Hormone-pheromone relationships of male Tenebrio molitor

Males of the beetle Tenebrio molitor produce a volatile sex pheromone which attracts females of the same species. The pheromone level peaks 8 days after emergence and then reaches a plateau. Elimination of endocrine centers by decapitating male adults 24 hr following adult ecdysis did not impair pheromone production. Treatment of decapitated males with juvenile hormone analogues did not make any detectable difference in the levels of pheromone activity. However, undecapitated males treated with juvenile hormone analogue showed a significant increase in pheromone activity when compared with those that had been decapitated and subsequently treated with juvenile hormone analogue. This observation is discussed in the light of published research on the effect of juvenile hormone on pheromone activity of females of T. molitor.     

Larval esterases of the southwestern corn borer, Diatraea grandiosella: Temporal changes and specificity

Disc electrophoresis was used to examine and characterize the esterases present in the fat body, haemolymph, and midgut of last stage larvae of the southwestern corn borer, Diatraea grandiosella. Significant temporal changes were observed in the pattern of the 4 major esterases of the fat body and 3 major esterases of the haemolymph. These changing profiles presumably relate, in part, to a requirement for the degradation of juvenile hormone (JH) in preparation for metamorphosis.The binding capacity of esterases present in the larval midgut towards JH I and three JH mimics (alkyl-3,7,11-trimethyl-2,4-dodecadienoates) was also examined. The midgut of last stage nondiapausing larvae was shown to contain a carboxylesterase which bound all three JH mimics. Another esterase which bound JH I, but not the mimics, was also present. An esterase with a similar electrophoretic mobility was detected in the haemolymph and integument. Since the JH I binding esterase did not bind the JH mimics, the mimics do not appear to synergize JH by inhibiting its ester hydrolysis.     

Critical Sensitivity of the Ovary of <Emphasis Type="Italic">Aedes aegypti</Emphasis> Adults to Sterilization by Juvenile Hormone Mimics

STERILIZATION of adult insects with juvenile hormone mimics has been reported several times^1–5, but only once for adult mosquitoes and no details were given². I report here on the sterilizing effect of three juvenile hormone mimics on female Aedes aegypti. They were (i) mixed geometric isomers of methyl 10,11-epoxy-3,7,11-trimethyl-2,6-tridecadienoate (CJH2), one of two substances with high juvenile hormone activity isolated from Cecropia oil⁶; (ii) mixed geometric isomers of farnesyl methyl ether (FME) and (iii) 2 cis/trans, 6 trans farnesenic acid ethyl ester (FAE). All three compounds were first tested on fifth instar Rhodnius prolixus using Wiggles-worth's method⁷. The doses to give a score of ten were as follows: CJH2 1.3µg; FME 1.4 µg; FAE 31.7 µg.     

Definition of a juvenile hormone-sensitive period in Rhodnius prolixus

This paper is an attempt to establish the times of onset and termination of the juvenile hormone-sensitive period for metamorphosis in fifth-instar larvae of Rhodnius. Small regions of the abdominal integument were exposed to discrete pulses of the juvenile hormone analogue ZR-515 (methoprene) by applying small drops of a mixture in paraffin to the dorsum at various times after a bloodmeal and removing these drops after different time intervals. The diffusion coefficient of the analogue in the integument was estimated and used together with estimates of its metabolism to determine the lag times between application of the analogue and its rise to above threshold concentration in the epidermis, and between removal of the analogue source and its fall to below threshold concentration in the epidermis. These lag times were estimated to be 1.5 and 24h, respectively. Knowledge of the lag times makes it possible to establish the limits of the juvenile hormone-sensitive period or metamorphosis from the responses of larvae to variously-timed pulses of the analogue. The juvenile hormone-sensitive period has the following properties. For the population as a whole it lasts from about day 3 to about day 9 after a bloodmeal. Any individual in that population, however, only requires the presence of juvenile hormone during a 2 to 4-day period. The exact duration of an individual's sensitive period within these limits is a stochastic event. Surprisingly, for any individual, a pulse of juvenile hormone is equally effective when experienced early as when experienced late during its juvenile hormone-sensitive period.     

Can larval epidermis omit the secretion of a pupal cuticle in a saturniid moth, Samia cynthia ricini?

