Inhibitors of ester hydrolysis as synergists for biological activity of Cecropia juvenile hormone.

In Manduca sexta pupae the sensitivity to exogenous Cecropia C18 juvenile hormone (JH) is governed in large part by the rate at which the hormone is metabolized. By analysing the distribution of labelled JH and its metabolites, when dispensed by injection in light mineral oil, I have shown that the half-life of JH at concentrations ranging from 0·02 to 1 μg/g live weight of insect is approximately 24 hr.When the same doses of JH are dispensed in mineral oil containing endocrinologically inactive carboxylesterase inhibitors, organophosphate, and carbamate insecticides, the hormone's half-life in certain cases is prolonged significantly. The formulations containing those materials which most effectively prolong the hormone's half-life give higher assay scores than equivalent doses of hormone in mineral oil alone.From these results it is inferred that the chemicals tested synergize the Cecropia juvenile hormone's biological activity by serving presumably as inhibitors of the principal enzyme responsible for the rapid breakdown of exogenous C18-JH in haemolymph—a carboxylesterase. Preliminary in vitro experiments with carboxylesterase-rich Manduca pupal blood further support this inference.     

Changes in the morphogenetic response of Tenebrio molitor pupae to juvenile hormone in relation to age

Morphogenetic effect of juvenile hormone (JH) and its analogues, dodecyl methyl ether, ethyl trimethyl dodecadienoate and methylenedioxyphenoxy-6-epoxy-3-ethyl-7-methyl-2-nonene, on carefully timed Tenebrio pupae was determined. These results show that the response of pupal epidermal cells to JH varied with age during the first 48 hr after larval-pupal ecdysis. The pupae showed low morphogenetic response soon after pupal ecdysis but their response increased gradually until 18 hr. The response to JH decreased in pupae older than about 32 hr; and 48 hr old pupae were unresponsive to low doses of JH employed in this study. Age-related differences in the pattern of response of the individual body regions to JH were also observed.The synergistic effect of 1 μg of ecdysterone with these JH compounds was also tested in relation to the age of Tenebrio pupa. The results show that the synergistic effect of ecdysterone was generally limited to >18 hr old pupae. This suggests that the physiological basis of the synergistic effect of ecdysterone may be the latter's ability to synchronize epidermal cells.The significance of these observations in the analysis of time of action of juvenile hormone is discussed.     

Dependence of juvenile hormone activity on haemolymph factor in Tenebrio molitor pupae

Morphogenetic response of Tenebrio molitor pupae to juvenile hormone (JH) varies with age, it being low during the first 6 hr after pupal ecdysis and reaching a peak at about 18 hr after ecdysis. Parabiosis of 6-hr pupa to a 18-hr-old pupa causes a higher morphogenetic response in 6-hr pupa to JH. A similar increase in morphogenetic response was not noticeable when a 0·45 μm Millipore filter was placed between the parabiotic partners, suggesting that the factor(s) may be macromolecular. This view is further supported by the observation that the Millipore filter did not prevent transport of ecdysterone another agent that enhances morphogenetic response of pupae to JH.     

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.     

Hormonal requirements for the larval-pupal ecdysis induced in the cultured integument of Chilo suppressalis

The switchover from a larval to a pupal epidermal commitment was studied on integument tissue fragments from early last-instar larvae (1–2 days after ecdysis) of Chilo suppressalis cultured in Grace's medium containing 0.01–0.5 μg/ml 20-hydroxyecdysone for 24–72 hr. Fragments were subsequently cultured in medium containing 1 μg/ml 20-hydroxyecdysone for 24 hr and maintained in hormone-free media for 6 additional days. The degree of switchover induction was measured as the ratio of the number of tissue fragments showing pupal characteristics to the total number of fragments used. The degree of switchover increased with the duration of culture, as well as with the concentration of the hormone (up to 0.1 μg/ml), in the first hormonal treatment. Above this concentration, apolysis and new cuticle formation were induced without change in the epidermal commitment. Cultured integument fragments from larvae in the diapause stage, 40–50 days after hatching, and from those in the penultimate stage, showed the switchover under almost the same hormonal conditions as those used with tissue from the early last-instar larvae. After the first hormone treatment, culture in hormone-free medium was unnecessary for cuticle tanning. Juvenile hormone II added to the medium (3 ng/ml) in the first hormonal treatment completely inhibited the switchover induced by 20-hydroxyecdysone. The potential use of the C. suppressalis integument as a bioassay system for juvenoids is discussed.     

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.     

