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.     

Changes in ecdysone titre during pupal-adult development in the silkworm, Bombyx mori

Changes in the ecdysone titre of the silkworm, Bombyx mori, during pupal-adult development were estimated. The average value of the maximum titre, which was observed on the second day after pupal ecdysis, was about 0·8 μg equivalent of β-ecdysone/g of live weight in both sexes.

There is a distinct sexual dimorphism in the pattern of the ecdysone titre. The male exhibited a single sharp peak on the second day whereas the female showed the second peak on the fifth day. When the female was ovariectomized, the ‘female type’ ecdysone pattern was converted to the ‘male type’. In the female pharate adult 7 days after pupal ecdysis, ecdysone activity accumulated in the ovaries.

The relationship between the ecdysone titre and adult differentiation, especially during ovarian development, is discussed.     

Changes in the activity of dopa quinone imine conversion factor during the development of Bombyx mori

The activity of DOPA quinone imine conversion factor (QICF) in tissues at different developmental stages of the silkworm, Bombyx mori, was determined. QICF activity was detected in all developmental stages from egg to pupa although the activities, other than in fifth instar larvae, were quite low. Activity in whole larvae peaked one day before the onset of larval-pupal development and declined to a low level shortly before ecdysis. In whole pupae, maximal QICF activity was obtained 1 h after pupation. The activity in larval cuticles was elevated on the last day of the fourth instar and again between days 4 and 8 of the fifth instar, decreasing to very low levels before pupal ecdysis. QICF was detectable in pupal cuticles with most of the pupal activity found in homogenates of mid and hind guts. A major part of the total larval QICF activity was found in hemolymph. Activity in hemolymph varied in a different manner from that in cuticles, with markedly raised levels immediately before pupal ecdysis when the cuticular activity had declined. It is postulated that QICF in cuticles plays some role in wound healing and/or sclerotizatio,, while QICF in hemolymph participates in melanization in the humoral immune system.     

Developmental expression and hormonal regulation of different isoforms of the transcription factor E75 in the tobacco hornworm Manduca sexta

E75A and E75B, isoforms of the E75 orphan nuclear receptor, are sequentially up-regulated in the abdominal epidermis of the tobacco hornworm Manduca sexta by 20-hydroxyecdysone (20E) during larval and pupal molts, with E75A also increasing at pupal commitment (Zhou et al., Dev. Biol. 193, 127-138, 1998). We have now cloned E75C and show that little is expressed in the epidermis during larval life with trace amounts seen just before ecdysis. Instead, E75C is found in high amounts during the development of the adult wings as the ecdysteroid titer is rising, and this increase was prevented by juvenile hormone (JH) that prevented adult development. By contrast, E75D is expressed transiently during the larval and pupal molts as the ecdysteroid titer begins to decline and again just before ecdysis, but in the developing adult wings is expressed on the rise of 20E. Removal of the source of JH had little effect on either E75C or E75D mRNA expression during the larval and pupal molts. At the time of pupal commitment, in vitro experiments show that 20E up-regulates E75D and JH prevents this increase. Neither E75A nor E75D mRNA was up-regulated by JH alone. Thus, E75C is primarily involved in adult differentiation whereas E75D has roles both during the molt and pupal commitment.     

Light and electron microscopic studies on the neurosecretory control of diapause incidence in Pieris rapae crucivora

The incidence of diapause was shown to be determined humorally during the larval-pupal ecdysis by means of brain extirpation experiments.On the basis of this observation, light and electron microscopic changes in the neurosecretory type II cells in the pars intercerebralis-corpus cardiacum system during pharate pupal and early pupal stages were examined in insects reared under long day-length (non-diapause individuals) and in insects reared under short day-length (diapause individuals). In the diapause individuals, neurosecretory granules in NS-II cells increased during the pupal instar and large aggregates of granules packed the cytoplasm. Thereafter, inclusion bodies showing cytoplasmic breakdown of the granules appeared.In the non-diapause individuals, on the contrary, electron micrographs suggesting the release of neurosecretory material from axon terminals were obtained just after the pupal ecdysis. There were very few granules, with many Golgi bodies and much rough ER 8 to 12 hr after the ecdysis.It is concluded that adult development is determined by the release of neurosecretory material from the axon terminals of NS-II cells at the larval-pupal ecdysis. If release does not occur, the pupae enter diapause. It is also thought that differences in day-length during the larval stages influence the activities of NS-II cells before pupation.     

