In vitro stimulation of cell death in the moulting glands of Oncopeltus fasciatus by 20-hydroxyecdysone

The moulting glands of the milkweed bug, Oncopeltus fasciatus, normally degenerate just before the time of ecdysis to an adult (day 7 of the fifth instar). Morphologically normal cell death can be prematurely stimulated in vitro by 20-hydroxyecdysone. Breakdown is triggered by a 24-hr period of exposure to 20-hydroxyecdysone, but an additional incubation period is required before clear signs of degeneration are manifested. Glands removed after the onset of endogenous ecdysteroid secretion degenerate in vitro in the absence of added hormones. Thus, in the moulting glands of Oncopeltus, ecdysteroids appear to act as an important trigger for metamorphic cell death.     

The control of Malpighian tubule developmental physiology by 20-hydroxyecdysone and juvenile hormone

The control of developmental changes in Malpighian tubule cell structure and fluid secretion by 20-hydroxyecdysone and juvenile hormone in the skipper butterfly Calpodes ethlius were studied using (1) in vitro tissue culture, (2) in vivo injection and topical application and (3) tubule transplantation experiments. At pupation, 20-hydroxyecdysone initiates cell remodelling and switches off fluid secretion in the Malpighian tubules. Juvenile hormone inhibits these alterations provided that treatment is begun on the first day of the last larval stage. In the pupal stage, 20-hydroxyecdysone triggers the differentiation of adult cell structure which culminates in the renewal of fluid secretion. The results show that 20-hydroxyecdysone and juvenile hormone regulate Malpighian tubule function by altering cell structure and are discussed with respect to the hormonal reprogramming of the Malpighian tubule cells during development.     

Humoral inhibition of the corpora allata in larvae of Diploptera punctata: Role of the brain and ecdysteroids

Juvenile hormone synthesis by adult female corpora allata was inhibited following implantation into final-larval-instar males; inhibition was prevented by decapitation of the larval hosts on day 11 (prior to the head critical period for moulting), but not by decapitation on day 13. Implantation of one larval protocerebrum restored inhibition of implanted corpora allata, demonstrating that the brain releases an inhibitory factor. Corpora allata implanted into larvae decapitated on day 11 were inhibited by injections of 20-hydroxyecdysone. Since treatment of corpora allata with 20-hydroxyecdysone in vitro did not inhibit juvenile hormone synthesis, ecdysteroids probably act indirectly on the corpora allata. Juvenile hormone synthesis and haemolymph ecdysteroid concentration were measured following implantation of corpora allata along with two larval brains into larval hosts. Brain implantation did not affect ecdysteroid concentration, but did inhibit juvenile hormone synthesis, even in animals with low haemolymph ecdysteroid concentration. Incubation with farnesoic acid stimulated juvenile hormone synthesis by corpora allata from males early in the final larval stadium, but not after day 8, showing that one of the final two reactions of juvenile hormone synthesis is rate-limiting in larval corpora allata at this stage. Adult female corpora allata which had been humorally inhibited by implantation into larvae were stimulated by farnesoic acid.     

Ecdysteroid levels throughout the life cycle of the desert locust, Schistocerca gregaria

Moulting hormone levels for all stages of the life cycle of the desert locust, Schistocerca gregaria, have been determined using gas chromatography with electron capture detection of the trimethylsilylated hormones. During larval development, the major hormone detected is 20-hydroxyecdysone with smaller quantities of ecdysone present. In mature adult females the major ecdysteroid observed is a polar conjugate of ecdysone, with smaller quantities of conjugated 20-hydroxyecdysone also present. During embryonic development the pattern changes from a high proportion of conjugated ecdysone in the early stages to give more free hormone and a higher proportion of 20-hydroxyecdysone in later stages. The highest titre of 20-hydroxyecdysone found in this insect is during the 5th larval instar. Maximal levels of ecdysteroid per insect are found in mature females just before oviposition, while the highest level of ecdysteroid per g of tissue is found in the eggs.     