Developmental profiles of the mRNAs for Manduca arylphorin and two other storage proteins during the final larval instar of Manduca sexta

When fat body mRNA from the tobacco hornworm larva, Manduca sexta, was translated in a rabbit reticulocyte lysate system, three major polypeptides were found, each having a different developmental profile. One mRNA coded for a 74 kilodalton (K) polypeptide doublet precipitated by an antibody to the arylphorin (manducin). This mRNA was present only during the intermolt feeding phase of the penultimate and the final larval instars. Its appearance 16–24 hr after larval ecdysis was dependent upon the incoming nutrient supply and independent of the juvenile hormone (JH) level. Immunoblots of proteins of the fat body, epidermis, and cuticle revealed the presence of arylphorin in all three tissues. Additionally, several small polypeptides that cross-reacted with the arylphorin antibody were found in the fat body during and up to 24 hr after the last larval molt and in the tanning pupal cuticle. The larval epidermis was also found to contain a small amount of arylphorin mRNA. At the time of the JH decline prior to the onset of metamorphosis, a female-specific mRNA coding for a 79 K translation product appeared. In allatectomized larvae this mRNA was detectable earlier, and its appearance in intact larvae was prevented by application of methoprene, indicating that JH regulates its appearance. At wandering a new mRNA that also codes for a 79 K polypeptide appeared in both sexes and was the major messenger present during the prepupal stage. Neither it nor the female-specific mRNA were translatable after pupal ecdysis.     

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.     

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.     

Hormonal regulation of JP29 in the epidermis during larval development and metamorphosis in the tobacco hornworm,Manduca sexta

Previous studies have shown that the larval epidermis of the tobacco hornworm, Manduca sexta, contains a 29 kDa nuclear protein (JP29) that binds pothoaffinity analogs of juvenile hormone (JH), but does not bind JH I with high affinity. We now find that JP29 is also associated with the insecticyanin granules, and we show that JP29 mRNA is regulated in a complex fashion by both 20-hydroxyecdysone (20E) and JH. Studies with day 2 fourth instar larval epidermis in vitro showed that a molting concentration 12 μg/ml) of 20E caused the disappearance of JP29 mRNA, irrespective of the presence or absence of JH; this effect was dependent on the concentration of 20E (ED₅₀=200 ng/ml). The reappearance of JP29 mRNA around the time of ecdysis required the presence of JH at head capsule slippage (HCS), since little appeared in larvae allatectomized about 6 h before HCS unless JH I was applied at the time of HCS. Maintenance of JP29 mRNA in fifth instar epidermis also required the continued presence of JH in both isolated abdomens and in vitro. Culture of either day 1 or day 2 fifth instar epidermis without hormones for 24 h caused decline of JP29 mRNA, which was accelerated by 20E in a concentration-dependent manner (ED₅₀ = 30 and 10 ng/ml 20E respectively). When day 2 epidermis was exposed to 500 ng/ml 20E for 24 h to cause pupal commitment, JP29 mRNA disappeared. Neither methoprene nor JH I (in either the presence or the absence of the esterase inhibitor O-ethyl, S-phenyl phosphamidethiolate [EPPAT]) was able to prevent this loss, although both slowed its rate. The mRNA for the larval cuticle protein LCP14 was found to be regulated similarly to that for JP29 by 20E, but differently by JH. The JP29 protein was relatively long-live, persisting after the disappearance of its mRNA for at least 19 h during the larval molt and for more than 24 h in vitro. Although trace amounts of JP29 are found for the first 12 h after pupal ecdysis, injection of 5 μg JH II into pupae during the critical period to cause the synthesis of a second pupal cuticle had no effect on the amount of JP29 present. Thus, although the presence of JP29 in larval epidermis is associated with and dependent on JH, high amounts are not associated with the “status quo” action of JH on the pupa. The role of this protein consequently remains obscure. Arch. Insect Biochem. Physiol. 34:409–428, 1997. © 1997 Wiley-Liss, Inc.     

Regulation and significance of ecdysteroid titre fluctuations in lepidopterous larvae and pupae