When the larval tissue is exposed to the hormonal milieu lacking juvenile hormone, adult characters appear directly omitting the pupal stage in some insects but not in others. In Samia cynthia ricini, a species belonging to the latter group, a possible omission of pupal characters was tested by previously untried experiments. Firstly, the possibility that the larval epidermis of only some stages is capable of responding so as to omit to secrete the pupal cuticle was tested. Pieces of larval integument taken from various developmental stages were implanted into developing (pharate) adults. None of these failed to secrete the pupal cuticle. Secondly, pieces of larval integument were first implanted into brainless pupae and left there for a month to eliminate the effect of a trace of juvenile hormone which might have been carried over by the implants. They were then caused to develop, and they again secreted pupal cuticle. It is concluded that the larval epidermis cannot omit secreting pupal cuticle in this species.     

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

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

Morphogenetic effects of juvenile hormone and juvenile hormone mimics on adult development of Drosophila

The morphogenetic effects of t,t-farnesol, Law-Williams juvenile hormone analogue, dichlorofarnesenic acid ethyl ester (DFAEE), and a syntetic racemic or isomeric mixture of C₁₈ juvenile hormone (JH), when applied topically to pharate pupae and adults of D. melanogaster have been studied. Of these various agents tested, only DFAEE and JH affected adult development and eclosion and the pharate pupae were the most sensitive to these agents. The racemic mixture of JH induced the secretion, in the abdomen, of a supernumerary cuticle indistinguishable from that of the pupa; it, in addition, retarded the synthesis of brown eye pigments, general body pigmentation, and affected the differentiation of various internal organs and cuticular structures of the abdomen. By comparing the effects of JH with those of Minute (M) and bobbed (bb) mutations on the adult development, it is suggested that JH, by retarding genetic translation mimics M or bb.     

Synthesis of Compounds with Juvenile Hormone Activity

A new and convenient non-stereoselective synthetic route to the C₁₈-Cecropia juvenile hormone (as a stereoisomeric mixture) was developed. Employing this method, several juvenile hormone analogues with various alkyl groups at the terminal position were synthesized as stereoisomeric mixtures. Two analogues with two ethyl groups or n-propyl and methyl groups at the terminal position were more active than the C₁₈-Cecropia juvenile hormone on Tenebrio molitor and Tribolium castaneum.     

The effects of juvenile hormone, 20-hydroxyecdysone and precocene II on activity of corpora allata and the mode of negative-feedback regulation of these glands in the adult Colorado potato beetle

When the titre of juvenile hormone III in female Leptinotarsa decemlineata was elevated by the implantation of supernumerary corpora allata or by the injection of the hormone, the rate of endogenous hormone production by the host glands was significantly restrained, as determined by the short-term in vitro radiochemical assay. From denervation studies, it is suggested that during phases of elevated juvenile hormone titre, the corpus allatum activity is regulated via humoral as well as neural factors requiring intact nerve connections. Restrainment of gland activity appears to be mainly via the neural pathway. Isolated corpora allata were not influenced by 10^?5 M juvenile hormone III added to the incubation medium in vitro.Studies with farnesenic acid revealed that the final two enzymatic steps in the biosynthetic pathway of juvenile hormone are also diminished during prolonged neural inhibition of the corpora allata.20-Hydroxyecdysone and precocene II had no apparent effect on the corpus allatum activity of Leptinotarsa decemlineata.     

A comparison of the morphogenetic and sterilizing activities of juvenile hormone mimics on Aedes aegypti

At 25°C, adult female aedes aegypti are most sensitive to sterilization by juvenile hormone (JH) mimics when such chemicals are applied 32 to 36 hr after the blood meal (when the ovaries are at late stage III to early stage IV). Application of JH mimics during this period reduces egg fertility and female fecundity and induces the production of large numbers of visually abnormal eggs. As the most sensitive phase for sterilization with JH mimics is well before oviposition, and as many abnormal eggs are laid following JH mimic treatment, it is likely that in this species sterilization effects are induced by some action on the developing oöcyte rather than on embryonic development.The relative activities of several JH mimics in sterilizing adult female A. aegypti are very similar to their relative activities in inhibiting metamorphosis. Thus the sterilizing action of JH mimics is likely to be a true JH effect and can be used as a test for JH activity for A. aegypti.     

Inhibition of oötheca production in Periplaneta americana (L.) with the anti juvenile hormone fluoromevalonate

Topical treatment of adult female Periplaneta americana with the anti juvenile hormone fluoromevalonate delays the formation of the first post-treatment oötheca. This effect is dose-related and can be counteracted by simultaneous application of a juvenile hormone analogue (hydroprene) or by a 5-fold excess of mevalonic acid. Although treatment with fluoromevalonate delayed the production of oöthecae, such treatment did not affect either the carrying period of oötheca or their weight or viability. The technique described permits rapid in vivo evaluation of candidate anti juvenile hormones as anti-gonadotropic agents and provides further opportunity for studying the role of the endocrine system in regulating reproduction in P. americana.     

