with a lower haemolymph ecdysteroid titre, as measured by radioimmunoassay. Following pupariation, both cultures show a high haemolymph titre associated with larval/pupal apolysis. The developing culture displays an ecdysteroid peak at 72 h after pupariation which may be involved with pupal/adult apolysis and the initiation of pharate-adult development. This peak is reduced in the diapause-destined culture. Following the initiation of pharate adult development, there is a very large peak at 85–90 h. Those pupae entering diapause display very low titres as a result of the failure of the brain/prothoracic gland axis to release ecdysone. There are no quantitative or qualitative differences between the titres of specific ecdysteroids in the prepupae of the two lines as determined by reverse-phase high-performance liquid chromatography. A preliminary examination of the levels of free and conjugated ecdysteroids has provided the basis for proposing a mechanism of ecdysone metabolism in this insect.     

Genetic and developmental analysis of puparium formation in Drosophila

Summary Five new mutants were isolated on the X-chromosome which prevent or substantially delay puparium formation and subsequent metamorphosis without affecting larval development. The mutant phenotype probably involves stage-specific gene functions unimportant for the larval development but vital for puparium formation and for the beginning of metamorphosis. Two mutants gave larval-puparial gynanders (LPG) and could not be induced to pupariate by the implanted wild type ring gland. The block in these is possibly in some ecdysone-inducible autonomous functions of the larval hypoderm. The other 3 mutants did not form LPG while the implanted wild type ring gland induced pupariation. These mutants presumably have a low, subthreshold amount of ecdysone which is not able to induce pupariation.     

The effects of starvation and 20-hydroxy-ecdysone on feeding and pupariation of early 3rd-instar Calliphora vicina larvae

At a larval body weight of 15–16 mg, young 3rd-instar Calliphora vicina larvae pass from the obligatory feeding phase, when starvation results in cessation of growth or development, to the facultative feeding phase when starvation leads to subsequent pupariation. During normal larval development the transition from obligatory to facultative feeding phase appears to be independent of 20-hydroxyecdysone but absence (or insufficiency) of the hormone is the likely reason why starved larvae in the obligatory feeding phase fail to pupariate. 20-Hydroxy-ecdysone induces termination of feeding by normal, facultative phase larvae and is the probable signal for larval commitment to pupariation.     

Role of the brain and ring gland in regulation of pupal diapause in the flesh fly Sarcophaga crassipalpis

Larvae of Sarcophaga crassipalpis photoperiodically programmed for pupal diapause pupariate later than larvae programmed for continuous development. Pupariation time is determined by the brain-ring gland complex as evidenced by transplantation experiments in which the timing of pupariation was transferred from one larva to another by transplantation of the brain-ring gland complex. The developmental commitment (diapause or nondiapause) of the larva also can be transferred with the brain-ring gland complex if the recipient's own neuroendocrine system is suppressed by ring gland extirpation. Thus, photoperiodic programming of the brain-ring gland complex is not only responsible for developmental commitment but also for determining the duration of the prepupal period. Surgical experiments with pupae indicate that an intact brain-ring gland complex is required for diapause termination and initiation of adult development. Pupae fail to break diapause if either the brain or the ring gland is removed or if their nervous connections are severed.     

Tracheal development in the Drosophila brain is constrained by glial cells

The Drosophila brain is tracheated by the cerebral trachea, a branch of the first segmental trachea of the embryo. During larval stages the cerebral trachea splits into several main (primary) branches that grow around the neuropile, forming a perineuropilar tracheal plexus (PNP) at the neuropile surface. Five primary tracheal branches whose spatial relationship to brain compartments is relatively invariant can be distinguished, although the exact trajectories and branching pattern of the brain tracheae are surprisingly variable. Immunohistochemical and electron microscopic studies demonstrate that all brain tracheae grow in direct contact with the glial cell processes that surround the neuropile. To investigate the effect of glia on tracheal development, embryos and larvae lacking glial cells as a result of a genetic mutation or a directed ablation were analyzed. In these animals, the tracheal branching pattern was highly abnormal. In particular, the number of secondary branches entering the central neuropile was increased. Wild-type larvae possess only two central tracheae, typically associated with the mushroom body and the antennocerebral tract. In larvae lacking glial cells, six to ten tracheal branches penetrate the neuropile in a variable pattern. This finding indicates that glia-derived signals constrained tracheal growth in the Drosophila brain and restrict the number of branches entering the neuropile.     

The effect of a juvenile hormone analogue on ecdysteroid titre during development and HnRNA formation in the moth,Ephestia cautella

The juvenile hormone analogue, methoprene was found to interfere with normal development of Ephestia in a manner dependent on age. Young embryos, prior to the stage of blastokinesis, and animals, shortly before and after pupation, were found to be the most sensitive to the compound. The JHA inhibited metamorphosis and produced giant larvae when it was given to immature larvae, however, when it was given to larvae 2–3 days prior to pupation or to young pupae it did not affect metamorphosis but prevented adult emergence. Comparison of the ecdysteroid titre determined in control and treated animals in the various developmental stages showed that JHA depressed the ecdysteroid titre totally only when it was given to young larvae and partially when it was applied shortly before pupation. It seems that the action of methoprene on ecdysone regulated systems and/or ecdysone producing systems in Ephestia appears to be mainly during the larval stage prior to the appearance of the small ecdysteroid peak and the formation of HnRNA in the transition period from larvae to pupae.     