The onset of metamorphosis in Tenebrio molitor L.: Effects of a juvenile hormone analogue and of 20-hydroxyecdysone

Sensitivity to juvenile hormone and to 20-hydroxyecdysone has been investigated during the last-larval stages of Tenebrio molitor. Topical applications of a juvenile hormone analogue (K-421d) showed that the sensitive period, occurring before apolysis, is relatively short (less than 4 days in a 3-week instar) and divided into two phases. Treatment during the first and longest phase induced a delay in development and then an increase in larval moult percentage. Treatment during the second phase induced several abnormal moults (prothetelic larvae and larval-pupal intermediates).Injections of massive doses of 20-hydroxyecdysone (10 μg per animal) also evidenced a period of disturbance of the morphogenetic programme, beginning before pupal apolysis but continuing several days after.Comparison of the sensitive periods to both hormones suggests that a very important and rapid step of the larval-pupal programme change is controlled hormonally just before pupal apolysis.     

Chitin synthesis in larval and pupal epidermis of the Indian meal moth,Plodia interpunctella (Hübner), and the greater wax moth,Galleria mellonella (L.)

The level of chitin synthesis was determined in whole last-instar larvae and in pupae of Plodia interpunctella, and in epidermal tissue from similar stages of Galleria mellonella. The incorporation of radiolabelled N-acetyl-d-glucosamine into chitin was used to measure synthesis. Chitin production was similar in both species with peaks of synthesis occurring at the beginning of the last larval instar, in prepupae, in white pupae and prior to adult emergence. P. interpunctella also exhibited an additional small increase at mid-instar. Exposure of larval epidermis of P. interpunctella to 20-hydroxyecdysone in vitro stimulated chitin synthesis, but only after a 24 hr lag period subsequent to exposure to the hormone. This hormonal stimulation of chitin synthesis was inhibited by actinomycin-D and cycloheximide which suggested that 20-hydroxyecdysone-stimulated production of chitin depended on synthesis of RNA and protein. Comparison of the synthesis of chitin in epidermis of G. mellonella with previously published ecdysone titres, indicated that chitin production in vivo is preceded by an elevated ecdysone titre.     

Response of cultured Aedes aegypti fat bodies to 20-hydroxyecdysone

Fat bodies from non-blood-fed Aedes aegypti, stimulated in vitro by 10⁻⁴ M and 10⁻⁶ M of 20-hydroxyecdysone, were found to synthesize and release vitellogenin into the culture medium. Vitellogenin-specific monoclonal antibodies were utilized in an enzyme-linked immunosorbent assay procedure for quantification of vitellogenin in small aliquots of medium taken periodically from the culture. A minimal exposure of 5 h to 20-hydroxyecdysone was shown to be needed before the fat bodies would respond. Time-course of vitellogenin production in vitro was found to be identical to that observed in vivo. Vitellogenin-titre profiles were also investigated in cultured fat bodies from blood-fed A. aegypti. In all cases, response patterns were not affected by the presence or absence of 20-hydroxyecdysone after the fat bodies had been stimulated by blood meal to produce vitellogenin. We suggest here that initiation and control of vitellogenin synthesis is a programmed response to 20-hydroxyecdysone.     

Qualitative and quantitative analyses of juvenile hormone and ecdysteroids from the egg to the pupal molt in Trichoplusia ni