Dynamics and metamorphosis of an identifiable peptidergic neuron in an insect

Eclosion hormone (EH) is a 7000 Da peptide that triggers ecdysis behavior in insects. In the moth, Manduca sexta, EH is found in two pairs of ventromedial (VM) cells in the brain which send their axons down the ventral nerve cord to a neurohemal site in the proctodeal nerve in the larva and pupa. During adult development, these cells send axon collaterals to the corpora cardiaca where they form a new release site used for adult eclosion. Studies of bioassayable peptide during the 5th larval instar and the larval-pupal transformation revealed that after depletion at ecdysis, the VM cells showed a transient increase in EH found in their cell bodies and axons. By contrast, their terminals in the proctodeal nerve showed a gradual accumulation of peptide followed by a release of over 90% of the stored material at pupal ecdysis. In situ hybridization analysis on whole mounts of the brains showed that the VM cells always contained EH mRNA with increased accumulation during the larval and pupal molting periods with a slight decline just before ecdysis. High levels of EH mRNA were found in brains of diapausing pupae. During the first two-thirds of adult development, mRNA accumulated to high levels, then slowly declined until ecdysis. EH mRNA levels up to 3 days after adult eclosion. At no time was EH mRNA found in the lateral neurosecretory cell cluster previously reported to produce EH for adult eclosion. 1994 John Wiley & Sons, Inc.     

Bursicon in the mealworm, Tenebrio molitor L. and its role in the control of postecdysial tanning

Using the adult Calliphora bioassay, we found that the tanning hormone, bursicon, is present in the blood of pupal and adult Tenebrio only at the time of ecdysis, when it is released massively from the thoracic and abdominal central nervous system. The hormone's half life in the blood is short (about 1–2 h). Contrary to the findings of other workers, we could find no evidence for the presence of the hormone in the haemolymph during pharate adult development, before ecdysis begins. When newly ecdysed pupae were ligated about the neck, adult development of the thorax and abdomen proceeded normally, but postecdysial tanning of the adult cuticle was almost completely prevented. This failure to tan was not due to lack of bursicon as the hormone was released normally in the ligated animals at the time of ecdysis. This suggests that a pre-ecdysial signal may be required for the development of epidermal competence to respond to bursicon.     

BIOSYNTHESIS OF ECDYSONE IN THE ISOLATED ABDOMEN OF THE SILKWORM,BOMBYX MORI*

During pupal-adult development of the silkworm, Bombyx mori, the ecdysone titer changes, exhibiting two maxima in the females: one on the second day of pupal development and the other just before adult emergence. During the second maximum, ecdysone accumulates in the ovaries. It also accumulates in isolated abdomens, which were prepared just after pupal ecdysis and induced to initiate adult development by injection with β-ecdysone. Several lines of evidence suggest that ecdysone is synthesized in the ovary itself.     

Circadian regulation of the lark RNA-binding protein within identifiable neurosecretory cells

Molecular genetic analysis indicates that rhythmic changes in the abundance of the Drosophila lark RNA-binding protein are important for circadian regulation of adult eclosion (the emergence or ecdysis of the adult from the pupal case). To define the tissues and cell types that might be important for lark function, we have characterized the spatial and developmental patterns of lark protein expression. Using immunocytochemical or protein blotting methods, lark can be detected in late embryos and throughout postembryonic development, from the third instar larval stage to adulthood. At the late pupal (pharate adult) stage, lark protein has a broad pattern of tissue expression, which includes two groups of crustacean cardioactive peptide (CCAP)-containing neurons within the ventral nervous system. In other insects, the homologous neurons have been implicated in the physiological regulation of ecdysis. Whereas lark has a nuclear distribution in most cell types, it is present in the cytoplasm of the CCAP neurons and certain other cells, which suggests that the protein might execute two different RNA-binding functions. Lark protein exhibits significant circadian changes in abundance in at least one group of CCAP neurons, with abundance being lowest during the night, several hours prior to the time of adult ecdysis. Such a temporal profile is consistent with genetic evidence indicating that the protein serves a repressor function in mediating the clock regulation of adult ecdysis. In contrast, we did not observe circadian changes in CCAP neuropeptide abundance in late pupae, although CCAP amounts were decreased in newly-emerged adults, presumably because the peptide is released at the time of ecdysis. Given the cytoplasmic localization of the lark RNA-binding protein within CCAP neurons, and the known role of CCAP in the control of ecdysis, we suggest that changes in lark abundance may regulate the translation of a factor important for CCAP release or CCAP cell excitability.     