Reduced titres of ecdysone following juvenile hormone treatment in the German cockroach, Blattella germanica

Changes in ecdysone titre of the larvae of the German cockroach, Blattella germanica, exposed continuously to the juvenile hormone (JH), or to the insect growth regulator (IGR) with JH activity, can be correlated with the nature of the substance applied, its dose, and the time of application. The younger larvae exposed to the high dose of the IGR die in the next ecdysis, whereas the same treatment induces a diapause-like stage of developmental arrest in the last larval stage. The affected larvae have very little or no ecdysone, the synthesis of which takes place in the second part of the instar. The same treatment after this period has a lesser effect. The extent of the effect is correlated to the amount of ecdysone synthesized before the application of IGR. Last instar larvae exposed to the lower dose of the IGR or JH lack the peak of ecdysone normally found in the controls at the end of the second third of the instar when metamorphosis takes place. In these insects the first rise of the ecdysone titre begins towards the end of the instar, and ecdysis into the supernumerary larval stage is initiated when the ecdysone titre reached a level permitting ecdysis.A direct or indirect antagonism between these hormones, both fundamental to insect development, can explain the morphogenetic, inhibitory, and lethal effects observed in insects treated with JH or IGR with JH activity.     

Correlations between juvenile hormone esterase activity,ecdysone titre and cellular reprogramming in Galleria mellonella

Juvenile hormone esterase (JHE) activity, ecdysone titre, and developmental competence of the epidermis were determined in last instar larvae and pupae of Galleria mellonella. Haemolymph JHE activity reaches a peak before increases are observed in ecdysone titre both during larval-pupal and pupal-adult metamorphosis. JHE activity is low during the penultimate larval instar although general esterase activity is relatively high. In last instar larvae two ecdysone peaks are noted after the increase in JHE activity. Furthermore, epidermal cell reprogramming occurs just after the increase in haemolymph JHE activity and possibly before the first increase in ecdysone titre. This was tested by injection of high doses of β-ecdysone into last instar larvae of different ages resulting in rapid cuticle deposition. Reprogramming occurred if the resulting cuticle was of the pupal type. These correlative observations may increase our understanding of the relative importance of an ecdysone surge in the absence of JH in reprogramming of the insect epidermis.     

Ontogeny of tracheal dimensions and gas exchange capacities in the grasshopper, Schistocerca americana

How does body size affect the structure and gas exchange capacities of insect tracheae? Do insects become more oxygen-limited as they grow? We addressed these questions by measuring the dimensions of two transverse tracheae within the abdomen of American locusts of different ages, and evaluating the potential for diffusion or convection to provide adequate gas exchange. The grasshopper abdomen has longitudinal tracheae that run along the midgut, heart, nerve cord, and lateral body wall. Transverse tracheae run from each spiracle to the longitudinal tracheae. Dorsal air sacs attach near each spiracle. In both transverse tracheae studied, diffusive capacities increased more slowly than metabolic rates with age, and calculated oxygen gradients necessary to supply oxygen by diffusion increased exponentially with age. However, surgical studies demonstrated that transport of gas through these transverse tracheae occurred by convection, at least in adults. Convective capacities paralleled metabolic rates with age, and the calculated pressure gradients required to sustain oxygen consumption rates by convection were independent of age. Thus, in growing grasshoppers, tracheal capacities matched tissue oxygen needs. Our morphological and physiological data together suggest that use of convection allows older grasshoppers to overcome potential limitations on size imposed by diffusion through tracheal systems.     

Epithelial polarity and cell separation in the neoplastic l(1)dlg-1 mutant of Drosophila.

Lethal (1) discs-large-1 [l(1)dlg-1] is a non-epithelial overgrowth or neoplastic mutant of Drosophila, which results in tumor-like imaginal discs and enlarged larvae that never pupariate. In an ultrastructural analysis we found that the wing discs develop convoluted monolayers of epithelial cells characterized by well-defined apical-basal polarity and that these layered cells secrete large amounts of basement membrane material. Immuno-EM indicates that Drosophila laminin and collagen are components of this matrix. Late in development clusters or 'rosettes' of separated cells lacking cell-cell junctions and apical-basal polarity form. In in vitro culture experiments l(1)dlg-1 wing discs did not respond to a pulse of exogenous ecdysone by secreting cuticle or losing basement membrane as normal discs do. Our observations are consistent with the hypothesis that cell-cell interaction and communication is required for termination of disc cell proliferation, which must occur prior to a cellular response to ecdysone.     

