Growth and silk formation of silkworm larvae influenced by phytoecdysones

The fourth and fifth instar larvae of the silkworm were reared on artificial diets containing ponasterone A, ecdysterone, and inokosterone. The growth of the larvae and their silk glands, fibroin-synthesizing activity, and silk formation have been investigated. With a diet containing ponasterone A, the fourth instar larvae grew slowly and only a few larvae could ecdyse, while the growth of the fifth instar larvae was disturbed and they died with a darkening of the skin. Ponasterone A also inhibited the growth of the silk glands during the fifth instar. In contrast, the other two phytoecdysones did not greatly influence larval growth. The fourth instar larvae grew rapidly and their ecdysis was advanced with a diet which contained 10 μg of inokosterone/1 g of dry diet. The diet which contained 5 μg of ecdysterone or 10 μg of inokosterone/1 g of dry diet accelerated maturation, while that containing 10 or 20 μg of ecdysterone, or 40 μg of inokosterone, delayed maturation of the fifth instar larvae.Only phytoecdysones caused a decrease in growth of the silk glands in the early half of the instar, and a large amount of phytoecdysones accelerated their growth during the last part of the fifth instar. The fibroin-synthesizing activity was levelled up by feeding ecdysterone and inokosterone, and inokosterone appreciably stimulated activity. Assay of in vitro fibroin synthesis showed that ponasterone A competed with ecdysterone in a stimulative action. Silk formation was much lower in larvae fed the diet containing 5 μg of ecdysterone or 10 μg of inokosterone/1 g of dry diet and was far greater in larvae fed the diet containing 40 μg of inokosterone than in the controls.     

Ecdysterone and an analogue of juvenile hormone on the autophagy in the cells of fat body of mamestra brassicae.

The effect of ecdysterone and a juvenile hormone analogue (JHa) on autophagy and heterophagy was investigated in the fat body cells of the last larval instar of Mamestra brassicae. In the course of normal development autophagic vacuoles and protein granules of heterophagic origin begin to accumulate in these cells, on the 4th and 5th day of the last larval stage respectively. When ecdysterone (10 mug/g body weight) was administered to the larvae for 24 h either on the 1st or on the 2nd day of the last larval stage, autophagic and heterophagic vacuoles appeared in the cells as early as on the 2nd or 3rd days. Autophagy was also observed in the cells of one-or two-day-old last larval fat body after a 5 h incubation in a medium containing 10 mug/ml ecdysterone, in vitro. Ligation of the last thoracic segment resulted in inhibition of metamorphic changes in the fat body lobules of the isolated abdomen. Injection of 10 mug ecdysterone into the isolated abdomen resulted in an appearence of autophagic vacuoles in these cells, too. JHa treatment, when started on the 2nd or 3rd day of the last larval stage, inhibited both auto- and heterophagy and the fat bodies maintained their larval character. Treatment started on the 4th or 5th day proved either ineffective or lethal. It is concluded that the auto- and heterophagy taking place in the larval fat body cells are stimulated by ecdysterone and inhibited by JHa. Experiments performed in vitro or on ligated animals in vivo provided evidence for a direct action of ecdysterone at the cellular level.     

Prothoracic gland activity and blood titres of ecdysone and ecdysterone during the last larval instar of Locusta migratoria L.

The kinetics of secretion of ecdysone by the prothoracic glands of Locusta migratoria were studied during the last larval instar. Three stages of intense production of ecdysone (α-ecdysone) were monitored during this developmental period: they correspond to three peaks of moulting hormone concentration in the blood, which indicates that the main regulation of the moulting hormone titre is achieved through variations in prothoracic gland activity. In the haemolymph the ratio of ecdysone to ecdysterone (20-hydroxy-ecdysone) is in favour of ecdysone during the two first moulting hormone peaks ecdysterone being by far predominant over ecdysone at the time of the third (major) peak; these results support previous studies on the metabolic fate of injected labelled ecdysone during the same developmental period in Locusta migratoria.     

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.     

