Ecdysone metabolism and endogenous moulting hormone titre during larval-pupal development in Choristoneura fumiferana

The titre and metabolism of ecdysone were studied in the last larval instar of the spruce budworm, Choristoneura fumiferana. Both in males and females a distinct ecdysone peak is present just before ecdysis. Injection of radioactive α-ecdysone into the insect when the endogenous level is low results in the transformation of most of the injected hormone into 3-dehydro-α-ecdysone and conjugates, with very little conversion to β-ecdysone. Whereas when the labelled material is administered when the endogenous level is high, the α-ecdysone is for the most part converted to β-ecdysone. The significance of the correlation between the endogenous titre of ecdysone and the metabolism of injected α-ecdysone is discussed.     

Effects of alpha-ecdysone, beta-ecdysone and inokosterone on the in vitro evagination of Drosophila leg discs and the subsequent differentiation of imaginal integumentary structures

The morphogenetic activity of three hormonal substances—α-ecdysone, β-ecdysone, and inokosterone—has been studied in vitro on isolated imaginal leg discs of third-instar larvae of Drosophila melanogaster.In the presence of α-ecdysone (0.3–3 μg/ml) and also of the phytohormone inokosterone (0.3–3 μg/ml), the discs underwent metamorphosis, as characterized by complete evagination (in less than 24 hr), secretion, and shedding (48 hr after explanation) of the pupal cuticle, secretion, and structural differentiation of the imaginal cuticle, namely pigmentation and formation of claws, bristles, and hairs (during days 3–6).In the presence of β-ecdysone (10, 6, 3, 0.3, 0.03, 0.003 μg/ml), evagination was always abnormal and incomplete. With all concentrations but the lowest, the partially everted legs had a swollen appearance and, at all concentrations, the subsequent development was inhibited. No imaginal differentiation occurred at any of the concentrations tested.Larval fat body or larval epidermis added to the isolated discs had no influence on their response to either α-ecdysone or β-ecdysone.Changing the osmotic pressure of the β-ecdysone containing medium likewise did not alter the noxious effect of β-ecdysone.Discs cultured first in the presence of β-ecdysone (for 24 hr), then transferred to fresh medium containing α-ecdysone were unable to undergo normal development. The inhibitory effect of β-ecdysone thus appears to be irreversible.Discs cultured first in the presence of α-ecdysone (for 24, 48 or 72 hr), then transferred to β-ecdysone containing medium, were unable to continue their normal differentiation. Further development was blocked within a few hours after the transfer.Results are discussed in view of results obtained with other in vitro and in vivo cultivation techniques. In conclusion, isolated leg discs of Drosophila are unable to respond physiologically to exogenous β-ecdysone. Only α-ecdysone and inokosterone will induce complete and normal metamorphosis in leg discs cultured in vitro.     

Der metabolismus von 3H-α-ecdyson bei larven von Tenebrio molitor

The metabolism of ³H-α-ecdysone has been investigated in larvae of Tenebrio molitor within a moulting cycle. The metabolization occurs by hydroxylation, dehydration, and conjugation. A total of 8 metabolites including α- and β-ecdysone were found. Peak I was cleaved enzymatically up to 56%. The hydrolized part consists of esters of sulfuric- and glucuronic acid with compounds II and III, also with α-ecdysone and 3-dehydroecdysterone to a lesser degree.The hydroxylation of α-ecdysone to β-ecdysone is a very rapid one. Velocity and intensity depends on the physiological stage of the larvae. On days with a large endogenous hormone titer they are maximal and on days with a low endogenous titer they are lower. The rate of conversion of α- to β-ecdysone shows a correlation with the endogenous titer and vice versa.At a low endogenous titer the rate of excretion is very strong, in larvae aged to 2 to 5 days and also 7 to 8 days, 8 h after injection 50 to 80% of injected activity was recovered in the faeces. At the beginning of the moulting cycle 3% and at the 6th day 30% (hormone titer maximum) of activity is excreted. The unexpected high rate of excretion at the first day is compensated by increasing metabolism and storage.The faeces mainly consist of conjugates and α- and β-ecdysone. A correlation between the appearance of these compounds and the physiological stage of the larvae could be found. On those days with low endogenous titer the quota of ecdysone (α and β) is higher.     

