Juvenile hormones and their titer regulation in Galleria mellonella

Juvenile hormones I, II and III occur in Galleria but JH II is dominant. Its concentration reaches a peak of 3 pmol/g body wt in the penultimate instar, drops to zero in the last larval instar and, except for a small peak in prepupae (0.2 pmol/g), remains undetectable until pharate adults. After emergence the titer reaches over 5 pmol/g in both sexes. Presence of JH II is associated with JH II acid; JH III acid occurs even more often, including stages lacking JH III. Brain implantation into freshly ecdysed last instar larvae effects a similar JH peak as in the penultimate instar and causes an extra larval molt. The opposite treatment, i.e. decerebration of fresh last instar larvae, elicits a continuous rise of JH II to 10 pmol/g and an increase of otherwise rare JH I to 3 pmol/g. Sham operations of these larvae or decerebration of old larvae elevate practically only JH II titer to 1–1.5 pmol/g. Implanted brain-corpora cardiaca-corpora allata complexes maintain in various hosts 0.14–1.6 pmol/g of JH II. The significance and regulation of these fluctuations in JH titer are discussed.     

Haemolymph juvenile hormone esterase during the life cycle of the tobacco hornworm,Manduca sexta (L.)

Juvenile hormone (JH) esterase activity was found in the plasma of larvae, pupae and adults of wild-type tobacco hornworms, Manduca sexta. There was a single peak of plasma JH esterase activity approx. 28 h prior to ecdysis in each instar from the second through the fourth instar and a peak of activity prior to both wandering and pupation in the fifth (last) instar. JH esterase activity was high in newly formed male and female pupae but declined to minimal levels by day 1 of the pupal stage. For the remainder of the pupal period, activity was at background levels. JH esterase activity increased again in newly emerged, virgin male and female adults but declined and remained at a low level 1 day after emergence through death. Gel filtration analysis of larval, pupal and adult plasma resolved a single peak of JH esterase activity with an apparent molecular weight of 66,000. However, isoelectric focusing revealed three forms with isoelectric points of 5.5, 5.8 and 6.1. These isoelectric forms were also found in black and white mutants of last instar M. sexta and in purified JH esterase from wild-type larvae. The plasma JH esterase activity metabolized JH I 2–3 times faster than JH III and was sensitive to inhibition by octylthio-1,1,1-trifluoro-2-propanone and insensitive to O,O-diisopropyl phosphorofluoridate. Gel filtration, isoelectric focusing, substrate specificity and developmental studies suggest that the same JH esterases are found in the plasma of larvae, pupae and adults and appear to be different from general (α-NA) esterase.     

Enzyme immunoassays of JH III and JH III diol using acetylcholinesterase as tracer: An alternative to radioimmunoassay

Immunogens were prepared by coupling JH III and JH III diol to human serum albumin. Specific and sensitive antibodies were obtained by immunizing rabbits. Pure acetylcholinesterase (EC 3.1.1.7) from electric eel (Electrophorus electricus) was covalently coupled to the acids from hydrolyzing JH III or JH III diol. The enzyme immunoassays (EIA) were performed in 96-well microtiter plates coated with second antibody (pig anti-rabbit).The JH III EIA performance was equivalent to or better than radioimmunoassay using an iodinated tracer: the sensitivity was 0.91 ng/ml at 50% B/B₀, the detection limit was 0.2 ng/ml; cross-reactivity was less than 1% for the diols of JH I, JH II and JH III, and 30% for JH III acid. For the JH III diol assay, the EIA sensitivity was 1.9 ng/ml at 50% B/B₀ and the detection limit was 0.2 ng/ml; cross-reactivity was less than 1% for JH III and JH III acid, and 14 and 10% for JH I diol and JH II diol. Finally, use of semi-automatic apparatus allowed rapid and easy EIA analyses in which the enzyme label is a long-lived reagent and handling of radioactive compounds is avoided.     