Ontogeny of tracheal dimensions and gas exchange capacities in the grasshopper, Schistocerca americana

How does body size affect the structure and gas exchange capacities of insect tracheae? Do insects become more oxygen-limited as they grow? We addressed these questions by measuring the dimensions of two transverse tracheae within the abdomen of American locusts of different ages, and evaluating the potential for diffusion or convection to provide adequate gas exchange. The grasshopper abdomen has longitudinal tracheae that run along the midgut, heart, nerve cord, and lateral body wall. Transverse tracheae run from each spiracle to the longitudinal tracheae. Dorsal air sacs attach near each spiracle. In both transverse tracheae studied, diffusive capacities increased more slowly than metabolic rates with age, and calculated oxygen gradients necessary to supply oxygen by diffusion increased exponentially with age. However, surgical studies demonstrated that transport of gas through these transverse tracheae occurred by convection, at least in adults. Convective capacities paralleled metabolic rates with age, and the calculated pressure gradients required to sustain oxygen consumption rates by convection were independent of age. Thus, in growing grasshoppers, tracheal capacities matched tissue oxygen needs. Our morphological and physiological data together suggest that use of convection allows older grasshoppers to overcome potential limitations on size imposed by diffusion through tracheal systems.     

The control of prepupal puffing patterns in vitro; Implications for prepupal ecdysone titres in Drosophilia melanogaster

In late third instar larvae and prepupae of Drosophila melanogaster there is a complex change in puffing patterns in the salivary gland chromosomes. There are two peaks of activity in this period. The first, in larvae, is known to be under the control of the moulting hormone ecdysone. The second, in prepupae, is now shown by the in vitro culture of prepupal glands to be under the specific control of β-ecdysone in a manner similar to the first. A new class of puffs, active between these two peaks, whose induction is inhibited by ecdysone in vitro, is described. The behaviour of these puffs, exemplified by 75CD and 63E, suggests a period of very low ecdysone titre in vivo. The developmental significance of the role of ecdysone during prepupal development is discussed.     

On the control of ecdysone biosynthesis by the central nervous system of blowfly larvae

Ecdysone was found to be the major secreted steroid of ring glands dissected from blowfly larvae and incubated in vitro. Other secretory products such as 3-dehydroecdysone and 20-deoxy-makisterone A could not be detected when the glands were labelled with tritiated cholesterol. Ecdysone synthesis and secretion were found to be tightly coupled. The highest rate of secretion was observed a few hours before pupariation. In vitro, the rate of ecdysone secretion by ring glands was affected significantly by coincubation with the central nervous system (CNS). Modulating effects from the CNS to the gland were mediated both by culture medium and by nerve connections. Distinct parts of the CNS revealed multiple and partially opposite effects on ecdysone secretion, suggesting a more complex control than had been anticipated. Multiple neural control systems appear to be involved. Moreover, the observed effects changed with development during the second half of the third instar, reflecting a significant plasticity of neural control. © 1993 Wiley-Liss, Inc.     

Involvement of mind the gap in the organization of the tracheal apical extracellular matrix in Drosophila and Nilaparvata lugens

The tracheal apical extracellular matrix (aECM) is vital for expansion of the tracheal lumen and supports the normal structure of the lumen to guarantee air entry and circulation in insects. Although it has been found that some cuticular proteins are involved in the organization of the aECM, unidentified factors still exist. Here, we found that mind the gap (Mtg), a predicted chitin‐binding protein, is required for the normal formation of the apical chitin matrix of airway tubes in the model holometabolous insect Drosophila melanogaster. Similar to chitin, the Mtg protein was linearly arranged in the tracheal dorsal trunk of the tracheae in Drosophila. Decreased mtg expression in the tracheae seriously affected the viability of larvae and caused tracheal chitin spiral defects in some larvae. Analysis of mtg mutant showed that mtg was required for normal development of tracheae in embryos. Irregular taenidial folds of some mtg mutant embryos were found on either lateral view of tracheal dorsal trunk or internal view of transmission electron microscopy analysis. These abnormal tracheae were not fully filled with gas and accompanied by a reduction in tracheal width, which are characteristic phenotypes of tracheal aECM defects. Furthermore, in the hemimetabolous brown planthopper (BPH) Nilaparvata lugens, downregulation of NlCPAP1‐N (a homolog of mtg) also led to the formation of abnormal tracheal chitin spirals and death. These results suggest that mtg and its homolog are involved in the proper organization of the tracheal aECMs in flies and BPH, and that this function may be conserved in insects.     

Regulation of ecdysone hydroxylation in Locusta migratoria: Rôle of the moulting hormone level

After repetitive injections of moderate doses of ecdysone, ecdysterone or phenobarbital to young Vth (last) instar larvae of Locusta migratoria, the conversion rate of ecdysone to ecdysterone in vivo is significantly higher than in control insects. Similarly, 5 hr after injection of a low dose of ecdysone or ecdysterone, a strong ‘induction’ of ecdysone 20-monooxygenase activity occurs. This ‘inductive’ effect is blocked by cycloheximide.Simultaneous injections of ecdysone and ecdysterone show that hydroxylation of ecdysone is inhibited by the product of the reaction, ecdysterone. Removal of the prothoracic glands and X-ray treatment of the hemocytopoietic tissue do not affect ecdysone hydroxylation. The mechanism of induction and inhibition of ecdysone 20-monooxygenase shown in this study is probably responsible for the important variations of this key enzyme which have been reported from several insect species.