In vitro development of insect cells: III. Effects of ecdysone on neonatal larval cells

Both α- and β-ecdysone increased the growth of monocellular spheres in primary cultures of two dipteran species, Aedes taeniorhynchus and Drosophila melanogaster. A limited amount of differentiation was evident in the secretion of one or more membranes, the formation of cellular bridges and the appearance of setae-like structures. A process resembling ecdysis was also observed in one of the D. melanogaster cultures.     

Activities of hormone metabolizing enzymes in house flies treated with some substituted urea growth regulators.

The insect growth regulators (IGR) TH 6038 and TH 6040 affect larvae of various species by interfering with cuticle development. In a biochemical study of their effects, larvae of the house fly, $\text{Musca domestica}$ L. were reared for 2 days on diets containing 1.7 to 166.7 ppm of these compounds, then assayed for activities of the microsomal oxidases and the enzyme(s) which metabolize β-ecdysone. The activities of these enzymes were compared with the percentage of treated larvae completing pupal-adult ecdysis. The two compounds reduced the activity of the β-ecdysone metabolizing enzyme(s) by as much as 57%, reduced pupal-adult ecdysis by 43% to 100%, and stimulated microsomal oxidase activity 4- to 12-fold. Supplementation of the diet of the treated insects with the Cecropia juvenile hormone, JH I, partially restored pupal-adult ecdysis but supplementation with β-ecdysone had no effect. The mode of action indicated by these results is that the IGRs cause an accumulation of β-ecdysone in the treated larvae. This stimulates the enzyme, chitinase, which degrades chitin in preparation for formation of the new cuticle. The hormone may also cause a JH deficiency and the stimulation of DOPA decarboxylase and phenol oxidase which would further disrupt the normal molting process.     

Metabolism of 3H-α-ecdysone in Gryllus bimaculatus during the eighth larval instar

During the 8th larval instar of Gryllus bimaculatus the metabolites of exogenous tritiumlabelled α-ecdysone were isolated from animals and from excrement, qualified by TLC and quantified in the scintillation counter. Besides β-ecdysone, there were 3 other compounds more polar than α-ecdysone (compounds I, II, and III), in addition to two less polar ones: compounds IV and V.The pattern of hormone changes characteristically during the period of development investigated. Thus on the 3rd day compound IV, on the 4th day α-ecdysone, and on the 5th day, at the moment of the hormone titre maximum, β-ecdysone dominates.Whether all ecdysone metabolites represent products of inactivation will be discussed in this article.     

The apparent requirement of two hormones, alpha- and beta-ecdysone, for molting induction in insects

Puff formations at loci I-18-C and IV-2-B of the salivary gland chromosomes are early indications of a beginning molting process in Chironomus tentans larvae. The effectiveness of the two ecdysone analogs, α- and β-ecdysone, in inducing these puffs was compared. Incubation of salivary glands in vitro with β-ecdysone causes only puff IV-2-B to appear; incubation with α-ecdysone stimulates initially puffing at only I-18-C. After an injection of α-ecdysone, puffing at I-18-C begins within less than 15 min, whereas puffing at IV-2-B is delayed for more than 30 min. Following an injection of β-ecdysone, puffing at IV-2-B begins within less than 15 min, whereas puffing at I-18-C is delayed. Injected ³H-α-ecdysone is converted to β-ecdysone and a polar compound. Injected ³H-β-ecdysone is converted to a compound less polar than α-ecdysone and a polar metabolite which stimulates puffing at I-18-C, like α-ecdysone. It is suggested that the two ecdysones have different targets in the cell, that they can be rapidly converted to compounds with the activity of the other analog, and that the induction of a complete molt requires the action of both hormones.     

Time-dosage studies of juvenile hormone action on the development of Plodia interpunctella

The degree of inhibition of larval-pupal ecdysis of Indian meal moths, Plodia interpunctella, by juvenile hormone (JH) treatment depended upon the dosage of hormone and time of treatment. During the last larval instar, the timing aspect operated independently of dosage and had two essential components for effectiveness, (a) early initiation of exposure and (b) maintenance of exposure. The effects of JH treatments could be reversed by removing the insects from the JH diet. In vitro tests with wing disks indicated that JH reversibly inhibited disk development only during the early part of the last larval instar, a time when disks are insensitive to β-ecdysone. After disks acquire full sensitivity to β-ecdysone, they lose their ability to respond to JH.     