Enhancement of short wing formation and ovarian growth in the genetically defined macropterous strain of the brown planthopper,Nilaparvata lugens

When JH II, III or methoprene was applied in the nymphal stages to two different strains of the brown planthopper which were selected to produce long (macropterous) or short (brachypterous) wing forms, no effect was observed on the molting profile or metamorphosis. Brachypterization of a majority of the presumptive macropters was, however, observed by application of these chemicals, although there was no effect on wing form in the presumptive brachypters. The results show that the sensitive periods for the brachypterization of the presumptive macropters falls between early antepenultimate instar and within 1 or 2days of the penultimate instar, and that the chemicals were effective, in the following order of potency: methoprene>JH III>JH II. Ovarian growth was greatly enhanced in the presumptive macropters when JH III or methoprene was applied twice, within 12h of the 3rd or 4th nymphal instar and 6h before adult emergence. JH II on the other hand had no effect on ovarian growth when applied to the presumptive macropters at any of the nymphal stages. None of the chemicals had any effect on ovarian growth in the presumptive brachypters.     

Juvenile hormone and photoperiodically controlled polymorphism in Aphis fabae: Prenatal effects on presumptive oviparae

All three naturally occurring juvenile hormones (JH's) were shown to have effects on the parthenogenetic/gamic polymorphism of Aphis fabae; they mimicked long day conditions by inducing parthenogenetic forms. When topically applied to fourth instar gynoparae, JH caused the appearance of oviparous/viviparous intermediate morphs in the progeny. JH induced both wing development and embryogenesis in embryonic, presumptive oviparae. Embryogenesis was induced by lower doses of JH. Adult, embryo-containing alatae produced by treatment with high JH doses were capable of flight, and whilst reluctant to reproduce, their few viable progeny were oviparae. They did, however, differ from normal gynoparae in size, occasional presence of scent plaques on the metathoracic tibiae, numbers of secondary rhinaria on the antennae and morphogenetic response to postnatal rearing in long day conditions. The presumptive, oviparous embryos most sensitive to JH treatment were shown to be ca 323 μm in length, close to the stage where their germaria differentiate as parthenogenetic or gamic. Similar effects were observed in the progeny of JH-treated, teneral adult gynoparae but there was no effect on the morph of progeny of long day, alate virginoparae. The JH's differed in potency in the order JH I > JH II > JH III. The treatment of fourth instar gynoparae also induced a terminal batch of apparently normal viviparous progeny in a number of aphids. This result was obtained even at JH doses below threshold for the appearance of oviparous/viviparous intermorphs.     

Juvenile hormone changes associated with diapause induction, maintenance, and termination in the beet webworm, Loxostege sticticalis (Lepidoptera: Pyralidae)

At 22°C and under a long-day photoperiod of L:D 16:8, all the last fifth instar Loxostege sticticalis larvae undergo prepupal stage and pupate without diapause. Under a short-day photoperiod of L:D 12:12, in contrast, they all enter diapause with approximately 36 days diapause maintenance and then terminate diapause spontaneously, although only 44% of the larvae terminated diapause successfully. Changes in hemolymph juvenile hormone (JH I) titers of diapause-destined larvae across diapause induction, maintenance and termination were examined using HPLC, and were compared with those of non-diapause-destined larvae from the fifth instar through pupation. JH I titer of the earliest fifth instar diapause-destined larvae remained at a high level with a peak of 220.4 ng/ml, though it decreased continuously to a minimum of 69.0 ng/ml on day 5 in the fifth instar when the larvae stopped feeding to enter diapause. During the diapause maintenance, JH I titer of the mature larvae increased significantly and maintained a high level until day 31 in prepupae. JH I titer declined and fluctuated at low level from 5 days before pupation. In contrast, JH I titer of both the fifth instar non-diapause-destined larvae and prepupae remained and fluctuated at low level consistently, as well as decreased before pupation. These results indicate that diapause induction and maintenance in this species might be a consequence of high JH, whereas diapause termination can be attributed to low JH titer, which was in agreement with the hormonal regulation observed in many other larval-diapausing insects.     