The activity of juvenile hormone mimics for the eggs of Rhodnius prolixus

Twenty four juvenile hormone (JH) mimics of several different chemical classes were applied to freshly laid eggs of Rhodnius prolixus. Activity of the JH mimics was assessed in terms of their ability to inhibit eclosion. All chemical classes tested except one of the natural JHs and two very closely related long chain compounds contained members which inhibited eclosion; the most active chemicals were derivatives of geranyl para-aminobenzoic acid esters and aryl methylene dioxyphenyl ethers. In general, those chemicals of a particular class which had highest morphogenetic activity when applied to last instar larvae, were also most active in inhibiting eclosion. However, not all structure/activity relationships of JH mimics for last instar larvae were applicable to eggs; in particular the presence of a terminal epoxide group increased activity greatly for eggs but only slightly for last instar larvae. The dose per unit weight to inhibit eclosion is far greater than the equivalent dose to disrupt normal metamorphosis.     

Synthesis and Biological Activity of Some Juvenile Hormone Analogs Lacking the Alkyl Substituents at C-7 or Both at C-3 and at C-7

Two groups of juvenile hormone analogs were synthesized. One lacks the alkyl substituent at C?7. The other possesses the alkyl substituents neither at C?3 nor at C?7. These analogs were almost inactive on Bombyx mori L. Some of them with the alkyl substituent at C?3, however, were active on Tenebrio molitor L. This indicates the very narrow sensitivity of Bombyx mori L. to juvenile hormone analogs.     

Juvenile hormone and juvenile hormone esterase in adult females of the mosquito Aedes aegypti

Juvenile hormone III levels and juvenile hormone esterase activity were measured in whole body extracts and haemolymph, respectively, of female Aedes aegypti. The amount of juvenile hormone, determined by coupled gas chromatography-mass spectrometry, rose over the first 2 days after emergence from 0.7 to 7.5 ng/g, and then slowly fell over the next 5 days in females not given a blood meal. In females fed blood, juvenile hormone levels fell during the first 3 h to 2.3 ng/g. The rate of decline then slowed so that levels had reached their lowest point (0.4 ng/g) by 24 h after the blood meal. By 48 h, levels started to rise again until 96 h when they were equivalent to pre-blood meal levels.Juvenile hormone esterase activity in the haemolymph of females was measured with a partition assay. The esterase activity showed small fluctuations in unfed animals. In females fed blood on the 3rd day after emergence, the juvenile hormone esterase activity rose slowly to a peak at 36 h. At 42 h it began to decline, and by 66 h it had returned to pre-blood meal levels. Thus, juvenile hormone levels and juvenile hormone esterase activity were inversely correlated after a blood meal. Both the ovary and fat body produce juvenile hormone esterase in organ culture.Juvenile hormone III acid was the only metabolite produced after incubation of haemolymph with racemic-labelled juvenile hormone III. Juvenile hormone acid, diol, and acid diol were the main metabolic products seen in whole animal extracts after topical application of labelled hormone. About 25% of topically applied, labelled juvenile hormone appears in the haemolymph as the acid diol, and 50% of this is excreted in the urine immediately after the blood meal. Topical application of BEPAT (S-benzyl-O-ethyl phosphoramidothiolate), a specific inhibitor of juvenile hormone esterase, resulted in the absence of juvenile hormone acid and a reduction in the acid diol. Both BEPAT and methoprene, a juvenile hormone analogue, caused a reduction in egg hatch when applied topically 30 h after a blood meal, demonstrating that the decline in juvenile hormone levels after a blood meal is necessary for normal egg development and suggesting that the decline is mediated, at least in part, by juvenile hormone esterase.     

The onset of metamorphosis in Tenebrio molitor L.: Effects of a juvenile hormone analogue and of 20-hydroxyecdysone

Sensitivity to juvenile hormone and to 20-hydroxyecdysone has been investigated during the last-larval stages of Tenebrio molitor. Topical applications of a juvenile hormone analogue (K-421d) showed that the sensitive period, occurring before apolysis, is relatively short (less than 4 days in a 3-week instar) and divided into two phases. Treatment during the first and longest phase induced a delay in development and then an increase in larval moult percentage. Treatment during the second phase induced several abnormal moults (prothetelic larvae and larval-pupal intermediates).Injections of massive doses of 20-hydroxyecdysone (10 μg per animal) also evidenced a period of disturbance of the morphogenetic programme, beginning before pupal apolysis but continuing several days after.Comparison of the sensitive periods to both hormones suggests that a very important and rapid step of the larval-pupal programme change is controlled hormonally just before pupal apolysis.     