Retrograde BMP signaling controls Drosophila behavior through regulation of a peptide hormone battery

Retrograde BMP signaling in neurons plays conserved roles in synaptic efficacy and subtype-specific gene expression. However, a role for retrograde BMP signaling in the behavioral output of neuronal networks has not been established. Insect development proceeds through a series of stages punctuated by ecdysis, a complex patterned behavior coordinated by a dedicated neuronal network. In Drosophila, larval ecdysis sheds the old cuticle between larval stages, and pupal ecdysis everts the head and appendages to their adult external position during metamorphosis. Here, we found that mutants of the type II BMP receptor wit exhibited a defect in the timing of larval ecdysis and in the completion of pupal ecdysis. These phenotypes largely recapitulate those previously observed upon ablation of CCAP neurons, an integral subset of the ecdysis neuronal network. Here, we establish that retrograde BMP signaling in only the efferent subset of CCAP neurons (CCAP-ENs) is required to cell-autonomously upregulate expression of the peptide hormones CCAP, Mip and Bursicon β. In wit mutants, restoration of wit exclusively in CCAP neurons significantly rescued peptide hormone expression and ecdysis phenotypes. Moreover, combinatorial restoration of peptide hormone expression in CCAP neurons in wit mutants also significantly rescued wit ecdysis phenotypes. Collectively, our data demonstrate a novel role for retrograde BMP signaling in maintaining the behavioral output of a neuronal network and uncover the underlying cellular and gene regulatory substrates.     

Targeted ablation of CCAP neuropeptide-containing neurons of Drosophila causes specific defects in execution and circadian timing of ecdysis behavior

Insect growth and metamorphosis is punctuated by molts, during which a new cuticle is produced. Every molt culminates in ecdysis, the shedding of the remains of the old cuticle. Both the timing of ecdysis relative to the molt and the actual execution of this vital insect behavior are under peptidergic neuronal control. Based on studies in the moth, Manduca sexta, it has been postulated that the neuropeptide Crustacean cardioactive peptide (CCAP) plays a key role in the initiation of the ecdysis motor program. We have used Drosophila bearing targeted ablations of CCAP neurons (CCAP KO animals) to investigate the role of CCAP in the execution and circadian regulation of ecdysis. CCAP KO animals showed specific defects at ecdysis, yet the severity and nature of the defects varied at different developmental stages. The majority of CCAP KO animals died at the pupal stage from the failure of pupal ecdysis, whereas larval ecdysis and adult eclosion behaviors showed only subtle defects. Interestingly, the most severe failure seen at eclosion appeared to be in a function required for abdominal inflation, which could be cardioactive in nature. Although CCAP KO populations exhibited circadian eclosion rhythms, the daily distribution of eclosion events (i.e., gating) was abnormal. Effects on the execution of ecdysis and its circadian regulation indicate that CCAP is a key regulator of the behavior. Nevertheless, an unexpected finding of this work is that the primary functions of CCAP as well as its importance in the control of ecdysis behaviors may change during the postembryonic development of Drosophila.     

Differentially expressed genes in metamorphosis and after juvenile hormone application in the pupa of Galleria.

In Galleria mellonella, the pupal-adult transformation of epidermal cells is initiated at day 1 after pupal ecdysis by downregulation of pupal syntheses and loss of juvenile hormone (JH) sensitivity, indicating the change from pupal to adult commitment. To trace regulatory events as close as possible to the early steps of this process, we have analyzed, by differential display, changes in epidermal mRNA populations during the first day after pupal ecdysis in normal development as well as after JH injection. We isolated and cloned 20 cDNA 3'-fragments that are differentially expressed with regard to their developmental profile either in normal development or after injection of JH. Four clones could be verified by Northern blot hybridization.Screening of corresponding cDNA libraries with digoxigenin-labeled anti-sense mRNA probes yielded two full-length cDNA clones (9/27 and 23/86). Both of them represent genes that could be involved in the regulatory events during initiation of pupal metamorphosis or in the action of JH, respectively. The 9/27 mRNA is inducible by JH. It contains, in the 3' untranslated region, a consensus sequence for deadenylation and specific degradation. The corresponding protein possesses two PKC phosphorylation sites and is with high probability a nuclear protein. The 23/86 clone represents polyubiquitin, differentially regulated in normal development and after JH application.     