肿腿蜂类寄生蜂室内控害效能评价——以松脊吉丁肿腿蜂为例

为了开发利用天敌资源防治害虫,科学而客观地评价肿腿蜂对蛀干害虫的控害作用,研究了松脊吉丁肿腿蜂(Sclerodermus sp.)对松褐天牛3龄幼虫的功能反应,建立了肿腿蜂类寄生蜂室内控害效能评价体系,并证明了其可行性。该评价体系包括供试虫源标准、寄生蜂生物学与寄生行为学观察、寄生蜂对寄主的功能反应和寻找寄主效应以及寄生蜂的忠岐指数(Y)4个部分。研究结果表明:松脊吉丁肿腿蜂具有较强的控害潜力,单头雌成虫能防治3—4头松褐天牛3龄幼虫,21d内最多可致死9.07头寄主幼虫;寄主密度对单头寄生蜂寄生作用功能反应的测定结果与对寄生作用寻找效应的测定结果以及对产卵量影响的测定结果一致;综合评价该蜂对松褐天牛3龄幼虫控制效能,释放比为1∶1(即1头肿腿蜂雌蜂:1头3龄松褐天牛幼虫)时最高,其忠岐指数Y为39.63,这可能是肿腿蜂类天敌特有的抚幼习性所致,结论也与寄生蜂生物学特性及寄生行为学观察结果相同。研究结论证明该评价体系是稳定可靠的。评价体系在利用天敌昆虫生物防治害虫时为筛选最佳寄生性天敌种类提供了可行的方法和依据。     

Endocrine changes associated with metamorphosis and diapause induction in the yellow-spotted longicorn beetle, Psacothea hilaris

At 25 degrees C and under a long-day photoperiod, all 5th instar Psacothea hilaris larvae pupate at the next molt. Under a short-day photoperiod, in contrast, they undergo one or two additional larval molts and enter diapause; the 7th instar larvae enter diapause without further molt. The changes in hemolymph juvenile hormone (JH III) titers, JH esterase activity, and ecdysteroid titers in pupation-destined, pre-diapause, and diapause-destined larvae were examined. JH titers of the 5th instar pupation-destined larvae decreased continuously from 1.3 ng/ml and became virtually undetectable on day 13, when JH esterase activity peaked. Ecdysteroids exhibited a small peak on day 8, 1 day before gut purge, and a large peak on day 11, 2 days before the larvae became pre-pupae. The two ecdysteroid peaks are suggested to be associated with pupal commitment and pupation, respectively. JH titers of the 5th instar pre-diapause larvae were maintained at approximately 1.5 ng/ml for 5 days and then increased to form a peak (3.3 ng/ml) on day 11. JH esterase activity remained at a low level throughout. Ecdysteroid levels exhibited a large peak of 40 ng/ml on day 18, coincident with the larval molt to the 6th instar. JH titers of the 7th instar diapause-destined larvae peaked at 1.9 ng/ml on day 3, and a level of approximately 1.1 ng/ml was maintained even 30-60 days into the instar, when they were in diapause. Ecdysteroid titers remained approximately 0.02 ng/ml. Diapause induction in this species was suggested to be a consequence of high JH and low ecdysteroid titers.     

Ecdysteroids and juvenile hormones of whiteflies, important insect vectors for plant viruses

