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.     

Hormonal requirements for the larval-pupal transformation of the epidermis of Manduca sexta in vitro

In the tobacco hornworm, Manduca sexta, metamorphosis occurs in response to two releases of ecdysone that occur 2 days apart. Epidermis was explanted from feeding final-instar larvae before the first release of ecdysone and was cultured in Grace's medium. When exposed to 1 μg/ml of β-ecdysone for 24 hr and then to hormone-free medium for 24 hr, followed by 5 μg/ml of β-ecdysone for 4 days, the epidermis produced tanned pupal cuticle in vitro. During the first 24 hr of exposure to β-ecdysone, the epidermis first changed its cellular commitment to that for pupal cuticle formation (ET₅₀ = 14 hr), then later (by 22 hr) it became committed to tan that cuticle. Then, for most of the pupal cuticle to be tanned, at least a 12-hr period of culture in hormone-free medium was required before the cuticle synthesis was initiated. Consequently, some events prerequisite to sclerotization of pupal cuticle not only occur during the ecdysone-induced change in commitment but also during the ecdysone-free period. When the tissue was preincubated in 3 μg/ml of juvenile hormone (JH I or a mimic epoxygeranylsesamole) for 3 hr and then exposed to both ecdysone and juvenile hormone for 24 hr, it subsequently formed larval cuticle. The optimal conditions for this larval cuticle formation were exposure to 5 μg/ml of β-ecdysone in the presence of 3 μg/ml of epoxygeranylsesamole for 48 hr. When the epidermis was cultured in Grace's medium for 3 days and then exposed to 5 μg/ml of β-ecdysone for 4 days, 70% of the pieces formed pupal cuticle. By contrast, if both ecdysone and JH were added, 77% formed larval cuticle. Therefore, the change from larval to pupal commitment of the epidermal cells requires not only the absence of JH, but also exposure to ecdysone.     

RNA synthesis in imaginal disks of Galleria mellonella: Effects of alpha- and beta-ecdysone and fat body in vitro

The effects of alpha-ecdysone (α-E), beta-ecdysone (β-E), and larval fat body on morphogenesis and total RNA synthesis in wing imaginal disks of Galleria mellonella were studied. Both ecdysones induce morphogenesis of disks in vitro. Alpha-ecdysone and β-E (0·3–3·0 μg/ml) stimulate RNA synthesis 30 and 60 per cent above control levels, respectively. While less α-E (0·3 μg/ml) is required to increase RNA synthesis than to induce morphogenesis, the reverse is true for β-E. Morphogenesis (i.e. tracheole migration and evagination) can proceed in the presence of concentrations of β-E (0·03 μg/ml) that are subthreshold for the induction of RNA synthesis (0·3 μg/ml). We conclude, therefore, that the increase in total RNA (presumbly ribosomal) is unrelated to and not a prerequisite for tracheole migration or evagination. If morphogenically active preconditioned medium (i.e. medium in which α-E and fat body have been incubated for 48 hr and the fat body then removed) is added to disk cultures, RNA synthesis is not stimulated. Apparently, increases in total RNA caused by both ecdysones may not be necessary for early in vitro disk development. The independent nature of some ecdysone-induced events and implications of our conclusions are discussed.     

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.     

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.     

The synthetic and minimal culture requirements for evagination of imaginal discs of Drosophila melanogaster in vitro

Imaginal discs are induced by β-ecdysone to evaginate and undergo imaginal differentiation in completely defined culture medium (Robb's). The minimal nutritional requirements for evagination are salts, glucose, and 6 or 7 amino acids. Concentrations of β-ecdysone which cause evagination also produce increases in RNA and protein synthesis. Inhibitors of RNA and protein synthesis and amino acid starvation block evagination. Inhibitors of DNA synthesis do not inhibit evagination. The effects of β-ecdysone are concentration dependent. To produce complete evagination, discs must be exposed to low concentrations (0.1 μg/ml) of β-ecdysone for a longer time than to high concentrations (10 μg/ml). However, high concentrations of hormone reduce the rate, and under some conditions, the degree of evagination.     

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.     

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.     