Metamorphic shortening of interganglionic connectives of Galleria mellonella (Lepidoptera) in vitro: stimulation by ecdysone analogues

In the absence of other organ systems, β-ecdysone (0·05 to 0·10 μg/ml culture medium) stimulates the shortening of interganglionic connectives of Galleria mellonella that occurs during metamorphosis. There is a direct relations-ship between the amount of β-ecdysone in the medium and the fraction of the sample shortening to at least half the initial length. β-Ecdysone is ～ 140 × more active than α-ecdysone in eliciting the response. When β-ecdysone and other ecdysone analogues are assayed on this system at uniform dosages (10 μg/ml tissue culture medium), the order of effectiveness (percentage sample shortening to at least half the initial length) is: cyasterone > ponasterone-A = β-ecdysone > inokosterone > α-ecdysone. 22-Iso-α-ecdysone is ineffective in stimulating shortening.     

Galleria mellonella nerve cords in vitro: stage-specific survival and differential responsiveness to beta-ecdysone

The survival of ventral nerve cord segments of Galleria mellonella in tissue culture medium, ascertained by histological and biochemical criteria, ability to shorten when transplanted, and responsiveness to β-ecdysone, is correlated with the stage of development of the donor, and with the presence of a connective tissue sheath, the neural lamella, about the segment. After only 18 hr in vitro connectives which have lost the neural lamella during metamorphosis no longer have the capacity to shorten when transplanted or when exposed to β-ecdysone in the culture medium. By contrast, after 7 days in vitro connectives with a neural lamella shorten appreciably when β-ecdysone is added, or when they are exposed to the humoral milieu of a host undergoing metamorphosis. β-Ecdysone stimulates the incorporation of uridine-5-³H in segments both with and without the neural lamella, but only in segments which have previously begun their metamorphosis. Since shortening in response to β-ecdysone occurs only in connectives which have already begun to shorten, β-ecdysone appears to accelerate physiological processes underway before it is added to the medium rather than initiate metamorphosis in cultured nerve cords.     

Differentiation of insect sensory neurons in the absence of their normal synaptic targets.

Sensory neurons in the antenna of the moth, Manduca sexta, arise and differentiate during the 18 days of metamorphosis from pupa to adult, sending axons to the brain. To assess the trophic dependence of developing antennal neurons on their targets, we studied antennae from surgically debrained animals. If the brain is removed 1 to 45 hr after pupal ecdysis (before and during the period when antennal neurons arise by cell divisions), adult development can be triggered by injection of β-ecdysone; if the brain is removed 50 to 60 hr after pupal ecdysis (before antennal axons contact the brain), metamorphosis proceeds spontaneously. Neurons proliferate normally and differentiate extensively in the antennae of debrained animals. They acquire a characteristic size and shape, elaborate axons and dendrites, migrate to appropriate positions in the sensilla, accumulate components of a neurotransmitter system (acetylcholine, choline acetyltransferase, and acetylcholinesterase), and generate electrical responses to olfactory and mechanical stimuli. Antennal sensory neurons thus differ from a variety of vertebrate neurons, which fail to mature when deprived of their synaptic targets.     

Biosynthesis of ecdysones in isolated prothoracic glands and oenocytes of Tenebrio molitor in vitro

Isolated prothoracic glands from Tenebrio larvae synthesize in vitro α-ecdysone, but not β-ecdysone from 4-¹⁴C-cholesterol. Isolated abdominal oenocytes from the larvae synthesize mainly β-ecdysone, but only little α-ecdysone. When prothoracic glands and oenocytes are cultured together, the α-ecdysone derived from the prothoracic glands is oxidized by the oenocytes to β-ecdysone. The newly synthesized hormones are not stored in the cells, but are secreted into the medium if sufficient amounts of non-labelled hormones are present. If no unlabelled hormones are added to the culture medium, the newly formed hormones are converted to a large extent into polar conjugates.     

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.     

The secretion and metabolism of alpha-ecdysone by cockroach (Leucophaea maderae) tissues in vitro

Hemolymph β-ecdysone levels are high (～1.6 μg/ml) in late last instar cockroach ($\text{Leucophaea}$$\text{maderae}$) nymphs; the level of α-ecdysone (～0.1 μg/ml) is evidently subphysiological. Cultured leg regenerates, target organs of ecdysone, are capable of slowly converting α- to β-ecdysone. Cultured prothoracic glands secrete α-ecdysone, which was identified by complete mass spectrometry. These results are consistent with the view that α-ecdysone, secreted by the prothoracic gland, functions as a prohormone which is converted into the active moulting hormone, β-ecdysone, in other tissues.     