Ecdysteroids and juvenile hormones (JHs) regulate many physiological events throughout the insect life cycle, including molting, metamorphosis, ecdysis, diapause, reproduction, and behavior. Fluctuation of whitefly ecdysteroid levels and the identity of the whitefly molting hormone (20-hydroxyecdysone) have only been reported within the last few years. An ecdysteroid commitment peak that is associated with the reprogramming of tissues for a metamorphic molt in many holometabolous and some hemimetabolous insect species was not observed in last nymphal instars of either the sweet potato whitefly, Bemisia tabaci (Biotype B), or the greenhouse whitefly, Trialeurodes vaporariorum. Ecdysteroids reach peak levels 1-2 days prior to the initiation of the nymphal-adult metamorphic molt. Adult eye and wing differentiation which signal the onset of this molt begin earlier in 4th instar T. vaporariorum (Stages 4 and 5, respectively) than in B. tabaci (Stage 6), and the premolt peak is 3-4 times greater in B. tabaci ( approximately 400 fg/microg protein) than in T. vaporariorum ( approximately 120 fg/microg protein). The JH of B. tabaci nymphs and eggs was found to be JH III, supporting the view that JHs I and II are, with rare exception, only present in lepidopteran insects. In B. tabaci eggs, JH levels were approximately 10 times greater on day 2/3 (0.44 fg/egg or 0.54 ng/g) than on day 5 (0.04 fg/egg or 0.054 ng/g) post-oviposition. Approximately, 1.4 fg/2nd-3rd instar nymph (0.36 ng/g) was detected. It is probable that the relatively high level of JH in day 2/3 eggs is associated with the differentiation of various whitefly tissues during embryonic development.     

3S-(+)-3,7-Dimethyl-1,5-Octadiene-3,7-Diol and Ionone Derivatives from Tea

1-Isobutyl-5-(4-phenoxyphenyl)imidazole (KK-98), an inhibitor of juvenile hormone (JH) biosynthesis in the cockroach, and related imidazole compounds were evaluated against silkworm, Bombyx mori, for their activity to induce precocious metamorphosis. KK-98 induced precocious metamorphosis in the 4th instar larvae at high doses. Replacement of the 4-phenoxy group by a 3-phenoxy or 3-benzyloxy group on the benzene ring increased the activity. Among this series of compounds, 5-(3-benzyloxyphenyl)-1-isopropylimidazole (8) showed the highest activity. The induction of precocious metamorphosis by compound 8 was rescued by the simultaneous application of methoprene, a JH minie. When newly molted 3rd instar larvae were treated with a high dose of compound 8, a few larvae formed larval-pupal intermediates in the 3rd instar stage, which has not been formed by treating of any other imidazoles so far.     

Juvenile hormone analog binding in Manduca epidermis

Of a series of derivatives of JH I and methoprene, iodovinylmethoprenol (IVMA) proved most active (ed₅₀s of 3.2 pmol and 20 nM in the Manduca black larval assay and in the prevention of the 20-hydroxyecdysone-induced change to pupal commitment in the epidermis in vitro, respectively). When incubated with nuclei isolated from day 1 fifth instar abdominal epidermis, [¹²⁵I]IVMA bound specifically to two components with K_ds of 4 and 59 nM. This binding was competed by IVMA and methoprene but not by JH I; similar binding by [³H]JH I was not competed by IVMA or methoprene. Specific binding of IVMA was not found in pupally committed epidermis from wandering larvae, but it reappeared in pupal abdominal and thoracic epidermis but not in the wings. Culture of day 2 fifth instar epidermis with 20-hydroxyecdysone to cause pupal commitment caused the loss of the IVMA nuclear binders whereas culture in the absence of hormortes had no effect, indicating that 20HE in the absence of JH downregulates JH receptors.     

In vivo fluctuation of JH,JH acid,and ecdysteroid titer,and JH esterase activity,during development of fifth stadium Manduca sexta

Juvenile hormone (JH), JH acid, and ecdysteroid titer, and JH esterase activity, were measured in hemolymph from synchronous last stadium larvae of Manduca sexta. JH and JH acids were identified and quantified by GC-MS: JH I and II (and the corresponding acids) were the predominant JH homologs detected in males or females. Maximum levels of JHs and JH acids were observed just following ecdysis to the fifth (last) stadium (day 0, 0 hr) and at the prepupal stage (day 6–day 7). JH titer (≥ 1 ng JH I or II/ml) was higher than JH acid titer (∼0.7 ng JH I acid or JH II acid/ml) in very early fifth stadium larvae. However, this was reversed at the prepupal stage when higher titers of JH acids than JH were observed. JH acid titer began to rise prior to JH titer at the prepupal stage. JH esterase activity rose significantly only after JH or JH acid titers had begun to decline; maximum JH esterase activity was observed at day 3 and day 8. Ecdysteroid titer (measured by RIA) decreased during the last larval molt to a low level by day 0 (0 hr) and to undetectable levels at day 0 (12 hr) of the fifth stadium, by which time JH and JH acid levels had also declined substantially. Just prior to wandering, a small ecdysteroid peak was noted and a slightly elevated level of ecdysteroid was maintained for a further 2 days before a surge in ecdysteroid titer occurred at the prepupal stage, in synchrony with JH and JH acid titer maxima. There was no sexual dimorphism in timing or magnitude of JH, JH acid, and ecdysteroid titer or JH esterase activity.     