Time studies of ecdysone-action on in vitro apolysis of Chilo suppressalis integument

The relationship between induction of in vitro apolysis and the duration of hormone treatment, and the effects of metabolic inhibitors on the ecdysone-induced apolysis were investigated in the cultured integument taken from the rice stem borer larva, Chilo suppressalis. When fragments of integument were subjected to 0.3 μg/ml β-ecdysone for more than 5 hr and then transferred to hormone free medium, they were induced to apolyse one day after treatment. If the fragments of integument were treated with hormone for 1 to 4 hr at first and then treated with hormone for 2 to 5 hr again after a 5 day interval in hormone free medium, almost all the fragments were induced to apolyse one day after treatment. This result suggests that the action of β-ecdysone on the cultured integument is accumulative. If the fragments of integument were cultured in the medium containing actinomycin-D and then transferred to medium containing β-ecdysone, a strong inhibitory effect on the apolysis of the integument was observed. Similarly, an inhibitory effect appeared when fragments of integument were treated first with hormone and then with puromycin. These results show that the m-RNA synthesis necessary for apolysis was completed within 6 hr after hormone treatment. However, the protein synthesis required for apolysis was not. The relationship of the results obtained from these in vitro experiments to the mode of action of ecdysone is discussed.     

Pupal cuticle formation by Manduca sexta epidermis in vitro: Patterns of ecdysone sensitivity

During the larval-pupal transformation, various regions of the epidermis of Manduca sexta larvae have previously been found to require different lengths of exposure to the prothoracic glands in order to form pupal cuticle. To distinguish between requirements for differing threshold concentrations of ecdysone and those for differing durations of exposure to ecdysone, wandering stage larval epidermis was cultured in Grace's medium. When most of the thick larval cuticle was removed, the epidermis responded to concentrations of β-ecdysone of 1.0 μ/ml or greater for 4 days by forming cysts which later formed tanned pupal cuticle. No fat body or protein supplement was required. When the larval integument was explanted intact, similar requirements for cuticle formation and for tanning were found. All regions of the fifth abdominal segment required similar concentrations of β-ecdysone (0.4–0.6 μg/ml) for 4 days for 50% to form pupal cuticle, but gin trap epidermis required the least exposure to a threshold concentration of ecdysone (1.5 days in 0.9 μg/ml). The anterior dorsal intersegmental region required about 0.5 day longer, followed by the posterior intersegmental and the dorsal intrasegmental regions. Thus, the duration of exposure seemed more important. About 1 day longer of exposure to ecdysone was required for subsequent tanning of the new cuticle than for cuticle formation, yet tanning of the cuticle did not occur with prolonged exposure to ecdysone.     

Effect of cytochalasin B on the evagination in vitro of leg imaginal discs

Cytochalasin B (1 μg/ml) completely inhibited the evagination of isolated leg imaginal discs cultured in vitro in a synthetic medium (ME) containing α-ecdysone (3 μg/ml). In discs precultured for 6 hr in medium ME without the drug, then transferred to cytochalasin B-containing medium, continuation of evagination was stopped immediately. The inhibition of evagination was completely reversible, provided pretreatment with cytochalasin B did not exceed 8 hr. Results are discussed in view of what is known on the effect of cytochalasin B on other developmental systems. Findings are compatible with the primary action of the drug being an alteration of cell surface properties, thus bringing to light the importance of these properties in the course of normal imaginal disc evagination.     

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.     

Mitotic responses of the anterior pericardial wall of Biomphalaria glabrata (Mollusca) subjected to challenge

Using light microscope autoradiography and electron microscopy we studied the effect of juvenile hormone III (JHIII) and β-ecdysone insect molting hormone (β-ecd) on the replication of Tipula iridescent virus (TIV) in suspension cultured cells of Estigmene acrea. JHIII at a concentration of 87.5 μg/ml completely inhibited viral DNA synthesis, but upon removal of JHIII, [³H]thymidine was incorporated into the cytoplasm as detected by autoradiography and virions in developmental stages from the same cell samples were-readily seen by electron microscopy. β-ecd at a concentration of 17.5 μg/ml, unlike JHIII, permitted viral DNA synthesis in the presence of the hormone although at a reduced level when compared to TIV-infected cells. But the presence of β-ecd seemed to prevent capsid formation, although islands similar in fine structure to those of viroplastic centers were seen by electron microscopy. Once β-ecd was removed from the medium, TIV-inoculated cells appeared to synthesize new virions in a normal pattern. Both hormones inhibited host cell DNA synthesis in noninfected cells.     

