Identification of the juvenile hormone from the cricket, Teleogryllus commodus, and juvenile hormone titre changes

In the cricket, Teleogryllus commodus, eggs, haemolymph of 7th and 8th (last)-larval instars, and haemolymph of adults of both sexes contain only juvenile hormone III. While in the male the hormone titre is independent of previous mating experience, juvenile hormone concentration in haemolymph taken from females 36–38 hr after mating (an event which is followed by oviposition) is at a level 5 times higher than that of virgin females. Based on data gleaned from several research groups the identification of juvenile hormone III as the exclusive juvenile hormone in the Order Orthopteroidea is discussed.     

Precocene I and II inhibition of vitellogenic oöcyte development in Drosophila melanogaster

Adult female Drosophila melanogaster were exposed to precocene I and II, antiallatropin compounds which result in juvenile hormone deficiency in many insects. The presence of juvenile hormone in Drosophila adults was evaluated by examining vitellogenic oöcyte development, a process regulated by juvenile hormone in these flies. Both precocenes reduced the number of vitellogenic oöcytes present 43 hr after exposure in a dose-dependent manner. Precocene I was effective when applied to either newly eclosed females prior to vitellogenic oöcyte development or to gravid females. Precocene I was also effective in decapitated females, indicating that the action of the compound is not mediated by the brain. Corpus allatum volume, presumably a reflection of secretory activity, increased between 0 and 24 hr after eclosion in control females but not in precocene-treated females even after 48 hr. However, when females were removed from precocene medium, gland volumes increased within 48 hr to approximately those of control flies. This result is consistent with the reversibility of the precocene effect on Drosophila adults. These results suggest that precocene acts on the corpus allatum of Drosophila adult females to produce juvenile hormone deficiency.     

Biosynthesis and titre of juvenile hormone during the first gonotrophic cycle in isolated and crowded Locusta migratoria females

Basal oöcyte length, corpus allatum volume and “in vitro” juvenile hormone biosynthesis were measured in isolated and crowded Locusta migratoria females at selected times during the first gonotrophic cycle. Using gas chromatography-mass spectrometry with selected ion monitoring, the juvenile hormone titre in the haemolymph of isolated and crowded females was also determined 1 and 4 days after fledging. The rate of oöcyte growth was more rapid in isolated females and a significant (P < 0.01) difference in mean length was apparent as early as 3 days after fledging. This early manifestation of a difference in rate of oöcyte growth was correlated with a difference in haemolymph juvenile hormone titre between isolated and crowded females. Whilst there was no difference in titre 1 day after fledging, by day 4 the juvenile hormone titre in isolated females was found to be approximately twice that in crowded females. There was no significant difference in the rates of juvenile hormone biosynthesis by corpora allata from isolated and crowded females on days 0 through to 6 after fledging. On day 8, however, the rates of juvenile hormone biosynthesis of corpora allata from isolated females were very high (mean value = 136 pmol/h/pair) and were significantly (P < 0.002) greater than those of corpora allata from crowded females. Day 8 was also the point in the first gonotrophic cycle at which the difference in the mean basal oöcyte length in isolated and crowded females was at a maximum. The mean volume of corpora allata from isolated females was greater than that of corpora allata from crowded females at all points at which measurements were taken during the first gonotrophic cycle.     

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.     

Biogenic amines regulate the reproductive function in <Emphasis Type="Italic">Drosophila</Emphasis> as neurohormones

We studied the influence of experimental increase in the octopamine and dopamine content on the level of juvenile hormone degradation, oogenesis, and fertility in wild type Drosophila virilis flies. Feeding of flies on octopamine led to a significantly decreased level of juvenile hormone degradation (increased titer) in young and sexually mature females, rather than in males, markedly decreased the number of vitellogenic (stages 8–10) and mature (stage 14) oocytes), and sharply reduced fertility. Feeding of flies on dopamine decreased the juvenile hormone degradation (increased titer) in young wild type females and increased it (lowered the juvenile hormone titer) in sexually mature females, as well as decreased the fertility of wild type females to a level characteristic for D. virilis line with a mutation doubling the endogenous dopamine level. A possible mechanism of the influence of these amines on the reproductive function in Drosophila as neurohormones is discussed and a conclusion is drawn that the reduced fertility of females at an increased level of amines appears to be related to an increased level of ecdysteroids, which is caused by an increased, as a result of decreased degradation, juvenile hormone titer.     

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 role of endocrines in flight-muscle degeneration in Dysdercus cingulatus (Heteroptera: Pyrrhocoridae)

In Dysdercus cingulatus, extirpation of the median neurosecretory cells inhibits flight-muscle breakdown. However, implantation of median neurosecretory cells or corpus allatum into females lacking these neurosecretory cells induces muscle histolysis. Median neurosecretory cells stimulate the corpus allatum to produce juvenile hormone which in turn induces muscle degeneration. Topical application of kinoprene induces muscle breakdown, even in males and starved virgin females. The direct participation of juvenile hormone in muscle degeneration is further confirmed by observations on the effect of precocene II which inhibits muscle histolysis in many individuals. The endocrine basis of vitellogenesis and flight-muscle degeneration could be identical; vitellogenesis however appears to require a higher threshold concentration of juvenile hormone.     