A method was developed to determine in the same extract juvenile hormone and various types of ecdysteroids in precisely staged eggs and larvae of Trichoplusia ni. Ecdysteroids were tentatively identified on the basis of their retention time in ion suppression reversed-phase HPLC and their cross-reactivity with two relatively non-specific, complimentary antibodies, whereas juvenile hormone was identified using reversed-phase HPLC combined with Galleria bioassay. Freshly laid eggs contained low levels of immunoreactive ecdysteroids. Mid-polar ecdysteroids increased in the phase of segmentation (14-18 h) and 1st larval cuticle formation (36-44 h), when 20-hydroxyecdysone and 20,26-dihydroxyecdysone were found to be predominant. Only traces of ecdysone and 26-hydroxyecdysone were seen. Toward hatching ecdysteroids decreased and represented mainly compounds more polar than 20,26-dihydroxyecdysone. In larval development ecdysteroids were low at the beginning of the feeding phases, increased toward cessation of feeding, and reached highest levels 12-15 h before ecdysis. In feeding stages ecdysone and 20-hydroxyecdysone were predominant, whereas in molting stages they were seen together with 20,26-dihydroxyecdysone and 20-hydroxyecdysonoic acid. The juvenile hormone titer was very low in freshly laid eggs and was high (approximately 25 ng/g) in embryos at the stage of 1st larval cuticle formation and eye pigmentation. In eggs we tentatively identified juvenile hormones I and II, whereas in larval stages juvenile hormone II appeared to be the predominant or exclusive juvenile hormone. Its titer fluctuated rapidly and was high in early 1st-instar larvae and again before the molts into the 3rd, 4th, and 5th instar. Highest titers were reached concomitant with the peak in 20-hydroxyecdysone 12-15 h before ecdysis.     

Hormonal control of seasonal-morph determination in the small copper butterfly, Lycaena phlaeas daimio Seitz.

Spring and summer morphs of Lycaena phlaeas daimio Seitz. are characterized by a wing colour of red and reddish brown, respectively.When newly ecdysed pupae destined to be summer or intermediate morphs (90 or 10%) by larval exposure to long days (long-day pupae) were decapitated or decerebrated, more than half of the operated pupae developed into intermediate and spring morphs (48 and 7%). But, in pupae destined to be spring, intermediate, or summer morphs (72, 22 or 4%) (short-day pupae) these operations did not produce any significant changes in the seasonal morph.Brains excised from newly ecdysed long-day pupae were transplanted into the abdomen of decapitated short-day pupae of the same age. The implants changed most recipients into summer and intermediate morphs (46 and 36%). However, when the brains of short-day pupae were used, no significant changes occurred in the seasonal morph.When long-day or short-day pupae were treated with 20-hydroxyecdysone just after pupation, they produced more reddish wings than those of the untreated or saline-treated controls. When the application was followed by chilling, already known to induce the reddish morph, the effects of both treatments are cumulative so that more reddish adults developed.The results indicate that the brain of long-day pupae secretes a factor causing the wing to be brownish. In the absence (or low titre) of the factor, most short-day pupae develop into spring or intermediate morphs. Furthermore, ecdysteroids make the wing more reddish, when applied to newly ecdysed pupae.     

The effect of 20-hydroxyecdysone and protein on granule formation in the in vitro cultured fat body of Drosophila

The larval fat body of Drosophila melanogaster when cultured in a medium containing 20-hydroxyecdysone and foetal calf serum produces protein granules in the cytoplasm in a region-specific manner similar to that found in vivo. If ecdysteroid is omitted from this medium, the tissue continues to produce the granules at the same time, in the same region-specific manner, but in lower amounts. Only the high molecular weight fraction of the calf serum has the granule-inducing effect. Bovine serum albumin, herring protamine and bovine haemoglobin will also induce the granules to form. The degree of granule formation is directly proportional to the concentration of protein in the medium. Protein-free medium produces no granules, and protein concentrations in the medium above 3 mg/ml produce no further increase in granule formation. Although the medium containing foetal calf serum and 20-hydroxyecdysone induces more granule formation than medium containing only serum, the extent of granule formation does not differ at concentrations of hormone above 10^?6 M with any given concentration of serum. A minimal amount of serum (3.75%) permits measuring the effects of 20-hydroxyecdysone at concentrations below 10^?6 M. At this serum level the inducing effects of the hormone could be detected at concentrations of 10^?7 M.     