Circadian regulation of the lark RNA‐binding protein within identifiable neurosecretory cells

Molecular genetic analysis indicates that rhythmic changes in the abundance of the Drosophila lark RNA‐binding protein are important for circadian regulation of adult eclosion (the emergence or ecdysis of the adult from the pupal case). To define the tissues and cell types that might be important for lark function, we have characterized the spatial and developmental patterns of lark protein expression. Using immunocytochemical or protein blotting methods, lark can be detected in late embryos and throughout postembryonic development, from the third instar larval stage to adulthood. At the late pupal (pharate adult) stage, lark protein has a broad pattern of tissue expression, which includes two groups of crustacean cardioactive peptide (CCAP)‐containing neurons within the ventral nervous system. In other insects, the homologous neurons have been implicated in the physiological regulation of ecdysis. Whereas lark has a nuclear distribution in most cell types, it is present in the cytoplasm of the CCAP neurons and certain other cells, which suggests that the protein might execute two different RNA‐binding functions. Lark protein exhibits significant circadian changes in abundance in at least one group of CCAP neurons, with abundance being lowest during the night, several hours prior to the time of adult ecdysis. Such a temporal profile is consistent with genetic evidence indicating that the protein serves a repressor function in mediating the clock regulation of adult ecdysis. In contrast, we did not observe circadian changes in CCAP neuropeptide abundance in late pupae, although CCAP amounts were decreased in newly‐emerged adults, presumably because the peptide is released at the time of ecdysis. Given the cytoplasmic localization of the lark RNA‐binding protein within CCAP neurons, and the known role of CCAP in the control of ecdysis, we suggest that changes in lark abundance may regulate the translation of a factor important for CCAP release or CCAP cell excitability. © 2000 John Wiley & Sons, Inc. J Neurobiol 45: 14–29, 2000     

Developmental changes in Malpighian tubule fluid transport

Developmental changes in Malpighian tubule fluid transport were studied using in vitro and in situ preparations from timed larval, pupal and adult skipper butterflies (Calpodes ethlius). The ability to transport fluid and the rate of fluid secretion depend on the developmental stage and the physiological state. Larval tubules are permanently switched on, do not require a diuretic hormone and transport fluid at an increasing rate as the larvae feed and grow. Fluid transport continues at larval-larval moults but is switched off 24 hr before pupal ecdysis. No secretory activity occurs during the first half of the pupal stage when the tubules are remodelled for adult function. The resumption of fluid transport midway through the pupal stage is in preparation for a rapid diuresis at adult emergence. High rates of fluid secretion are associated with feeding or drinking in adults.     

Molting hormone titer changes and their significance during development of the colorado beetle, Leptinotarsa decemlineata

Molting hormone (MH) titer in whole animal extracts of Leptinotarsa decemlineata was determined by chemical extraction and the Musca test (1 MU = 3.5 ng ecdysterone) during the developmental span from newly-ecdysed fourth instar larva to an adult 3 days after eclosion. Within the 17-day period, 21 age groups were chosen to estimate the MH titer. Two peaks of MH titer were detected, one in the post-feeding larval stage and the other during the pupal and pharate adult stage. MH activity was first detected in 2-day-old post-feeding larvae, and reached a maximum of 23.5 MU/g tissue on the third day. It began to decline on 3.5 days, and fell to 5.5 MU/g tissue on 4.5 days, the time of larval-pupal ecdysis. In the pupal and pharate adult stage MH rose after the first day and increased to a maximum of 91.5 MU/g tissue on the third day. The titer again declined on the fourth day, and became undetectable one day before adult emergence and in adults 3 days after emergence. MH was demonstrated to be produced by isolated larval abdomens. A peak of 11.5 MU/g tissue was detected in 7-day post-ligation preparations. The titer decreased to 6.9 MU/g tissue in 10-day post-ligation preparations, which was the time of the ecdysis. The finding raises questions concerning the rôle of MH synthesis by other tissues in relation to the function of the prothoracic glands during insect development.     