Interactions between beta-ecdysone and fat body during wing disk development in vitro

We have investigated the actions of beta-ecdysone and fat body on wing disks of Plodia interpunctella in a series of sequential incubations in vitro. These experiments revealed that extended treatment times of beta-ecdysone at concentrations of 0·5 μg/ml or greater inhibited development of disks, and confirm that the presence of a fat body factor in the culture medium prevents this inhibition.     

Uptake of beta-ecdysone by the fat body and membrane vesicles of fat body cells of Sarcophaga peregrina larvae.

The fat body of Sarcophaga peregrina larvae was shown to incorporate ³H-β-ecdysone when it was incubated with the hormone in vitro. Most of the incorporated radioactivity was found in the cytoplasmic fraction as free β-ecdysone, not as a protein-β-ecdysone complex.Rapid uptake and accumulation of β-ecdysone was observed in the membrane vesicles of fat body cells in vitro. The apparent K_m value for uptake was estimated to be 1·25 × 10^?7 M. The β-ecdysone in the membrane vesicles was rapidly released when 2,4-dinitrophenol was added. These results suggest that β-ecdysone was incorporated into the membrane vesicles by active transport and not by free diffusion. The hormone is probably incorporated into larval tissues by the same mechanism as it is incorporated into the membrane vesicles of fat body cells.     

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.     

In vitro synthesis of peritrophic membranes of the blowfly, Calliphora erythrocephala.

Tyrode solution containing added glutamine and Leloup's medium 1 has been used as a basic medium for the in vitro culture of the so-called proventriculus of adult Calliphora erythrocephala to elucidate some of the factors controlling the synthesis of peritrophic membranes (PM) in vitro. The formation rate was chosen as a quantitative criterion for the evaluation of the modifications of the incubation media.After systematic variation of osmolarity, pH, and temperature optimal formation rates were obtained in media with an osmolarity of 320 to 360 mOsmol, a pH of 6·8, and an incubation temperature of 27°C. Under these conditions the average rate of formation was in the modified Tyrode solution 3·0±1·1 mm PM/hr, and in Leloup's medium 3·6±0·8 mm PM/hr. In the modified Tyrode solution the formation of PM was complete after 5 to 7 hr, whereas in Leloup's medium it continued up to 24 hr. The addition of β-ecdysone caused an increase of the formation rate of PM to 4·5 to 5·5 mm PM/hr.The results obtained led to the hypothesis that an osmotically regulated enzyme system could be the limiting factor of the formation rate of peritrophic membranes, i.e. a system which could regulate the internal osmolarity of the formative cells by the interconversion of a bulk polymer and its monomer which are needed for the synthesis of PM.     

The initiation of adult development in Sarcophaga argyrostoma by β-ecdysone

Sarcophaga argyrostoma pupae otherwise destined to diapause can be made to initiate prompt, complete adult development by injection of 0.2 to 0.3 μg β-ecdysone/g body weight, if the injection is given soon after head eversion at the time ecdysone levels would normally increase in developing animals. At these doses some animals show only the earliest signs of adult development and then enter diapause. After two weeks in diapause, a 40-fold higher dose (10 μg/g) is required to initiate development promptly. β-ecdysone can also accelerate the termination of diapause after a time delay which is dose-dependent. Doses of 6 to 10 μg/g lead to hyperhormonal abnormalities affecting antennae, genitalia, and bristle orientation.     

Stages of diapause development in the pupa of Mamestra configurata based on the β-ecdysone sensitivity index

Four distinct stages of diapause development in pupae of Mamestra configurata held at 20°C can be recognized by means of the ‘β-ecdysone sensitivity index’. The latter refers to the ED50 of injected β-ecdysone required to break diapause in half of the treated pupae. Stage 1 begins with the newly-formed pupa, lasts about 3.5 days and is characterized by a rapidly falling ED50. Stage 2 lasts about four weeks during which the ED50 increases by almost 20-fold, from 0.27 μg/g at the beginning to 4.9 μg/g at the end. Stage 3 begins when the pupae are about 4 weeks old and lasts for about six weeks. Stage 3 is the stable diapausing state and is characterized by a virtually unchanging ED50. The onset of stage 4 occurs when the pupae are about 10 weeks old and is recognized by the beginning of a decline in the ED50. Stage 4 precedes the completion of diapause development and may signal the transition of the endocrine system to its active state.Pupal diapause deepens with time in M. configurata. The deepening process evidently occurs during stage 2 of diapause development. Pupae that were transferred to 5°C at the beginning of stage 2 failed to make the transition to stage 3 and were trapped in a very shallow diapause.     

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.