Loss of protein kinase C delta alters mammary gland development and apoptosis

As apoptotic pathways are commonly deregulated in breast cancer, exploring how mammary gland cell death is regulated is critical for understanding human disease. We show that primary mammary epithelial cells from protein kinase C delta (PKCδ) −/− mice have a suppressed response to apoptotic agents in vitro. In the mammary gland in vivo, apoptosis is critical for ductal morphogenesis during puberty and involution following lactation. We have explored mammary gland development in the PKCδ −/− mouse during these two critical windows. Branching morphogenesis was altered in 4- to 6-week-old PKCδ −/− mice as indicated by reduced ductal branching; however, apoptosis and proliferation in the terminal end buds was unaltered. Conversely, activation of caspase-3 during involution was delayed in PKCδ −/− mice, but involution proceeded normally. The thymus also undergoes apoptosis in response to physiological signals. A dramatic suppression of caspase-3 activation was observed in the thymus of PKCδ −/− mice treated with irradiation, but not mice treated with dexamethasone, suggesting that there are both target- and tissue-dependent differences in the execution of apoptotic pathways in vivo. These findings highlight a role for PKCδ in both apoptotic and nonapoptotic processes in the mammary gland and underscore the redundancy of apoptotic pathways in vivo.     

Ecdysteroid levels and integument changes in post-embryonic stages of Anastrepha suspensa

Ecdysteroid levels in larvae and pupae of Anastrepha suspensa (Diptera: Tephritidae) were measured by radioimmunoassay. These levels were correlated with histological changes throughout the development of the post-embryonic stages. Ecdysteroid levels increase rapidly throughout the last-larval instar and on the last day of this stage are 283 pg equivalents of 20-hydroxyecdysone per insect (14.5 ng/g) when wandering behaviour is initiated. At the end of this period the puparium is formed and within 24 h, the ecdysteroid rises to its highest peak (625 pg equivalents of 20-hydroxyecdysone/insect). Larval-pupal apolysis is initiated within 24 h later and the pupal cuticle is then secreted. Two days later, the ecdysteroids reach their lowest levels (75 pg equivalents of 20-hydroxyecdysone/insect or 0.6 ng/g) and most of the larval fat body and other tissues have been histolysed. In 5- to 10-day old pupae ecdysteroid levels again increase and remain relatively high throughout. During this period the larval epidermis is replaced by imaginal epidermis, imaginal discs begin to proliferate and the adult cuticle is secreted. Ecdysteroid levels finally fall 2 days prior to adult emergence. HPLC determinations indicate that 20-hydroxyecdysone is the predominant free ecdysteroid, and along with ecdysone, is readily detectable in all postembryonic stages of this species. An unusually high and unexplained peak of 20-hydroxyecdysone occurs in the pharate adult. This peak probably consists of ecdysone metabolites with retentions similar to that of 20-hydroxyecdysone and to which the antiserum is sensitive.     

Feedback inhibition of ecdysone production by 20-hydroxyecdysone in Pieris brassicae pupae

The effects of exogenous moulting hormones, ecdysone and 20-hydroxyecdysone on ecdysteroid production were studied in vivo in Pieris brassicae pupae. Both hormones inhibit ecdysteroid production; however, 20-hydroxyecdysone is much more efficient than ecdysone, and it is likely that the ecdysone effect is due to its partial conversion into 20-hydroxyecdysone. These results suggest that 20-hydroxyecdysone acts on ecdysteroid production as a negative-feedback regulator. Furthermore, since 20-hydroxyecdysone elicits inhibition in headless pupae, it is suggested that 20-hydroxyecdysone acts directly upon the prothoracic glands.     

