Larval juvenile hormone treatment affects pre-adult development,but not adult age at onset of foraging in worker honey bees (Apis mellifera)

Previous research has shown that juvenile hormone (JH) titers increase as adult worker honey bees age and treatments with JH, JH analogs and JH mimics induce precocious foraging. Larvae from genotypes exhibiting faster adult behavioral development had significantly higher levels of juvenile hormone during the 2nd and 3rd larval instar. It is known that highly increased JH during this period causes the totipotent female larvae to differentiate into a queen. We treated third instar larvae with JH to test the hypothesis that this time period may be a developmental critical period for organizational effects of JH on brain and behavior also in the worker caste, such that JH treatment at a lower level than required to produce queens will speed adult behavioral development in workers. Larval JH treatment did not influence adult worker behavioral development. However, it made pre-adult development more queen-like in two ways: treated larvae were capped sooner by adult bees, and emerged from pupation earlier. These results suggest that some aspects of honey bee behavioral development may be relatively insensitive to pre-adult perturbation. These results also suggest JH titer may be connected to cues perceived by the adult bees indicating larval readiness for pupation resulting in adult bee cell capping behavior.     

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.     

A putative new juvenile peptide hormone in lepidopteran insects.

A growth-blocking peptide (GBP) with repressive activity against juvenile hormone (JH) esterase has been isolated from the last (6th) instar larval plasma of the armyworm Pseudaletia separata (Lepidoptera: Noctuidae) parasitized by the parasitoid wasp Apanteles kariyai (Hymenoptera: Braconidae) (1,2). This study demonstrates that GBP not only exists in the plasma of parasitized last instar larvae, but also in the plasma of unparasitized penultimate (5th) instar larvae, while the plasma of last instar larvae does not contain any detectable amount of GBP. The detection of GBP in unparasitized penultimate instar larvae, before the final larval molt, demonstrates that this factor is naturally occurring in the insect larva before the last larval instar and is seemingly coordinating, along with JH, the regulation of juvenile characteristics. This finding suggests the existence of a new type of juvenile peptide hormone in lepidopteran insects.     

Influence of the braconid Glyptapanteles liparidis on the juvenile hormone titer of its larval host,the gypsy moth,Lymantria dispar

The increase in the juvenile hormone (JH) III titer in the hemolymph of Lymantria dispar larvae that were parasitized by the endoparasitoid braconid, Glyptapanteles liparidis, during the host's premolt to third instar, coincided with the molt of the parasitoid larvae to the second instar between day 5 and 7 of the fourth host instar. It reached a maximum mean value of 89 pmol/ml on day 7 of the fifth instar while it remained below 1 pmol/ml in unparasitized larvae. Only newly molted fifth instar hosts showed a low JH III titer similar to that of the unparasitized larvae. JH II, which is the predominant JH homologue in unparasitized gypsy moth larvae, also increased relative to controls in the last two samples (days 7 and 9) from parasitized fourth and fifth instars. Compared to unparasitized larvae, a generally reduced activity of JH esterase (JHE) was found in parasitized larvae throughout both larval stages. The reduction in enzyme activity at the beginning and at the end of each instar, when the JHE activity in unparasitized larvae was high, may be in part responsible for the increased JH II and JH III titers in parasitized larvae. Ester hydrolysis was the only pathway of JH metabolism in the hemolymph of unparasitized and parasitized gypsy moth larvae as detected by chromatographic assays. © 1996 Wiley-Liss, Inc.     

Effects of ultralow doses of fenoxycarb on juvenile hormone–regulated physiological parameters in the silkworm,Bombyx mori L.