Simultaneous determination of molting and juvenile hormone titers of the greater wax moth

A simple and rapid extraction procedure was developed to determine simultaneously the molting hormone (MH) and juvenile hormone (JH) activity in a single insect tissue sample. From the onset of the last larval stage to adult eclosion of the greater wax moth, Galleria mellonella, three JH peaks were noted: at the time of the sixth larval ecdysis, 1 day before the seventh larval ecdysis, and at the time of adult eclosion. Three MH peaks were recorded for the male: at 1 day before the sixth larval ecdysis, 1 day before the seventh larval ecdysis, and 2 days after pupation. In the female, a fourth peak was shown at the time of adult eclosion. This fourth peak exhibits the highest molting hormone activity of all samples, 1600 Musca units/g of fresh tissue or an equivalent of 5.6 μg/g of ecdysterone. Eighty per cent of this MH accumulated in the ovary. The significance of MH and JH titers as related to the endocrine regulation of development is discussed in the light of this finding.     

Juvenile hormone and DNA synthesis in imaginal disks of Calliphora erythrocephala: results of a new incubation technique.

An in vitro incubation technique in which imaginal disks are exposed to juvenile hormone and some of its analogues is presented. These substances were shown to have an inhibitory effect on the incorporation of tritiated thymidine (³HTdR) during the post-feeding period of the last larval instar of Calliphora. The technique makes it possible to investigate the nature of the effects of ecdysterone and juvenile hormones on the DNA synthesis in imaginal disks of exo- and endopterygote insects.     

Ecdysterone responsive functions in the mutantl(1)su(f) ts67g ofDrosophila melanogaster

Summary Transferring the temperature sensitive mutantl(1)su(f) ^ts67g from 25° C to 30° C before or early in the third larval instar blocks the increase in the ecdysterone titer that normally occurs at the end of the larval period. Feeding exogenous ecdysterone to these hormone-deficient larvae results in the formation of pseudopupae. The mutant was used to study ecdysterone-inducible functions in late larval salivary glands by preparing three animal samples with different hormone titers: the titer was low in one sample because of an earlier temperature shift, high in a second sample because the larvae were subsequently transferred to ecdysterone-supplemented food, and also high in a third sample that was kept at 25°C, providing a control for normal development. The effect of the different hormone conditions was studied by³⁵S-methionine labeling of the salivary gland proteins during the larval to prepupal transition and the prepupal period. The results indicate that synthesis of several of the proteins normally appearing during the transition and prepupal period is induced by exogenous ecdysterone.     

Correlations between epidermal cell structure and endogenous hormone titers during the fifth larval instar of the tobacco hornworm, Manduca sexta

Epidermal cell morphology and cuticle production in Manduca sexta are directly influenced by both ecdysterone and juvenile hormone. Up to day 6 of the last larval instar, post-molt endocuticle is continuously deposited even though cells undergo a partial and temporary separation from the overlying cuticle at the time when a small ecdysteroid peak is detected (approximately day 3.5). At about days 6--7 when another, larger ecdysteroid peak is present, apolysis occurs accompanied by the appearance of edcysial droplets. Following apolysis, layers of pupal cuticle are deposited. Increased quantities of rough endoplasmic reticulum characterize the epidermis at times of peak endocuticle deposition (day 3, larval cuticle; day 9, pupal cuticle). Dense pigment inclusions are found in epidermis from the day of ecdysis to the last larval instar until they are eliminated 5 days later. These dense bodies migrate from cell apex to base in the absence of juvenile hormone (or in the presence of a negligible amount of juvenile hormone) and probably contain insecticyanin.     

Do the brains of wax moth larvae secrete an allatotropic hormone?

