Development of the indirect flight muscles of Drosophila.

We have followed the pupal development of the indirect flight muscles (IFMs) of Drosophila melanogaster. At the onset of metamorphosis larval muscles start to histolyze, with the exception of a specific set of thoracic muscles. Myoblasts surround these persisting larval muscles and begin the formation of one group of adult indirect flight muscles, the dorsal longitudinal muscles. We show that the other group of indirect flight muscles, the dorsoventral muscles, develops simultaneously but without the use of larval templates. By morphological criteria and by patterns of specific gene expression, our experiments define events in IFM development.     

The developmental profile of paramyosin and other myofibrillar proteins of larval and imaginal thoracic muscles of Lepidoptera

The synthesis of paramyosin and other myofibrillar proteins of the thoracic muscles of the tobacco hornworm Manduca sexta was studied by immunological and electrophoretical methods during the histolysis of the larval thoracic muscles and the differentiation of the indirect flight muscles. Antigens of the myofibrillar proteins in the thoracic muscles of the last-larval stage cross reacted with those in the flight muscles of the adults against polyspecific antibodies from actomyosin and monospecific antibodies from paramyosin. After the breakdown of the larval thoracic muscles (2 days from larval-pupal ecdysis) these antigens can no longer be detected in the thorax. The results indicate an almost complete removal of the larval thoracic muscles. Paramyosin could be identified again in a homogenate of the thoracic muscles of animals on the 13th day from larval-pupal ecdysis. Paramyosin is the first protein found during the differentiation of the flight muscles. The other myofibrillar proteins could be identified in thoracic homogenates of pharate adults of Manduca sexta on the 14th and 15th day from larval-pupal ecdysis. On the 14th day from larval-pupal ecdysis the dorso-longitudinal muscle and the tergosternal muscles show cross-striation, and the appearance of most of the electrophoretical results are in accordance with immunological and morphological findings. The myofibrillar proteins of the indirect flight muscles of Manduca sexta are synthesized de novo during metamorphosis.     

Micro-computed tomography of pupal metamorphosis in the solitary bee Megachile rotundata

Insect metamorphosis involves a complex change in form and function. In this study, we examined the development of the solitary bee, Megachile rotundata, using micro-computed tomography (μCT) and volume analysis. We describe volumetric changes of brain, tracheae, flight muscles, gut, and fat bodies in prepupal, pupal, and adult M. rotundata. We observed that individual organ systems have distinct patterns of developmental progression, which vary in their timing and duration. This has important implications for commercial management of this agriculturally relevant pollinator.     

The nymphal-adult molt of the silverleaf whitefly (Bemisia argentifolii): Timing,regulation, and progress

The developmental progress of silverleaf whitefly (Bemisia argentifolii) 3rd instars and 4th instar/pharate adults was monitored using a tracking system that had been designed to identify synchronous individuals in another species of whitefly, the greenhouse whitefly, Trialeurodes vaporariorum. When reared on greenbean under conditions of LD 16:8 and a temperature of 26 +/- 2 degrees C, the body depth of 3rd instar SLWFs increased from approximately 0.04 mm (Stage 2) to 0.175-0.2 mm (Stage 7-8) and the body depth of the 4th instar increased from approximately 0.1 mm (Stage 1) to 0.25-0.30 mm (Stage 4-5). The durations of the 3rd instar and the 4th instar/pharate adult were approximately 3 and 7 days, respectively. Examination of coronal sections of 4th instars revealed that adult eye and wing development are initiated during Stage 6, the stage in which an external examination showed that the eye has begun to undergo pigment diffusion. Ecdysteroid titers peaked at approximately 400 fg/ micro g protein during stages 4 through 6A of the 4th instar, i.e., just prior to and upon the initiation of the pharate adult stage. Although adult development is initiated later in the SLWF than in the GHWF (adult eye and wing development begin in Stages 4 and 5, respectively, in GHWFs), the same rapidity of metamorphosis is observed in both species. Within approximately 24 h, the simple bi-layered wing bud developed into a deeply folded wing of nearly adult proportions and within an additional 12-24 h, the nymphal eye and wing bud had been replaced by the well-differentiated eye and wing of the adult whitefly. Our study is the first to describe the regulation, timing, and progress of the nymphal-adult molt and of the structural changes that accompany nymphal-adult metamorphosis in the SLWF.     