Effects of fenoxycarb at ultralow doses were investigated on juvenile hormone (JH)–regulated parameters in the silkworm, B. mori. Like JH, this non-terpenoid carbamate is able to induce permanent larvae in the last larval instar. However, whereas micrograms of JH are needed to produce this effect, only a few picograms of fenoxycarb are necessary to induce the same effect. The effects of fenoxycarb observed in this study were only visible from day 4 of the last larval instar—that is, when the JH titer has dropped to undetectable levels and JH-repressed physiological parameters would naturally be expressed. We observed that the permanent larvae induced with low doses of fenoxycarb (100 pg/larva) had no 20-hydroxyecdysone (20E) peak. Their prothoracic glands (Pgs) were completely inactive and very weakly sensitive to prothoracicotropic hormone (PTTH). Fenoxycarb at doses of 1 ng/larva also significantly inhibited silk gland growth and coloration, whereas carotenoid content of the hemolymph was maintained at high levels, which could reflect an inhibition of its uptake by the silk glands. Total hemolymph protein levels in last instar larvae were also depressed at these doses. So, it seems that low doses of fenoxycarb are sufficient to maintain in a juvenilized status the physiological parameters that are normally expressed when JH titer has declined. Moreover, from an endocrinological viewpoint, we demonstrated that the corpora allata (CA) are not necessary for fenoxycarb to induce those effects and discussed its possible mode of action. Arch. Insect Biochem. Physiol. 37:178–189, 1998. © 1998 Wiley-Liss, Inc.     

Titres of juvenile hormone I,II and III in Spodoptera littoralis (Noctuidae) from the egg to the pupal moult and their modification by the egg-larval parasitoid Chelonus inanitus (Braconidae)

Physico-chemical analysis of juvenile hormones (JHs) of Spodoptera littoralis revealed highest quantities in the second half of embryonic development and in newly hatched 1st instar larvae. At these stages, mostly JH II, JH I and little JH III were found, while in later stages only JH II and JH III were found. Titres fluctuated in a similar manner in all larval instars, being lowest during the moults. In last (=6th) instar larvae, JHs disappeared in the late feeding-digging stage and again increased in the early prepupal stage. Parasitisation with Chelonus inanitus, a solitary egg-larval parasitoid which induces in its host the precocious onset of metamorphosis in the 5th instar, did not alter JH homologue composition but led to a disappearance of JHs in the 5th instar. Implantation of a parasitoid larva into early 5th instar larvae containing polydnavirus/venom caused a drop in the JH titre which indicates that the parasitoid larva plays an important role in the manipulation of the host's JH titre. In the parasitoid larva, only JH III was found; titres were highest in the 2nd larval instar, a stage when the host is in the 5th instar and contains almost no JHs. Thus, JHs of the parasitoid and the host fluctuate in an independent manner.     

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.     

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.     

Social and nonsocial stimuli and juvenile hormone titer in a male burying beetle, Nicrophorus orbicollis

We investigated the interaction of social and nonsocial stimuli on juvenile hormone (JH) titer in male burying beetles (Nicrophorus orbicollis). The initial JH response to discovery of a carcass was substantial (10-15-fold increase over controls) and rapid (<1h), and occurred whether or not a female was present. By 3h after discovery, JH titers were declining, the decline being more pronounced when a female was not present. We also tested the effect of larval stimulation on JH titer in care-giving males by removing a male's brood and replacing it with a brood of first or third instar larvae. Males initially providing care for begging first instar larvae continued to maintain high titers of JH when the replacement broods were first but not third instars. Males caring for third instar larvae (normally low JH titers) maintained low levels of JH regardless of the developmental stage of the replacement brood. This suggests that once males begin to care for nutritionally independent third instar larvae, JH titers remain low regardless of subsequent larval stimulation. Burying beetles are socially and hormonally complex organisms in which stimuli from a breeding resource, mating partners, rivals and young interact to alter the JH profile of breeding adults.     

Influence of a juvenile hormone analogue on vitellogenin synthesis and oögenesis in larvae of Nauphoeta cinerea