The hypothesis that the brains of young, last instar larvae of Galleria mellonella (L.) initiate supernumerary larval apolyses by secreting an ‘allatotropic factor’ was reexamined. It was confirmed that following bilateral allatectomy the larvae lose their ability to produce supernumerary instars (superlarvae) in response to implanted brains. The JH analog Altosid caused the allatectomized larvae to undergo extra apolyses irrespective of whether or not brains had been implanted. Although the percentage of superlarvae obtained following Altosid treatment was not increased by the implanted brains, the onset of extra apolyses was accelerated. This suggests that the brain can promote larval-larval apolyses without acting first on the corpora allata (CA). Presumably, it does so by producing prothoracotropic hormone.The propensity to generate new larval structures was tested by injecting ecdysterone into larvae 48 and 65 hr after they had been allatectomized. Within 48 hr after both CA had been removed the precocious apolysis resulted in individuals with antennae that were partly larval and partly pupal, and by 65 hr the ability to reproduce larval parts had diminished further. Those that were hemi-allatectomized did not demonstrate this impairment. The results were consistent with the interpretation that allatectomy abolishes the capacity to produce superlarvae because the JH titer declines to a level insufficient to permit expression of the larval genetic program during the next moulting cycle. This is offered as an alternative to the hypothesis that allatectomy prevents implanted brains from producing superlarvae because the target organs of the ‘allatotropic factor’ have been removed.An attempt was made to confirm the observation that brains from young, last instar larvae are more effective initiators of supernumerary apolyses than those from donors in the process of pupating. There was no evidence for a different endocrine function by the brain during the two stages.     

Ecdysterone induced protein synthesis in salivary glands and in fat body of Drosophila melanogaster larvae

Salivary glands of 3rd instar larvae of Drosophila melanogaster were labeled with ³H-leucine in the presence and absence of ecdysterone. Twentysix ecdysterone inducible proteins were detected. Their induction was correlated with puff stage. Synthesis of fifteen proteins commenced during early puff stage (PS2); synthesis of seven others at late puff stages (PS8–10). Synthesis of four proteins was induced between puff stage 3/4 and 7/8. Thus, the hormonal induction of protein synthesis generally reflected the appearance of early and of late puffs as described by Ashburner (1972). Eleven ecdysterone inducible proteins were detected in larval fat body in vitro. Comparison of the fat body to the salivary gland proteins revealed that one of the ecdysterone induced fat body proteins was identical in molecular weight and charge to one of the proteins induced by ecdysterone in salivary glands.     

Regulation of hemoglobin synthesis by ecdysterone and juvenile hormone during development of Chironomus thummi (Diptera)

Chironomus thummi contains nine soluble hemoglobins (Hbs) in the larval hemolymph which can be resolved by 12.7% acrylamide gel electrophoresis (pH 8.65). Hemoglobins 2 and 3 are stage specific for the 4th instar and are first detected by day 4 of this stage in vivo, being absent in the 3rd instar. Fat-body cultures in the presence of 3H-delta-aminolevulinic acid and 14C-amino acids synthesize and secrete labelled Hbs, as was assayed by acrylamide gel electrophoresis and immunoprecipitation of Hbs recovered from the culture medium. During development from 3rd instar to pupa, Chironomus fat body undergoes functional changes, being actively involved in Hb synthesis in intermolt periods and inactive with respect to Hb production during molting. The repression of Hb synthesis is reversed following the molt from the 3rd instar to the 4th instar. Metamorphosis is related to a gradual and irreversible loss of Hb synthesis and secretion by the fat body. The treatment of fat body in vitro with ecdysterone inhibits Hb synthesis in tissue from intermolt animals, even in the presence of excess methoprene, a potent juvenile hormone analogue. In contrast, immunoprecipitation of the translation products from a wheat-germ cell-free system, using mRNA from ecdysterone-treated 4th-instar fat body as a template, shows significant synthesis of globins, suggesting that ecdysterone does not affect the amount or template activity of globin messages. Methoprene induces the precocious in vitro synthesis of Hbs 2 and 3 in day-2 4th-instar fat body and enhances all Hb synthesis in the absence of ecdysterone. In vitro treatment with methoprene activates newly molted fat body to synthesize Hbs 2 and 3 in vitro. The process of Hb induction by this analogue is completely inhibited by actinomycin D or ecdysterone. Fat body from animals already exposed to high endogeneous ecdysterone titer are insensitive to treatment with this juvenile hormone analogue. Intermolt larvae normally possess stable Hb mRNA molecules, because actinomycin-D administration in vitro does not affect Hb synthesis for as long as 30 h, whereas it effectively inhibits all RNA synthesis in the fat body. Immunoprecipitation of globin translated in vitro from mRNA from 2-day-old 4th-instar larvae treated in vivo with methoprene shows enhanced synthesis of globins 2 and 3, as compared to controls with no treatment. It is suggested that both juvenile hormone and ecdysterone regulate Hb synthesis in Chironomus; juvenile hormone affecting the activity of Hb genes, and ecdysterone modulating the level of Hb gene expression.     