Role of low ecdysteroid titre in acquisition of competence for pupal transformation in Bombyx mori

Penultimate-instar larvae of Bombyx mori were neck-ligated or ligated posterior to the prothoracic glands. Repetitive injections of 20-hydroxyecdysone every 3 or more hours elicited the gut purge in thorax-ligated animals. Single injections of 20-hydroxyecdysone up to 40 μg failed to induce the gut purge. However, a single injection of 20-hydroxyecdysone together with juvenile hormone analogue, resulted in larval moulting of thorax-ligated animals. Once the thorax-ligated larvae showed the gut purge, a single injection of 20-hydroxyecdysone was enough to provoke pupation. The change in ecdysteroid titre in those animals receiving repeated injections was compared with that observed in neck-ligated larvae that spontaneously underwent the gut purge followed by precocious pupation. These data indicate that the very low ecdysteroid titre found before the gut purge is important for the acquisition of competence to undergo the gut purge in response to a small ecdysteroid surge just before the gut purge.     

Live Cell Imaging of Butterfly Pupal and Larval Wings In Vivo

Butterfly wing color patterns are determined during the late larval and early pupal stages. Characterization of wing epithelial cells at these stages is thus critical to understand how wing structures, including color patterns, are determined. Previously, we successfully recorded real-time in vivo images of developing butterfly wings over time at the tissue level. In this study, we employed similar in vivo fluorescent imaging techniques to visualize developing wing epithelial cells in the late larval and early pupal stages 1 hour post-pupation. Both larval and pupal epithelial cells were rich in mitochondria and intracellular networks of endoplasmic reticulum, suggesting high metabolic activities, likely in preparation for cellular division, polyploidization, and differentiation. Larval epithelial cells in the wing imaginal disk were relatively large horizontally and tightly packed, whereas pupal epithelial cells were smaller and relatively loosely packed. Furthermore, larval cells were flat, whereas pupal cells were vertically elongated as deep as 130 μm. In pupal cells, many endosome-like or autophagosome-like structures were present in the cellular periphery down to approximately 10 μm in depth, and extensive epidermal feet or filopodia-like processes were observed a few micrometers deep from the cellular surface. Cells were clustered or bundled from approximately 50 μm in depth to deeper levels. From 60 μm to 80 μm in depth, horizontal connections between these clusters were observed. The prospective eyespot and marginal focus areas were resistant to fluorescent dyes, likely because of their non-flat cone-like structures with a relatively thick cuticle. These in vivo images provide important information with which to understand processes of epithelial cell differentiation and color pattern determination in butterfly wings.     

Positional control of the fates of nuclei produced after meiosis in Paramecium caudatum: Analysis by nuclear transplantation

The survival or degeneration of nuclei produced by meiosis in Paramecium caudatum depends on their position in the cytoplasm. The surviving nucleus always lies in the special region of the cytoplasm called the paroral region, which is the region around the cytostome. The remaining three degenerate outside the region. The mechanism controlling the survival or degeneration of meiotic nuclei was analyzed microsurgically. When the nucleus in the early conjugating cells (stage II) was transplanted into the cell at the stage when three meiotic nuclei were degenerating, it did not degenerate, but divided. When one of the meiotic nuclei which was outside the paroral region and destined to degenerate was transplanted into the cell in the meiotic prophase (stage IV), it did not survive but degenerated. When the surviving nucleus in the paroral region was removed microsurgically, one of the three meiotic nuclei lying outside the paroral region and destined to degenerate moved into the paroral region and survived. These results suggest that the nuclei after meiosis are destined to degenerate but can be rescued from degeneration by the special environment of the paroral region.     

Prothoracic gland involution related to moulting hormone levels during the metamorphosis of Tenebrio molitor L.

Prothoracic gland (PG) of Tenebrio shows ultrastructural changes which can be correlated with ecdysteroid levels (measured by radioimmunoassay) during larval-pupal development. However, the gland cells begin to degenerate before pupal-adult ecdysis: the PG involution is completed before the moulting hormone peak which triggers pupal-adult development. These facts strongly suggest that another endocrine organ produces moulting hormone needed for adult development.