In experiments on the synthesis of the vitellogenic protein, farnesylmethylester, a juvenile hormone (JH) analogue, was injected into female Nauphoeta cinerea larvae at various stages during their development. Two and 4 days after injection, 2 μl of haemolymph were assayed in a vitellogenin immunodiffusion test. In second last and last instar larvae less than 6 days before adult ecdysis, high doses (100 μg) of farnesylmethylester are necessary to induce vitellogenin synthesis, whereas older last stage larvae and decapitated adults respond to small doses (1 μg) with the synthesis of vitellogenin. It seems that the competence to synthesize the vitellogenic protein changes at the time of induction of the moulting process. If farnesylmethylester is injected into last instar larvae with a supposedly high titre of ecdysone, the vitellogenic protein can be detected in the haemolymph of a small percentage of animals only.Oöcyte maturation can be observed in last instar larvae injected after the fifth to ninth day with farnesylmethylester. The observed volume changes of the corpora allata suggest that an absence of JH for a short time is necessary for the oöcytes to become competent to grow. Last instar larvae treated with farnesylmethylester become larval-adult intermediates with partly developed oöcytes, demonstrating a simultaneous juvenilizing and gonadotropic influence of the JH analogue. In last instar larvae injected with farnesylmethylester a partial degeneration of already maturing oöcytes is induced at the time when the ecdysone titre is supposedly high and the possible reasons for this are discussed.     

Reduced titres of ecdysone following juvenile hormone treatment in the German cockroach, Blattella germanica

Changes in ecdysone titre of the larvae of the German cockroach, Blattella germanica, exposed continuously to the juvenile hormone (JH), or to the insect growth regulator (IGR) with JH activity, can be correlated with the nature of the substance applied, its dose, and the time of application. The younger larvae exposed to the high dose of the IGR die in the next ecdysis, whereas the same treatment induces a diapause-like stage of developmental arrest in the last larval stage. The affected larvae have very little or no ecdysone, the synthesis of which takes place in the second part of the instar. The same treatment after this period has a lesser effect. The extent of the effect is correlated to the amount of ecdysone synthesized before the application of IGR. Last instar larvae exposed to the lower dose of the IGR or JH lack the peak of ecdysone normally found in the controls at the end of the second third of the instar when metamorphosis takes place. In these insects the first rise of the ecdysone titre begins towards the end of the instar, and ecdysis into the supernumerary larval stage is initiated when the ecdysone titre reached a level permitting ecdysis.A direct or indirect antagonism between these hormones, both fundamental to insect development, can explain the morphogenetic, inhibitory, and lethal effects observed in insects treated with JH or IGR with JH activity.     

Choristoneura fumiferana entomopoxvirus prevents metamorphosis and modulates juvenile hormone and ecdysteroid titers

Larvae of the spruce budworm, Choristoneura fumiferana, infected with C. fumiferana entomopoxvirus (CfEPV) continue to feed and grow without undergoing metamorphosis and die as moribund larvae. The lethal dose (LD(50)) and lethal time (LT(50)) values for fourth instar larvae are 2.4 spheroids and 25.2 days, respectively. One hundred percent of the control fourth instar larvae, which were fed water instead of virus, pupated by 18 days post feeding (PF). Only 30% of the larvae that were fed the LD(50) dose and none of the larvae that were fed the LD(95) dose pupated by 18 days PF. Of the control larvae, 95% became adults by 24 days PF, whereas in the treated group only 2% of larvae that were fed the LD(50) dose and none of the larvae that were fed the LD(95) dose became adults by 24 days PF. Some of the virus-treated larvae died as either larval/pupal or pupal/adult intermediates. These phenotypic effects were similar to the larval/pupal and pupal/adult intermediates, resulting from treating larvae with juvenile hormone (JH) or its analogs, which suggests that EPV may cause such abnormalities by modulating JH and/or ecdysteroid titers. In untreated sixth instar larvae the JH titer decreased to low levels by 24 h after ecdysis and remained low throughout larval life. EPV-fed sixth instar larvae had 2112 pg/ml on day 0, 477 pg/ml on day 1 and 875 pg/ml on day 8 of the sixth instar. Control larvae contained 860 ng of ecdysteroids per ml hemolymph on day 8 of the sixth instar, whereas EPV-treated larvae of the same age (30 days PF) had only 107 ng of ecdysteroids per ml of hemolymph. Thus, EPV infection results in increased JH titer and decreased ecdysteroid titer. Northern hybridization analysis was performed using RNA isolated from control and EPV-fed larvae and cDNA probes for (i) juvenile hormone esterase (JHE), which is JH inducible, (ii) Choristoneura hormone receptor 3 (CHR3), which is ecdysteroid inducible, and (iii) larval specific diapause associated protein 1 (DAP1), whose expression is larval specific. EPV-treated larvae showed higher levels of JHE and DAP1 mRNA and lower levels of CHR3 mRNA, indicating that they had higher levels of JH and lower levels of ecdysteroids. Thus, our data show that EPV prevents metamorphosis by modulating ecdysteroid and JH levels.     