Glial cells in adult and developing prothoracic ganglion of the hawk moth Manduca sexta

The glial cells of the prothoracic ganglion of the hawk moth Manduca sexta were studied in histological sections of several postembryonic stages and classified according to cell morphology, size, staining properties, and topographical relationships. In general, each glial cell type was found to be confined to one of the major ganglionic domains and each of these domains (i.e., perineurium, cell body rind, glial cover of the neuropil, and neuropil) was found to comprise specific cell types. Some types of glia were recognized in both larval and later stages, but other types were found exclusively from late pupal stages. It is proposed that the higher morphological diversity expressed by the glia of the pharate adult is attained by differentiation of new cell types during metamorphosis. Before the differentiation of new cell types, extensive cell death and cell proliferation seem to occur within some glial subpopulations.     

Coordination between the electrical activity of developing indirect flight muscles and the firing activity of a population of neurosecretory cells in the silkmoth, Bombyx mori

The developing indirect flight muscles of pharate moths are characterized by a rhythmic discharge of a long bout of flight-pattern-like muscle potentials in the absence of contractions. The electrical activity of the dorsal longitudinal flight muscles (DLMs) in the silkmoth, Bombyx mori, was discernible as a cluster of many series of muscle potentials that last for several minutes on day 4 of the pupal period. The duration of the active phases and the period of rhythmic activity gradually increased to a peak value on day 7 or 8 and then declined until the end of the pupal period. Mean duration of the active phases (+/-SD) and the mean period of the rhythmic activity (+/-SD) at the peak were 38.7+/-8.7 min and 74.5+/-7.3 min, respectively. The rhythmic electrical activity of immature DLMs was closely coordinated with the rhythmic (bursting) activity of a population of neurosecretory cells that are known to produce pheromone-biosynthesis activating neuropeptide (PBAN) and its related peptides, which belong to the multifunctional peptide family, pyrokinin/PBAN. The DLMs always became active a few minutes after the neurosecretory cells, and the timing of onset of these two activities appeared to be strictly regulated by a neural mechanism. The implication of the coordinated activity for development and maturation of imaginal tissues, including the flight motor system, and possible functions of the neuropeptides in this development are discussed.     

Disturbance of adult eclosion by fenoxycarb in the silkworm,Bombyx mori

Fenoxycarb treatment before and after pupal ecdysis of Bombyx mori disturbed adult eclosion and the animals were unable to escape from the pupal exuviae. This effect of fenoxycarb was dose and time dependent with the highest sensitivity around the pupal ecdysis. The sensitivity rapidly diminished within 20 hours of pupal ecdysis. Twenty-hydroxyecdysone (20E) produced similar effects. Fenoxycarb injection at the pupal ecdysis induced higher ecdysteroid production by the prothoracic glands and higher PTTH-secretory activity in the brain-corpora cardiaca-corpora allata complexes. As a result, the fenoxycarb treated pupae contained higher ecdysteroid titres in the haemolymph. Both the fenoxycarb and the 20E treatments resulted in the lack of development of the rectum in pharate adults. This was the main cause of high ecdysteroid titres in the pharate adult stage. This effect was mimicked by either removal of the rectum early in the pharate adult stage or a surgical extirpation of the hindgut at the time of pupal ecdysis. These results suggest that the disturbance of adult eclosion by fenoxycarb is due in part to the inability of the formation of the rectum in the pharate adult stage.     