Effects of fat body on α-ecdysone induced morphogenesis in cultured wing disks of the wax moth, Galleria mellonella

Fat body promoted ecdysone induced morphogenesis in Galleria wing disks cultured in vitro. Medium preincubated with fat body and α-ecdysone from any of the first 5 days of the final larval instar enhanced tracheal migration and elongation in the disks. Disks from the third, fourth, and fifth days of the final larval instar responded equally well to the fat body and α-ecdysone. We suggest a physiological rôle for Galleria fat body as an intermediary in the stimulation of wing disk development by α-ecdysone.     

The time during which beta-ecdysone is required for the differentiation in vitro and in situ of wing imaginal discs of Drosophila melanogaster.

The time during which β-ecdysone is required for the apolysis and imaginal differentiation of wing discs of Drosophila both in vitro and in situ has been examined, and it is concluded that β-ecdysone is required as a sustained stimulus rather than as a trigger for differentiation. These results are compared with the requirement for β-ecdysone for the puffing of salivary gland polytene chromosomes during the prepupal stage (Richards, G. P., 1976, Develop. Biol.48, 191–195). It is suggested that imaginal discs and larval salivary glands require different exposures to β-ecdysone to fulfill their developmental commitments and that the drop in β-ecdysone titer during the early prepupal stage, which is necessary for the subsequent puffing of the polytene chromosomes, plays little or no part in imaginal disc differentiation.     

Endocrine interactions controlling the larval diapause of the southwestern corn borer, Diatraea grandiosella

The effect of hormone treatments on larvae of the southwestern corn borer, Diatraea grandiosella, was examined to explore endocrine interactions which regulate its mature larval diapause. This species is especially suitable for investigating the endocrine control of larval diapause because it ecdyses from a spotted to an immaculate morph at the onset of diapause, and the immaculate morph may undergo up to three stationary ecdyses during diapause. The response of prediapause larvae to a β-ecdysone injection showed that the larvae have the potential to transform into the immaculate morph early in the final larval instar, but under normal conditions this ecdysis occurs after larvae reach maturity. Since a high rate of pupation occurred among early diapause larvae which received a head ligature, followed 17 days later by a β-ecdysone injection, diapause larvae retain active corpora allata. Since a head ligature prevented diapause larvae from responding to repeated topical applications of a juvenile hormone (JH) mimic or JH 1, the intermediate titer of JH associated with larval diapause may inhibit the synthesis or transport of ecdysiotropin, or its release from the corpora cardiaca. Current results suggest, therefore, that an interaction between the cerebral neurosecretory system and the corpora allata regulates the initiation, maintenance, and termination of this larval diapause.     

Occurrence of α-ecdysone in the developing embryos of the silkworm, Bombyx mori

From an acetone-ethanol extract of the developing embryos of the silkworm, Bombyx mori, the presence of α-ecdysone, but not of β-ecdysone, was shown by high pressure liquid chromatography and bioassay. The amount of α-ecdysone was estimated to be 0.74 μg per gram of eggs. The absence of a hydroxylating system at C-20 in the embryos is suggested.     

Elevation of ionic conductance between insect epidermal cells by β-ecdysone in vitro

Electrophysiological methods reveal that the cell-to-cell movement of inorganic ions in the epidermis of the beetle larva is facilitated by exposing the tissue to β-ecdysone in vitro. After exposure to 2 × 10^?6 M β-ecdysone for 24 hr, the resistivity of the intercellular pathway drops by 30%, from 389 Ωcm to 264 Ωcm. This response does not occur when α-ecdysone is used for extended incubation periods. As the resistivity of the epidermal cytoplasm in the absence (64 Ωcm) and presence of β-ecdysone (65 Ωcm) is constant, the hormone must exert its effect at the cell junctions. A simple geometrical model for the epidermal monolayer allows one to calculate that the ionic permeability of the junctional membrane increases by 66% in cells exposed to β-ecdysone for 24 hr in vitro.     

Selective activation of RNA polymerase I in fat body nuclei of Sarcophaga peregrina larvae by beta-ecdysone.

RNA synthesis in fat body nuclei of Sarcophaga peregrina larvae was temporarily activated after injection of β-ecdysone: increased synthesis was detectable 2 hr after injecting the hormone and lasted for at least 2 hr. This increased RNA synthesis was insensitive to α-amanitin and was observed in KCl-free reaction mixture, indicating that β-ecdysone activated RNA polymerase I but not RNA polymerase II. No activation was observed when protein synthesis was inhibited by cycloheximide, suggesting that protein synthesis was essential for the activation of the nuclei.