Juvenile hormone biosynthesis by corpus cardiacum-corpus allatum complexes of larval Lymantria dispar

• 1.1. A radiochemical assay was used to examine juvenile hormone (JH) synthesis and secretion in vitro by incubating two pairs of larval corpus cardiacum-corpus allatum complexes (CC-CA) from, Lymantria dispar, in 50 μl of osmotically balanced Grace's medium containing 1 μC1 [³H-methyl]-methionine for 6 hr.
• 2.2. For CC-CA of fourth instar female larvae, maximal incorporation of ³H-methyl was 0.15 pmol/pr/hr between days 2 and 3. High pressure liquid chromatographic (HPLC) analysis suggested that the biosynthetic products are mainly JH III with a little JH II at times.
• 3.3. For CC-CA of last instar female larvae, incorporation of ³H-methyl was 0.48 pmol/pr/hr at the beginning of the stadium and decreased to negligible levels by day 10. HPLC analysis suggested that CC-CA of last instar larvae produced only JH III. Volume increases in CA during the last instar were associated with declining activities of JH secretion.
• 4.4. Comparisons of maximal rates of ³ H-methyl incorporation by each unit volume of CA revealed that in the last instar each unit volume (μm³) of glandular tissue secreted 50% more JH than in the fourth instar.

     

Parasitoid-host endocrine relations: self-reliance or co-optation?

High titers of juvenile hormone (JH) maintain developmental arrest in Manduca sexta larvae parasitized by Cotesia congregata. Parasitized hosts exhibit up to 9.5 times greater amounts of total hemolymph JH (from 0.6±0.09 to 2.51±0.43 ng/ml) compared to non-parasitized controls. Elevated titers are observed throughout the fifth instar, even beyond egression of the parasitoids on day 5. GC–MS analysis revealed that in hemolymph of unparasitized control larvae, JH I is the major homolog and levels of JH III are negligible; in parasitized individuals the amounts of JH I, II, and III rise, and JH III predominates. Neck ligation ensured separation of M. sexta’s corpora allata from the posterior section, which contained most of the parasitoids in the infected insects. When the posterior region was sampled, JHs were not detected in the non-parasitzed larvae, but in those parasitized, JH III was found (1.98±0.29 ng/ml, 24 h post-ligation). JH III was the only homolog produced and secreted by the parasitoid in in vitro culture. This is the first report stating that a parasitoid secretes JH III and may contribute, at least in part, to the circulating titer in the host hemocoel, concurrently promoting host production of JH I and II.     

In vitro inhibition of the corpora allata by a larval brain factor in the cockroach Diploptera punctata

The inhibitory activity of extracts of brains from final instar male and female larvae on release of newly synthesized juvenile hormone (JH) was examined, as was the responsiveness of corpora allata (CA) from males and females to brain extract. Aqueous extracts of protocerebra from day 0 and day 14 final instar larvae (in which the CA are active and inactive, respectively) were tested on CA from adult females in vitro. For comparison, protocerebra from day 0 adult males and females were also tested. Dose responses were similar for protocerebra from all animals tested. In each case a dose of 1–2 protocerebral equivalents was required for maximal response.CA from penultimate instar females were inhibited to a greater extent by brain extract than those of males. The response of CA from final instar larvae to brain extract declined in the first few days of the stadium as the ability of the glands to biosynthesize JH declined.     