A possible role of ecdysteroids in pre-ecdysial tanning in larvae of Sarcophaga bullata (Diptera: Sarcophagidae)

The levels of ecdysteroids in Sarcophaga bullata were determined by radioimmunoassay (RIA) from the time of larviposition (0 hr) to after the 2nd ecdysis and from late larval to pupal development. Two distinct peaks of ecdysteroid activity were recorded mid-way through the first and second stadia (14 and 34 hr) and two smaller peaks occurred a few hours prior to each ecdysis. A large release of ecdysteroids occurred from 8 hr before and up to 18 hr after formation of the white prepupa. This peak initiated the formation of the prepupa, the tanning of the puparium, larval/pupal apolysis and secretion of the pupal cuticle.Assays for the cuticle tanning hormone, bursicon, in pre-ecdysial larvae were not positive and a possible role for ecdysone in pre-ecdysial tanning of larval cuticular structures is proposed.     

Release of prothoracicotropic hormone and potentiation of developmental ability during diapause in the bollworm, Heliothis zea

In Heliothis zea, pupal diapause is not due to a deficiency of the prothoracicotropic hormone (PTTH), as it is in many other insects. However, PTTH is essential for diapause termination and adult development. Removal of the pupal brain 4 hr after larval-pupal ecdysis blocks the insect's ability to initiate adult development. Transplantation of brain neurosecretory cells restores this ability, whereas other tissues such as corpora allata have no effect. In the diapausing pupa, PTTH is released from the brain within 24 hr after larval-pupal ecdysis. Subsequent removal of the brain fails to block the ability for diapause termination, because PTTH potentiates the ability for adult development. Since diapause termination is suppressed in a temperature of 21°C, the bollworm retains the ability to initiate development in 27°C whereas it remains in diapause in 21°C. Diapause continues even though pupae are supplied with additional PTTH via neurosecretory cell transplantation.Ecdysone injection and prothoracic gland-ablation experiments indicate that the prothoracic glands are the source of the prohormone α-ecdysone, and that diapause is maintained by an α-ecdysone deficiency. This evidence, in conjunction with the above results, suggests that PTTH release potentiates prothoracic gland function in the diapausing pupa which is then regulated by a temperature dependent process.     

Effect of omeprazole-evoked hypergastrinemia on ultrastructure of enterochromaffin-like cells in the stomach of portacaval-shunted rats

Immunocytochemical staining of the nervous system of larva, pupa, and adult stage of Tenebrio molitor with anti-insulin serum demonstrated insulin-like peptides in the protocerebrum, corpora allata, and suboesophageal ganglion. During pupal development, marked changes in staining intensity of the protocerebral cells were detected. The staining pattern suggests release of insulin-like peptides early on day 0 and again on day 3 of the stadium. Injections of anti-insulin at these times caused significant delays in the timing of pupal/adult ecdysis. An immunoblot of haemolymph from day-3 pupae revealed a 6.5-kDa insulin-like molecule. These results suggest that the prothoracicotropic hormone of T. molitor is an insulin-like molecule.     

Rôle des organes perisympathiques et dynamique de la secretion de la bursicon chez Tenebrio molitor

Light and electron microscope observations have been made on the perisympathetic organs (P.O.) situated on the dorsal somatic abdominal nerves in pupae of Tenebrio molitor.Tests carried out with extracts of P.O. using a bioassay method on pupae of Tenebrio at various developmental stages indicate that these organs have an important role in the storage and release of the tanning hormone, bursicon. The P.O. extracts from the abdominal segments (2 to 5) of 5-day-old pupae were found effective but not those from pharate adult (2 days before ecdysis). The storage and release of bursicon occur later from the P.O. of the posterior abdominal segments (6 to 8).The activity of the blood begins to be effective in the pharate adult 2 days before ecdysis, reaches a maximum 1 hr after the adult ecdysis, and decreases thereafter.This study carried out on the various parts of the nervous system shows that all these parts are effective at a certain stage of the pupal and adult development following an antero-posterior gradient. In the cephalic region, this activity is early and long-lasting, but it appears at later stages and only for a short time in the thorax and abdomen. This phenomenon indicates that bursicon is either passed along the ventral nervous chain or it is synthesized in different parts of the nervous system at successive developmental stages. In the present paper, we have tried to give a comprehensive summary of the dynamics of bursicon in insects.