The last larval moult of Galleria mellonella is induced by an elevation of ecdysteroid titre to more than 200 ng/g. After ecdysis the titre remains very low until 70 hr of the last-instar when a slight elevation in ecdysteroid concentration initiates the onset of metamorphosis. An ecdysteroid peak (275 ng/g), which occurs between 108 and 144 hr, is associated with wandering and cocoon spinning. Pupal ecdysis follows about 20 hr after a large ecdysteroid peak (780 ng/g) with a maximum in slowly-mobile prepupae (160 hr of the last larval instar). The ecdysteroid decrease between the two peaks coincides with the period when the larvae exposed to unfavourable conditions enter diapause. The pupal-adult moult is initiated by a high ecdysteroid peak (1500–2500 ng/g) in early pupae and imaginal cuticle is secreted in response to a smaller peak (ca. 500 ng/g) in the middle of pupal instar.Until early pupae, the ecdysteroid content is regulated by the prothoracic glands. In decapitated larvae the glands become spontaneously active after 30–40 days and the body titre of ecdysteroids undergoes an increase; the glands revert to inactivity when the insects accomplish secretion of pupal cuticle. A similar ecdysteroid increase occurs within 10 days when the decapitated larvae receive implants of brains releasing the prothoracicotropic neurohormone (PTTH). In either case, the pupation-inducing increase of ecdysteroids is 3 times higher than the large ecdysteroid peak in the last-instar of intact larvae. This indicates that the function of prothoracic glands in intact larvae is restrained, probably by the juvenile hormone (JH). Exogenous JH suppresses the spontaneous activation of the prothoracic glands in decapitated larvae and reduces the ecdysteroid concentration in those larvae (both decapitated and intact), whose glands were activated by PTTH. Furthermore, JH influences the PTTH release from the brain in situ: depending on JH concentration and the age and size of treated larvae, the PTTH liberation is either accelerated or delayed.Neither in G. mellonella larvae, nor in the diapausing pupae of Hyalophora cecropia and Celerio euphorbiae, does JH directly activate the prothoracic glands. It is suggested that the induction of the moult by JH in decerebrate insects, which has been observed in some species, is either due to indirect stimulation of ecdysteroid production or to increased sensitivity of target tissues to ecdysteroids. In G. mellonella, a moult occurs at a 5–15 times lower than usual ecdysteroid concentration when the last-instar larvae are exposed to JH.     

Mechanisms of midgut remodeling: juvenile hormone analog methoprene blocks midgut metamorphosis by modulating ecdysone action

In holometabolous insects such as mosquito, Aedes aegypti, midgut undergoes remodeling during metamorphosis. Insect metamorphosis is regulated by several hormones including juvenile hormone (JH) and 20-hydroxyecdysone (20E). The cellular and molecular events that occur during midgut remodeling were investigated by studying nuclear stained whole mounts and cross-sections of midguts and by monitoring the mRNA levels of genes involved in 20E action in methoprene-treated and untreated Ae. aegypti. We used JH analog, methoprene, to mimic JH action. In Ae. aegypti larvae, the programmed cell death (PCD) of larval midgut cells and the proliferation and differentiation of imaginal cells were initiated at about 36h after ecdysis to the 4th instar larval stage (AEFL) and were completed by 12h after ecdysis to the pupal stage (AEPS). In methoprene-treated larvae, the proliferation and differentiation of imaginal cells was initiated at 36h AEFL, but the PCD was initiated only after ecdysis to the pupal stage. However, the terminal events that occur for completion of PCD during pupal stage were blocked. As a result, the pupae developed from methoprene-treated larvae contained two midgut epithelial layers until they died during the pupal stage. Quantitative PCR analyses showed that methoprene affected midgut remodeling by modulating the expression of ecdysone receptor B, ultraspiracle A, broad complex, E93, ftz-f1, dronc and drice, the genes that are shown to play key roles in 20E action and PCD. Thus, JH analog, methoprene acts on Ae. aegypti by interfering with the expression of genes involved in 20E action resulting in a block in midgut remodeling and death during pupal stage.     

Ecdysteroids and diapause in pupae of Heliothis punctiger

Most pupae of H. punctiger enter diapause when reared at 19°C, 12L:12D. When pharate pupae were treated for only 12 hr at 28°C about 50% developed at 19°C. The proportion of non-diapausing pupae increased as the temperature at which the pharate pupal stage was spent increased.The quantity of injected 20-hydroxyecdysone necessary to promote development in diapausing pupae varied from about 1 μg g^?1 soon after pupation to about 4 μg g^?1 after 50 days. It fell somewhat after 150 days.Removing brains from non-diapausing pupae showed that the brain secreted its hormone at the time of pupation (or just before). However, if the pupae were kept at 19°C development did not occur unless the brain remained in situ for at least 20 hr at 28°C. Implanting brains from non-diapausing pupae into diapausing ones had no measurable effect.These results may be explained by postulating that the prothoracic gland is ‘activated’ by exposure to high temperature, but that it reverts to inactivity over a period at 19°C. The ‘active’ gland must then be stimulated by brain hormone for a long period to trigger secretion of its hormone, which results in development. Diapause is thus the result of the failure of the prothoracic gland to secrete.     

Pupal commitment and its hormonal control in wing imaginal discs

The timing of pupal commitment of the forewing imaginal discs of the silkworm, Bombyx mori, was determined by a transplantation assay using fourth instar larvae. The wing discs were not pupally committed at the time of ecdysis to the fifth instar. Pupal commitment began shortly after the ecdysis and was completed in 14 h. When the discs of newly molted larvae (0-h discs) were cultured in medium containing no hormone, they were pupally committed in 26 h. In vitro exposure of 0-h discs to 20-hydroxyecdysone accelerated the progression of pupal commitment. Methoprene, a juvenile hormone analog (JHA), did not suppress the change in commitment in vitro at physiological concentrations. Thus the wing discs at the time of the molt have lost their sensitivity to JH, and 20E is not a prerequisite for completion of pupal commitment. These results suggest that the change in commitment in the forewing discs may begin before the last larval molt.     