Caste Determination in Bombus terrestris: Differences in Development and Rates of JH Biosynthesis between Queen and Worker Larvae

To study the possible role of juvenile hormone in caste determination in Bombus terrestris, we measured development and rates of juvenile hormone biosynthesis in vitro in larvae destined to develop into either workers or queens. Larvae of both castes developed through four instars and had the same growth rates. However, the duration of the instars was longer for queen larvae, and their head width at the third and fourth instars was significantly larger. After validating the well-known radiochemical assay of JH for bumble bee larvae, we show that worker larvae corpora allata exhibited a constant and low rate of JH biosynthesis, never more than 5 pmol JH/h/pair. Queen larvae, in contrast, had two peaks of JH biosynthesis: a small one during the first instar, which has previously been correlated with caste determination; and a large peak, previously undetected, above 40 pmol JH/h/pair, during the second and third instars. We suggest that caste determination in this species is mediated by JH and that the duration of larval instars is a key factor. The possibility that the queen influences caste determination via an effect on instar duration is also discussed. Copyright 1997 Elsevier Science Ltd. All rights reserved     

Juvenile hormone synthesis, metabolism, and resulting haemolymph titre in Heliothis virescens larvae parasitized by Toxoneuron nigriceps

Last instar larvae of the tobacco budworm, Heliothis virescens F., fail to pupate and have little 20-hydroxyecdysone when parasitized by Toxoneuron nigriceps (Viereck). In this paper, we extend these observations to juvenile hormone (JH) to determine if parasitism by this wasp affects other endocrine systems. To this end, we compared the production of JH by corpora cardiaca-corpora allata complexes (CC-CA), the metabolism of JH by haemolymph enzymes, and the haemolymph titre of JH in parasitized and non-parasitized control larvae of H. virescens during the last larval instar. CC-CA from parasitized and control larvae had similar peaks of JH synthesis on day 1 of the fifth instar, with JH II accounting for more than 90% of total JH in both groups. On subsequent days, JH synthesis dropped to undetectable levels more quickly in non-parasitized controls than in parasitized larvae. JH metabolism by haemolymph of parasitized and control animals increased from low levels on day 1 of the fifth instar to high levels on days 2 and 3 of the instar. JH metabolism was significantly higher in control larvae than in parasitized larvae. After day 3, JH metabolism decreased in both groups, but was significantly higher in parasitized larvae. The major metabolite of JH in both groups was JH acid, though traces of JH diol and JH acid diol were also detected. The haemolymph titre of JH in both groups peaked on day 1 of the fifth instar and, similar to the synthesis of JH by CC-CA, decreased more rapidly in control larvae. As a result, non-parasitized animals had significantly lower JH titres on day 2. The higher JH titres observed in parasitized larvae during the early fifth instar may contribute to their developmental arrest. The possible role of these JH alterations in the host developmental and metabolic redirection is discussed and a more comprehensive physiological model accounting for host-parasitoid interactions is proposed.     

Fenoxycarb,a potent contaminant of the silkworm,Bombyx mori L., does not influence its juvenile hormone titer

Fenoxycarb (FC) effects were studied on juvenile hormone (JH) titers and JH‐esterase activities in the silkworm, B. Mori. In the literature, FC was observed to induce high JH titers but also to act without corpora allata (CA). These contradictory results did not permit us to conclude whether FC was a potent JH mimic or it was acting through the enhancement of JH titers in the hemolymph. Analysis of hemolymph JH‐esterase activities during the last larval instar reveals that FC was not a JH‐esterase inhibitor. Considering JHs, only JH II was detected in the European hybrid 200×300. Furthermore, JH titer was exactly identical in control and FC‐treated larvae, i.e., it dropped during the first 2 days of the last larval instar and became undetectable after day 2. This result is important since it contradicts the generally admitted concept that FC was acting by increasing the titer of JH. On the contrary, it was found that, despite its non‐terpenoid chemical structure, FC might be a JH mimic. In addition, FC suspected contamination of mulberry leaves was analyzed from a physiological viewpoint. We observed that "contaminated" mulberry leaves‐fed larvae became permanent larvae through the inhibition of their prothoracic glands (PG) activity and without any modification of their JH titers, i.e., exactly as for FC‐treated larvae. This last point adds information concerning the suspected implication of FC in the induction of the non‐spinning syndrome. Arch. Insect Biochem. Physiol. 40:141–149, 1999. © 1999 Wiley‐Liss, Inc.     