Biosynthesis and degradation of juvenile hormone in corpora allata and imaginal wing discs of Galleria mellonella (L.)

The rate of juvenile hormone (JH) biosynthesis by corpora allata-corpora cardiaca complex (CA/CC) during two last larval instars of Galleria mellonella was analysed. The rate of biosynthesis reaches maxima at the beginning of the VIth and VIIth instars. It is markedly reduced before the last larval ecdysis and after the first day of the last larval instar. After passing the second day of the last larval instar CA/CC exhibits again an increased ability for the biosynthesis of JH.The JH esterase activity in CA/CC is very low at the beginning of last larval instar and rapidly increases after the first day of this instar. Beginning on the second day of last larval instar the rate of JH hydrolysis is always higher than the rate of JH synthesis in CA/CC. It is concluded that the secretion of JH by CA/CC is possible until the second day of the last larval instar. After this, JH-acid can be supplied by CA/CC to peripheral tissues.The imaginal wing discs of mobile prepupa exhibit the ability to methylate JH-acid. It is concluded that some elevations of JH titre in G. mellonella haemolymph after the second day of VIIth instar are due in part to JH-acid methyltransferase activity in the imaginal discs.     

Analysis of molting and metamorphosis in the ecdysteroid-deficient mutant L(3)3DTS of Drosophila melanogaster

The dominant temperature-sensitive mutation L(3)3^DTS (DTS-3) in Drosophila melanogaster causes lethality of heterozygotes during the third larval instar at the restrictive temperature (29°C). Temperature-shift experiments revealed two distinct temperature-sensitive periods, with lethal phases during the third larval instar (which may persist for 4 weeks) and during the late pupal stage. At 29°C mutant imaginal discs are unable to evert in situ, but did evert normally if cultured in the presence of exogenous ecdysterone or when implanted into wild-type larval hosts. The only morphologically abnormal tissue present in the lethal larvae is the ring gland, the prothoracic gland being greatly hypertrophied in third instar DTS-3 larvae. Injection of a single wild-type ring gland rescued these mutant larvae, indicating that the mutant gland is functionally, as well as morphologically, abnormal. Finally, the mutant larvae were shown to have less than 10% of the wild-type ecdysteroid levels. These results are all consistent with a proposed lesion in ecdysteroid hormone production in DTS-3 larvae. A comparison with the phenotypes of other “ecdysone-less” mutants is presented.     

Hormonal effects on carotenoid uptake by the silk gland in the silkworm, Bombyx mori

The carotenoid uptake by the silk gland of the silkworm (Bombyx mori), which occurs only during the middle to late period of the last (fifth) instar in the natural condition, was studied in relation to the hormonal controls. During certain stages of the fourth and last instars, the corpus allatum hormone (JH) was found to inhibit the activation of the absorbing function of the silk gland. The absorbing activity was inactivated, if the activated silk gland was implanted into larva at the late stage of the fourth instar in the presence of the moulting hormone (MH). As more ponasterone-A (ecdysone-analogue) was injected into decapitated larvae, the pigmentation of the silk gland was increased; but injection of a high titre inhibited its activity. It seems that, through serial transplantations, the silk gland inactivated experimentally at the late stage of the fourth instar is reactivated in the presence of MH during the middle to late period of the last instar. The results indicate that MH and JH at each stage control the activity of the carotenoid uptake.     

Analysis of precocious metamorphosis induced by application of an imidazole derivative to early third instar larvae of the silkworm,Bombyx mori

When an imidazole derivative (KK-42) was applied to day 1 third instar larvae of the silkworm, Bombyx mori, 100% underwent precocious metamorphosis at the end of the fourth instar. Thus, the fourth instar becomes the last instar in these KK-42–treated larvae. The endocrine systems underlying the precocious metamorphosis were analyzed in the present study. Hydroprene application during the prolonged third instar after KK-42 treatment can prevent precocious metamorphosis, and the results showed dose-dependent and stage-specific effects. From analysis of the developmental changes in ecdysteroid levels in both KK-42–treated larvae and KK-42– and hydroprene-treated larvae, we conclude that changes in JH levels during the third larval instar can modify the secretion pattern of prothoracic glands and that during the next larval instar, very low ecdysteroid levels during the early stages of the presumptive last (fourth) larval instar are directly related to precocious metamorphosis. Arch. Insect Biochem. Physiol. 36:349–361, 1997. © 1997 Wiley-Liss, Inc.     