The effect of juvenile hormone on pupal pigmentation of Pieris brassicae L.

The role of juvenile hormone (JH) in the morphological colour adaptation of pupae of Pieris brassicae controlled by environmental factor was analyzed. First the effects of JH I and its analogue, Farnesyl-Methyl-Ether (FME) were tested. Secondly the JH-titres of the last instar larvae were measured under various light conditions which influence the future pigmentation of the pupae.During the sensitive period, which occurs before pupation, blue light (410 nm) produces the strongest, darkness medium, and yellow light (570 nm) the lightest pigmentation of the pupae.JH I as well as FME has an inhibiting effect on the formation of the black spots in the cuticle. However, this effect only becomes apparent (a) if the insects are kept under blue light during the sensitive period (which normally leads to a strong black pigmentation) and (b) only when these animals were treated with JH I or FME either at the beginning, or 10 hr after the beginning of the sensitive period. In the last larvae instar, JH could be found only during the sensitive period. Fourteen hours after the beginning of the sensitive period the JH concentration reaches a maximum of 30–100 pg JH per insect. The JH-titre resulting from blue light conditions is significantly different from those of the larvae kept under white or yellow light. An additional maximum of 60 pg JH per animal was found 8 hr/after the beginning of the sensitive period. Obviously, JH affects the process of pigmentation of the pupae, but the described results are not sufficient to explain thoroughly the regulation of pigmentation modified by environmental factors. The effects of further factors are discussed.     

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.     

A Biochemical Evidence of the Inhibitory Effect of Diflubenzuron on the Metamorphosis of the Silkworm,Bombyx mori

Diflubenzuron (DFB) has been known to prevent metamorphosis of silkworm, Bombyx mori, from larval to pupal stage at low dose exposure. To explain this inhibitory action of DFB, a hypothesis was raised that DFB acts like juvenile hormone (JH) or DFB inhibits JH esterase to increase endogenous JH titer. A JH bioassay using isolated abdomen clearly indicates that DFB does not act as JH analog because DFB did not induce vitellogenesis in the isolated female abdomen, while endogenous JHs did significantly. General esterase activities in hemolymph were lower in DFB-treated fifth instar larvae than in the control larvae, but there was no difference between fat body esterase activities in both groups. Two hemolymph esterases (‘E1’ and ‘E2’) of the fifth instar larvae were separated and visualized by α-and β-naphthyl acetate. From in vitro incubation experiment, the cathodal esterase (‘E1’) was sensitive to DFB at its nanomolar range. Considering the fact that early fifth instar larvae have high level of JH esterase in the hemolymph, these results suggest that DFB inhibit larval to pupal metamorphosis by blocking JH degradation, which increases endogenous JH titer especially at the critical period when the larvae determine metamorphic development at the following molt.     

Development changes in juvenile hormone and juvenile hormone acid titers in the hemolymph and in-vitro juvenile hormone synthesis by corpora allata of the silkworm,Bombyx mori

A simple method was developed to quantify hemolymph juvenile hormone (JH) and JH acid in hemolymph extracts from Bombyx mori with an established radioimmunoassay (RIA) for JH I. When various organic solvent extracts of hemolymph were assayed by RIA, levels of non-specific binding of the labeled ligand in the assay were determined to be greater than 50% of the maximum amount of the label bound by the antiserum. When hemolymph was diluted with methanol:water:8.4N ammonium hydroxide (10:9:1) and extracted with isooctane, non-specific binding was only 50% higher than control levels obtained with the assay buffer alone. The organic phase contained only JH and aqueous phase, JH acid. Consequently, this extraction method was used to prepare samples for RIA and enabled the separate measurement of JH and JH acid in hemolymph. With this method, changes in the hemolymph titers of JH and JH acid were determined from the third instar through early pupal stage of Bombyx mori. Changes in the in vitro secretory activity of corpora allata and brain-corpora cardiaca-corpora allata complexes from fifth instar larvae were also determined by using JH I RIA of the incubation medium.     

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.