A possible therapy by juvenile hormone I to Spodoptera littoralis (Boisd.) larvae previously treated by precocene II

An effective constant dose (55 μg) of precocene II (PII) was topically tested against the last three instars of Spodoptera littoralis (Boisd.) larvae. Application of PII induced morphogenetic abnormalities typical of juvenile hormone (JH) excess. The resultant imperfect insects included larval‐pupal mosaic and partial or severe cases of untanned pupae. The sixth‐instar larvae were more sensitive to PII administration than the two preceding instars. However, sensitivity of the last larval instar to PII varied with the timing of dose application relative to the developmental status of the larvae. Whereas the newly ecdysed (0‐day old) larvae were more sensitive, the older larvae of the same sixth‐instar showed sharp decrease in their sensitivity to PII with a concomitant increase of their age. Application of a single dose (5 μg) of JH I to PII pre‐treated larvae significantly (P < 0.001) reduced the production of imperfect insects where many PH‐treated larvae developed successfully to apparent normal pupae. Although a single dose of PII was more effective on S. littoralis larvae than repeated daily doses, the effectiveness of JHI‐therapy to PH pre‐treated larvae by repeated doses was less effective in producing perfect insects than JH‐therapy to PII pre‐treated larvae by single doses. The reversal of any of these by applied JHI is quite interesting but the mechanisms remain to be unraveled.     

Effect of juvenile hormone on caste determination and colony processes in the bumblebee Bombus terrestris

To investigate the role of juvenile hormone (JH) in caste determination, first and second instar larvae of Bombus terrestris were topically treated with one of three doses (2, 10, or 20 g/larva) of JH dissolved in acetone. Treated larvae belonged to very young colonies that had just been started by their queen. Therefore, all larvae were supposedly destined to develop into workers. Our study demonstrates that a single application of JH in the first or second instar can lead to the development of queens and that this effect is dose- and instar-dependent. The brood (second, or third brood of the colony) to which the larvae belonged also had an effect. A clear size dimorphism of the female castes exists in B. terrestris. In this study, however, intermediates also developed from treated larvae. In fact, even untreated larvae in a treated colony developed into queens and intermediates, depending on the total dose of JH applied to the colony. There are no indications that a larva, once determined to become a queen, can be forced to become a worker by means of malnutrition. Treatment with JH also had an influence on colony processes. For instance, the appearance of queen larvae resulted in the advanced start of reproduction by workers and egg robbery, the so called competition point. This indicates again the close relationship between queen rearing and the queen-worker conflict. However, the ultimate function of this casual connection is still unclear. Further, the queen reacted to the treatment by switching to the laying of haploid eggs at an earlier date in the colony development compared to untreated colonies.     

In vitro bioassay for the brain allatotropic hormone of Galleria mellonella (Lepidoptera).

An in vitro sensitive bioassay for the Galleria mellonella brain allatotropic hormone (ATTH) was developed. This assay measures the rate of juvenile hormone (JH) synthesis in corpora cardiacacorpora allata complex (CC-CA) stimulated in vitro by ATTH released from the brain during short-term in vitro incubation, or by ATTH extracted from the tissue with methanol. CC-CA of the late VIth instar (VI3) larvae were used for assessment of ATTH. The maximum activation of test CC-CA by ATTH occurred at a concentration of 2 brain equivalents (per 100 ul medium). The highest ATTH activity was exhibited by the brains of chilled VII1 larvae: ATTH extracted from freshly dissected brains, or ATTH released from these brains during 6 h in vitro incubation, activated JH synthesis in the CC-CA nearly five or four times, respectively. The brain of VII1 hydroprenetreated larvae were ATTH inactive.