Growth-blocking peptide titer during larval development of parasitized and cold-stressed armyworm

Growth-blocking peptide (GBP) has been isolated for the first time from the haemolymph of the host armyworm Pseudaletia separata whose development was halted in the last larval instar stage by parasitization with the parasitoid wasp Cotesia kariyai. Recent studies demonstrated that GBP not only exists in the plasma (haemolymph without cells) of parasitized last instar larvae, but also in the plasma of nonparasitized penultimate (5th) instar larvae. Monoclonal antibodies were prepared to measure the titers of GBP in nonparasitized and parasitized larval plasma. One of three monoclonal antibodies raised against GBP, which is the most specific for GBP, was used to quantify the concentration of plasma GBP. As this antibody recognized two plasma peptides other than GBP in crude plasma fractions, each plasma peptide fraction was separated by a reversed phase HPLC, and then plasma GBP level was measured by ELISA. The highest level of plasma GBP detected on Day 0 of the penultimate instar larvae was gradually decreased throughout the larval growth except for the temporary increase on Day 0 of last larval instar. After parasitization on Day 0 of last larval instar, two peaks of plasma GBP titer were detected during the last larval instar, one day and six days after parasitization. This characteristic increase and decrease in plasma GBP level was also observed by transferring last instar larvae of the armyworm from 25 to 10°C, as a result of which larvae delayed pupation by more than 15 days. From these results, it is reasonable to propose that plasma GBP in lepidopteran larvae might control certain upstream steps in a cascade of events leading to pupation; thus, an elevated level of plasma GBP interferes with normal metamorphosis from larvae to pupae.     

Hormonal regulation of pupation in the codling moth, Laspeyresia pomonella

ABSTRACT. According to the different reactions to the juvenoid Altosid®, the last larval instar (L₅) of Laspeyresia pomonella (L.) (Tortricidae) reared under 'long day' conditions (constant light) was subdivided into three sensitive phases: an additional larval instar, a larval–pupal intermediate, or a pupa. Under short day conditions, the prothoracotropic effect of juvenile hormone (JH) in L₅, which have a continuous high titre of JH during the whole instar, indicated that it is not a particular titre of JH but a rise in the titre that can induce the production of moulting hormone. Neck-ligation experiments showed that JH acts not directly on the prothoracic glands but via the head, probably via the neurosecretory system. The meaning of the JH-peak in mature L₅ reared under long days was determined either by injections with the anti-JH, precocene II, in combination with applications of Altosid, or by forcing precocene-treated larvae to a precocious moult by injecting them with ecdysterone. Precocene delayed, and JH accelerated pupation if administered 4.5 days after the L₅ -moult. JH was also found to stimulate the growth and differentiation of the imaginal discs. Moulting hormone in long-days reared insects was detected one day after the larvae had spun their cocoon, with a maximum on the second day after spinning. The hormone was also present in freshly moulted pupae. Neck-ligation of mature larvae indicated that the delay between activation of the prothoracic glands and the production of an effective amount of moulting hormone is less than one day.     

The metabolism of 3H-moulting hormone in Calliphora erythrocephala during larval development

The activity in whole insects for converting ³H-α-ecdysone to ³H-β-ecdysone after injection is low (half-maximal) in young last instar larvae, maximal in mature larvae, and minimal (fourth-maximal) at the white puparial stage. Because moulting hormone titre is low throughout the last larval instar and increases at the formation of the puparium it appears that hydroxylation at C-20 is not a key step in regulating β-ecdysone biosynthesis during larval development.The activity for catabolizing ³H-β-ecdysone is maximal in second instar larvae, about thirdmaximal throughout most of the third instar, and minimal at pupariation (thirtieth-maximal). Thus inactivation may play a rôle in regulating moulting hormone titre during larval development.