Haemolymph juvenile hormone III esterase activity during adult life of female and male crickets,Gryllus bimaculatus de Geer (Ensifera,Gryllidae)

Using an in vitro method, juvenile hormone III degradation was studied in the plasma of adult female and male crickets, Gryllus bimaculatus. The primary route of juvenile hormone III metabolism in cricket haemolymph is ester hydrolysis to juvenile hormone III acid by juvenile hormone III esterase. Juvenile hormone III esterase activity in females' haemolymph is low just after imaginal moulting. A sharp peak of enzyme activity is observed on day 3 after emergence, and two subsequent peak values occur in older animals. Plasma juvenile hormone III esterase activity in freshly ecdysed males is also low, but increases rapidly thereafter. Another increase in enzyme activity is observed in older males. The fluctuations in juvenile hormone III esterase activity are discussed in correlation with changes in haemolymph volume, haemolymph protein content, haemolymph juvenile hormone III titer, and the rates of juvenile hormone III biosynthesis in vitro of the corpora allata.     

The effect of juvenile hormone on prothoracic gland function during the larval-pupal development of Manduca sexta: An in situ and in vitro analysis

The application of juvenile hormone I or ZR 512 to neck-ligated, day-5 fifth instar (V₅) larvae reduced the time to pupation in a dose-dependent manner when compared to neck-ligated controls treated with methyl epoxy stearate. Haemolymph ecdysteroid titres determined by radioimmunoassay (RIA) reflected the ability of juvenile hormone I and ZR 512 to stimulate larval-pupal development, i.e. the ecdysteroid titres were similar to those of normally developing larvae although the ecdysteroid peak elicited by ZR 512 lagged that in the normal titre by 1 day, while that elicited by juvenile hormone I lagged the ecdysteroid peak in normal larvae by 2 days. Neck-ligated V₅ larvae that were untreated ultimately pupated and the haemolymph ecdysteroid peak eliciting pupation in these animals was 7 μg/ml haemolymph, almost double that of normal animals and ZR 512- and juvenile hormone I-treated, ligated larvae. The data indicated that juvenile hormone I does stimulate the prothoracic glands but to determine whether this stimulation was direct or indirect, an in vitro approach was taken. Prothoracic glands from V₅, V₆ and V₇ larvae were incubated in vitro under conditions in which they could be stimulated by prothoracicotropic hormone, and were exposed to concentration of free juvenile hormones I, II, III or ZR 512 ranging from 10^?5M to 10^?10M. In no case were the prothoracic glands stimulated in a dose-dependent manner that would be indicative of hormone activation. Similar results were obtained when juvenile hormone bound to binding protein was incubated with the prothoracic glands. Studies with the acids of the three juvenile hormone homologues revealed them to be ineffective in activating prothoracic glands, although juvenile hormone III acid does appear to inhibit the synthesis of ecdysone by day-0 pupal prothoracic glands. The significance of the latter effect is unknown. It is concluded from these data that juvenile hormone can, indeed, activate late larval prothoracic glands in situ, but does so indirectly.     

S-Adenosylmethionine:Juvenile hormone acid methyltransferase in male accessory reproductive glands of Hyalophora cecropia (L.)

The accessory reproductive glands of the adult male Hyalophora cecropia contain S-adenosylmethionine:juvenile hormone acid methyltransferase. The enzyme is soluble and can be found in the gland epithelium as well as in the glandular secretion, but not in any other part of the genital tract of the unmated male. The appearance of this enzyme activity in the pharate adult precedes the formation of a measurable pool of its substrate, juvenile hormone acid, and the onset of the juvenile hormone accumulation in the accessory reproductive glands. The accessory reproductive glands of Antherea pernyi and Manduca sexta, species which do not accumulate juvenile hormone, lack methyltransferase activity. It is concluded that the methyltransferase is an essential component of the juvenile hormone accumulation mechanism in H. cecropia.     

Activity of the corpora allata in the adult female migratory locust

Juvenile hormone was detected in the haemolymph of adult female Locusta by a modified Galleria bioassay. The hormone was present in the haemolymph immediately after the final ecdysis, but could not be detected after this time until the end of the period of somatic growth just before the start of ovarian development. During the first gonotrophic cycle the levels of juvenile hormone in the haemolymph could be related to the growth of the proximal oöcytes. The volumes of the corpora allata could be related to haemolymph juvenile hormone levels during the first gonotrophic cycle. Ovariectomy had no effect on haemolymph juvenile hormone levels or on the volumes of the corpora allata.