Entrainment of eclosion and preliminary ontogeny of circadian clock gene expression in the flesh fly,Sarcophaga crassipalpis

Timing of circadian activities is controlled by rhythmic expression of clock genes in pacemaker neurons in the insect brain. Circadian behavior and clock gene expression can entrain to both thermoperiod and photoperiod but the availability of such cues, the organization of the brain, and the need for circadian behavior change dramatically during the course of insect metamorphosis. We asked whether photoperiod or thermoperiod entrains the clock during pupal and pharate adult stages by exposing flies to different combinations of thermoperiod and photoperiod and observing the effect on the timing of adult eclosion. This study used qRT-PCR to examine how entrainment and expression of circadian clock genes change during the course of development in the flesh fly, Sarcophaga crassipalpis. Thermoperiod entrains expression of period and controls the timing of adult eclosion, suggesting that the clock gene period may be upstream of the eclosion pathway. Rhythmic clock gene expression is evident in larvae, appears to cease during the early pharate adult stage, and resumes again by the time of adult eclosion. Our results indicate that both patterns of clock gene expression and the cues to which the clock entrains are dynamic and respond to different environmental signals at different developmental stages in S. crassipalpis.     

Fat-body remodeling in Drosophila melanogaster

The remodeling of the larval fat body is observed in many insects during metamorphosis, but little is known about the physiological importance or the regulation of this process. In Drosophila melanogaster, fat-body remodeling involves the dissociation of the fat body into individual fat cells, which persist throughout pupal development but are later removed by cell death in the young adult. Inhibition of fat-body dissociation is associated with pharate adult lethality and thus is likely to be an essential developmental event. As a start toward understanding the role of fat-body remodeling in the life history of insects, we carried out a detailed study of fat-body disassociation in D. melanogaster using fluorescent microscopy, and tested whether this process is mediated by hemocytes as proposed for fat-body remodeling in Sarcophaga peregrina. We identified and correlated stereotypic events in fat-body dissociation with developmental changes during metamorphosis, and have demonstrated by cell ablation studies that fat-body remodeling in D. melanogaster is a hemocyte independent process.     

Metamorphosis of Wing Motor System in the Silk Moth, Bombyx mori: Origin of Wing Motor Neurons

The origin of the peripheral nerve and motor neurons that innervate the adult mesothoracic dorsal longitudinal muscles (DLMs) was examined in the silk moth, Bombyx mori . The anatomical features of the peripheral nerve and motor neurons were investigated by dissection, electron microscopy, and cobalt back-fill staining at different pupal stages. These studies showed that the peripheral nerve (IIN1c) that innervates the adult DLMs originates from a branch (db branch) of the larval mesothoracic dorsal nerve that innervates the larval DLMs. During metamorphosis the larval nerve shortens or lengthens locally without change in its basic branching pattern, and the db branch moves towards the mesothoracic ganglion to become the IIN1c. All the adult DLM motor neurons are from larval ones. Nine of the 14 larval DLM motor neurons survive during metamorphosis to become adult DLM motor neurons, and 5 disappear in early pupal stages.     

Critical periods for developmental acclimation to cold in the Queensland fruit fly, Dacus tryoni

Rapid acclimation to cold can occur in Dacus tryoni during two short stages of its life history: the stage immediately prior to the “hopping larva” phase and the “pharate adult” stage within the puparium. Transfer from 25 to 15°C at either of these stages can produce full acclimation to cold within a few days. Acclimation is not detectable at other times in puparial life: during adult life it takes over 100 days.     