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.     

Growth of the male accessory gland in adult locusts: Roles of juvenile hormone,JH esterase,and JH binding proteins

The participation of juvenile hormone (JH) in the regulation of growth and protein synthesis in the accessory reproductive gland of male Locusta migratoria has been investigated. After elimination of endogenous JH with ethoxyprecocene, the accessory gland failed to grow, but growth was restored by a single application of the JH analog, pyriproxyfen. Pyriproxyfen appeared to stimulate total protein synthesis by 3 h, with a significant effect by 12 h, in contrast to 24 h observed in fat body. The dose curve for stimulation of protein synthesis 12 h after applying pyriproxyfen gave an ED₅₀ of 0.1 μg; the dose curve for gland growth at 72 h was biphasic, with steps at about 0.01 μg and 10 μg, suggesting two phases in JH action. SDS-PAGE analysis showed several components that were stimulated by pyriproxyfen, the effect being strongest in an 11 kDa band. A 5 kDa component was enhanced in the soluble and reduced in the particulate fraction after precocene treatment. The accessory gland contained JH esterase activity at levels about 100 times those in fat body or hemolymph, and was higher in precocene treated locusts. Binding activity for [³H]10R -JH III was high in cytosolic and nuclear fractions, and was identified immunologically as due to the previously described hemolymph JH binding protein. The results indicate that the mode of action of JH in the accessory gland may differ from that in the fat body. The presence of intracellular JH binding protein suggests a direct action of JH within the gland, that may be modulated by JH esterase. © 1995 Wiley-Liss, Inc.     

Diapause of the southwestern corn borer, Diatraea grandiosella: Further evidence showing juvenile hormone to be the regulator

Further evidence is presented to demonstrate the involvement of juvenile hormone (JH) in regulating diapause in the final larval stage of the southwestern corn borer. Diatraea grandiosella. JH titres in the haemolymph were measured throughout the entire diapause period. Additional results showed that actively secreting corpora allata are necessary to maintain diapause because allatectomized larvae terminated diapause prematurely. A topical application of JH mimic 2 days after the allatectomy prevented this premature termination of diapause. Intact nervous connections between the brain and the corpora allata were necessary for the maintenance of JH secretion. Other surgical work showed that the brains of nondiapausing larvae exhibited a higher ecdysiotropic activity than those of pre-, early-or mid-diapausing larvae.A single application of a JH mimic was more effective in maintaining a diapause-like state in nondiapausing larvae than were repeated topical applications of C₁₈-JH or an implantation of active corpora allata, suggesting that JH was more rapidly metabolized than was the JH mimic. The oxygen consumption of diapausing larvae which had received repeated topical applications of JH mimic was not significantly elevated over that of the controls indicating that treated larvae maintained a low metabolic rate even though they reverted to the spotted morph. A single application of 0.03 μg JH mimic/larva was sufficient to prolong diapause, thereby confirming that JH is necessary for diapause maintenance.     

The all-or-none rule in morphogenetic action of juvenile hormone on insect epidermal cells

We have investigated ultrastructural changes in the integuments of larval–adult and larval–pupal intermediates produced by exogenous application of juvenile hormone (JH) analogues in Pyrrhocoris apterus (Hemiptera), and Galleria mellonella and Manduca sexta (Lepidoptera). Ultrastructural analysis of the epidermis of these intermediates always revealed the presence of only two types of epidermal cell, which produced morphologically perfect cuticles of the previous and future developmental stages. There were no intermediate cuticles at the level of individual cells. It has been determined that a single epidermal cell constitutes the lowest elementary unit in the perception and realization of the developmental messages conveyed by JH to its target tissues. Further investigations revealed that the responses of individual epidermal cells to JH were strictly autonomous and qualitative, i.e. they were executed according to the ''yes-or-no'' or ''all-or-none'' rule. The neighbouring epidermal cells could realize independently, side-by-side, the quite dissimilar +JH (somatic growth) or -JH (metamorphosis) developmental programmes, although each of them formed biochemically, functionally, and ontogenetically different structures. The qualitative on- and off- signal given by JH for induction of the stationary (+JH) developmental cycle was limited to relatively short, genetically determined, and stage-specific developmental periods of cellular susceptibility to JH. The mosaic mixtures of the heterochronic, larval–pupal or adult epidermal cells, which we found in different proportions on the bodies of the intermediates, revealed two variable, development-related factors: (i) the presence or absence of a minimum effective concentration of JH, and (ii) positive or negative sensitivity of a particular epidermal cell to JH.