Die Bildung spezifischer Proteine während der Metamorphose der Speicheldrüsen von Wilhelmia lineata (Simuliidae)

Histolysis of pupal salivary glands and their further development during metamorphosis of Wilhelmia lineata were investigated by light microscopy. After pupal-adult apolysis the distal parts of the glands degenerate. The adult gland develops from a ring of tightly packed very small cells with small nuclei at the anterior end of the degenerating pupal gland. The gland of the female pharate adult consists of a spherical accessory gland with small cells and oval nuclei and a little U-shaped main gland with larger cells and round nuclei. The two U-shaped lobes are orientated horizontally. The gland of the male pharate adult has the same shape and cellular structure as the accessory gland of the female. During further development the main gland becomes greatly elongated as the cells increase in size, the cells become flattened, and the secretion of saliva into the gland lumen can be seen. The glands are fully differentiated at the time of pupal-adult ecdysis. Soluble proteins from the one-day-old female pharate adult show a very similar pattern to those of pupal and male glands. With growth of the female main gland and secretion of saliva into the gland lumen increasing amounts of proteins, which have been characterized earlier (Poehling et al., 1976) occur in the gland. This could suggest a specific rôle of these proteins during bloodsucking in the adult females.     

Physiological trade‐offs between flight muscle and reproductive development in the wing‐dimorphic cricket Velarifictorus ornatus

Morphology, flight muscles, and reproductive development were compared between long‐winged (LW) and short‐winged (SW) morphs of the cricket Velarifictorus ornatus (Shiraki) (Orthoptera: Gryllidae). There was no difference in body weight and pre‐oviposition between the two morphs, but LW individuals had better‐developed flight muscles than SW individuals during and after emergence of the adult. The flight muscles at adult emergence represented 11.9% of the total body weight in the LW female and 4.9% in the SW female. In addition, the weight of the flight muscle of LW females increased by 50% during the first 5 days, whereas the flight muscle of the SW variant increased only slightly after adult emergence. The process of oviposition in LW, SW, and de‐alated females varied: SW females produced more eggs at the early stage than LW females, but de‐alation could shorten the time until the peak of egg laying and caused histolysis of flight muscles of LW females. There was no significant difference in total egg production between the above three groups. In the male, unlike the female, the accessory glands of the two wing morphs enlarged continuously at the same rate. There was no difference between the two wing morphs in the mass of the testes during the first 7 days after adult emergence.     

Gene-controlled incorporation of haemolymph protein into the ovaries of Bombyx mori

The haemolymph protein concentration in Bombyx mori decreases normally by about one-fourth during pharate adult development. In females homozygous for the small egg gene, the concentration of haemolymph protein remained constant throughout the pupal and pharate adult stages. The sm gene does not influence the synthesis of vitellogenic female protein of pupal and pharate adult haemolymph (FP). Normal ovaries transferred to the haemocoele of sm females undergo normal vitellogenesis. In the absence of normal alleles of sm, the ovaries encounter difficulties in the incorporation of FP into their oöcytes from pharate adult haemolymph. These results suggest that an active translocation mechanism is involved in the transfer of haemolymph protein into the ovaries.     

Ecdysteroid regulation of olfactory protein expression in the developing antenna of the tobacco hawk moth,Manduca sexta

During adult metamorphosis, the moth olfactory neurons and their glia-like support cells pass through a coordinated and synchronous development. By 60% of development, the olfactory system is anatomically complete, but functional maturation does not occur until about 90% of development. Maturation is characterized by the onset of odorant sensitivity in the sensory neurons and the expression of certain antennal-specific proteins including odorant binding proteins (OBPs) and odorant degrading enzymes (ODEs). The OBPs have been cloned and sequenced, and are thus useful models for investigating the molecular mechanisms coordinating final maturation of the developing olfactory system. The ecdysteroid hormones have been observed to regulate many cellular level neuronal changes during adult metamorphosis. In particular, the late pupal decline in ecdysteroids is known to influence programmed death of nerves and muscles at the end of metamorphoses. Experiments are presented here which indicate that this decline in ecdysteroids also induces the expression of the OBPs. Normal OBP expression occurs 35–40 h before adult emergence. In culture, OBP expression could be induced at least 90 h before adult emergence by the premature removal of ecdysteroid. This premature expression was blocked by culturing tissue in the presence of the biologically active ecdysteroid 20-hydroxyecdysone. These findings suggest that maturation of the olfactory system is regulated by the decline in ecdysteroids, and support the view that olfactory development, in general, may be coordinated by chaging levels of pupal ecdysteroids. © 1993 John Wiley & Sons, Inc.     

X-ray investigation of gas bubble formation, and water loss in tsetse fly pupae

ABSTRACT. Using a microfocal X-ray apparatus, a gas bubble was detected within the puparium of Glossina morsitans. The bubble appeared between 6 and 15 h after pupariation and was associated with one of the longitudinal tracheal trunks of the third instar larva. The bubble grew and achieved maximum size approximately 96 h after pupariation. It then disappeared at the time of eversion of the pupal appendages. There was a close correlation between bubble size and the weight of water lost since the time of pupariation. At the time of eversion of the pupal appendages the gas bubble apparently passed out through the longitudinal tracheal trunk and posterior spiracle to occupy the space between larval (puparial) and pupal cuticle. It is suggested that the bubble plays a vital role in the separation of these cuticular layers and that to this end water loss from the puparium is essential.     

Myogenesis in Aplysia californica (Cooper, 1863) (Mollusca,Gastropoda, Opisthobranchia) with special focus on muscular remodeling during metamorphosis

To date only few comparative approaches tried to reconstruct the ontogeny of the musculature in invertebrates. This may be due to the difficulties involved in reconstructing three dimensionally arranged muscle systems by means of classical histological techniques combined with light or transmission electron microscopy. Within the scope of the present study we investigated the myogenesis of premetamorphic, metamorphic, and juvenile developmental stages of the anaspidean opisthobranch Aplysia californica using fluorescence F‐actin‐labeling in conjunction with modern confocal laser scanning microscopy. We categorized muscles with respect to their differentiation and degeneration and found three true larval muscles that differentiate during the embryonic and veliger phase and degenerate during or slightly after metamorphosis. These are the larval retractor, the accessory larval retractor, and the metapodial retractor muscle. While the pedal retractor muscle, some transversal mantle fibers and major portions of the cephalopedal musculature are continued and elaborated during juvenile and adult life, the buccal musculature and the anterior retractor muscle constitute juvenile/adult muscles which differentiate during or after metamorphosis. The metapodial retractor muscle has never been reported for any other gastropod taxon. Our findings indicate that the late veliger larva of A. californica shares some common traits with veligers of other gastropods, such as a larval retractor muscle. However, the postmetamorphic stages exhibit only few congruencies with other gastropod taxa investigated to date, which is probably due to common larval but different adult life styles within gastropods. Accordingly, this study provides further evidence for morphological plasticity in gastropod myogenesis and stresses the importance of ontogenetic approaches to understand adult conditions and life history patterns. J. Morphol., 2008. © 2007 Wiley‐Liss, Inc.     

Postembryonic development of centrally generated flight motor patterns in the hawkmoth, Manduca sexta

This study analyses the maturation of centrally generated flight motor patterns during metamorphosis of Manduca sexta. Bath application of the octopamine agonist chlordimeform to the isolated central nervous system of adult moths reliably induces fictive flight patterns in wing depressor and elevator motoneurons. Pattern maturation is investigated by chlordimeform application at different developmental stages. Chlordimeform also induces motor patterns in larval ganglia, which differ from fictive flight, indicating that in larvae and adults, octopamine affects different networks. First changes in motoneuron activity occur at the pupal stage P10. Rhythmic motor output is induced in depressor, but not in elevator motoneurons at P12. Adult-like fictive flight activity in motoneurons is observed at P16 and increases in speed and precision until emergence 2 days later. Pharmacological block of chloride channels with picrotoxin also induces fictive flight in adults, suggesting that the pattern-generating network can be activated by the removal of inhibition, and that proper network function does not rely on GABA_A receptors. Our results suggest that the flight pattern-generating network becomes gradually established between P12 and P16, and is further refined until adulthood. These findings are discussed in the context of known physiological and structural CNS development during Manduca metamorphosis.