Endocrine influence upon the development of vitellogenic competency in Oncopeltus fasciatus

Immunoelectrophoretic analysis of the blood of precocious adult females of Oncopeltus demonstrated the presence of the A form of vitellogenin but no detectable AB form, the form present in mature adult-female haemolymph. Although the appearance of the AB form could be induced by topical treatment of precocious adult females with juvenile hormone, no yolk deposition was induced in these females. Histological examination revealed that the ovaries of precocious adult females reached only a previtellogenic stage of development with or without treatment with juvenile hormone. Topical treatment of normal larvae and adults with the hormone demonstrated that vitellogenin synthesis could not be induced with juvenile hormone treatment alone until after adult emergence. Since the precocious adult females are chronologically younger than normal last-stage larval instars, we suggest that a transition period during which juvenile hormone is absent (i.e. the precocious moult in treated animals; the final moult in control animals) must occur before some tissue of the precocious or normal adult females, presumably the fat body, becomes competent to respond to further exposure to the hormone by making the AB form of vitellogenin. The ovary requires a similar transition period prior to becoming capable of depositing vitellogenin; however, the times when the fat body and the ovary become competent to respond to the transition period differ.     

The Effects of Stress-Related Hormones on the Stress Resistance in <Emphasis Type="Italic">Drosophila melanogaster</Emphasis> Carrying Mutation in the <Emphasis Type="Italic">Dilp6</Emphasis> Gene

The heat stress resistance of Drosophila melanogaster females carrying a hypomorphic mutation of the DILP6 insulin-like protein gene (dilp6 ⁴¹ ) under a change in the level of stress-related hormones (juvenile hormone and octopamine) is studied. It is revealed that the dilp6 ⁴¹ mutation decreases the heat stress resistance of mature D. melanogaster females. An experimental decrease in the level of juvenile hormone is shown to restore the stress resistance of mutant females to the level of stress resistance observed in wild type Canton S females. These data suggest that the effects of the dilp6 ⁴¹ mutation on the stress resistance of females are mediated by an increased level of juvenile hormone. An experimental increase in the octopamine level that causes an increase in juvenile hormone level supports this hypothesis: the resistance to heat stress decreases in females of both lines and this decrease is more significant in mutant females than in the control line. Thus, it is established for the first time that the effect of the hypomorphic dilp6 gene mutation on the heat stress resistance of D. melanogaster females is mediated by juvenile hormone.     

Effects of decapitation and ovariectomy on the regulation of juvenile hormone synthesis in the cockroach, Diploptera punctata

Corpora allata from Diploptera punctata females at adult ecdysis or at the end of the last-larval stadium, when implanted into decapitated females, underwent a cycle of juvenile hormone synthesis similar in timing and magnitude to that of glands implanted into control animals which had been starved and allatectomized. Starvation did not alter the cycle in rates of juvenile hormone synthesis of sham-operated animals.Decapitation of ovariectomized animals resulted in no cycle in rates of juvenile hormone synthesis by implanted adult corpora allata; however, implantation of an ovary along with the corpora allata into decapitated, ovariectomized hosts resulted in a cycle of juvenile hormone synthesis. In control animals, which retained their heads but were starved and allatectomized as well as ovariectomized, the implanted corpora allata showed a cycle of juvenile hormone synthesis only when implanted with an ovary. The maximal rates of juvenile hormone synthesis by the corpora allata in both experimental and control conditions were lower than normal, likely due to the repeated trauma of surgery. However, at no time from eclosion to the end of the first gonotrophic period was the brain necessary for the cyclic response of the corpora allata to the presence of the ovary.     

InR gene expression and octopamine metabolism in Drosophila melanogaster females

The influence of suppression of the expression of the Drosophila insulin-like receptor gene (InR) in corpus allatum (the gland-synthesizing juvenile hormone) on octopamine (OA) and juvenile hormone metabolism and on the development of the stress-reaction in Drosophila melanogaster females was studied. It was demonstrated that the suppression of InR gene expression in corpus allatum induces in D. melanogaster females an increase in the activity of the enzyme that limits the rate of octopamine synthesis (tyrosine decarboxylase), as well as in the level of juvenile hormone degradation and the intensity of the response of octopamine and juvenile hormone metabolism systems to heat stress. It was mentioned that a decrease in InR gene expression in corpus allatum does not influence the activity of OA-dependent N-acetyltransferase (the enzyme that degrades octopamine). It was established that the influence of suppression of the InR gene expression in corpus allatum on octopamine metabolism is mediated by juvenile hormone, since the treatment of flies by exogenous juvenile hormone restores the activity of tyrosine decarboxylase in flies with decreased InR expression in corpus allatum up to the normal level.     

The effects of mating,exogenous juvenile hormone and a juvenile hormone analogue on pheromone titre,calling and oviposition in the omnivorous leafroller moth (Platynota stultana)

Mating in Platynota stultana resulted in the termination of calling, the gradual reduction of pheromone in the pheromone glands to non-detectable levels (<0.1 ng/♀) within 14 h, and oviposition of the first batch of eggs 20–24 h after copulation. Decapitation of virgin females resulted in a similar decline in pheromone titre, and also eliminated oviposition and calling. Pheromone production appears to be controlled via the head. Mating probably terminates neural or hormonal input required for pheromone production and/or removes neural or hormonal inhibition of pheromone degradation. A juvenile hormone analogue (ZR-512) and juvenile hormones I, II and III applied exogenously to virgin females elicited oviposition comparable to mated females and terminated calling within 48 h. The juvenile hormone analogue also appeared to block pheromone production in virgin females. These results suggest that juvenile hormone may be involved in the switch from virgin to mated behaviour in this species.     

Mating behaviour of Plodia interpunctella reared on juvenile hormone-treated diet

Treatment of larval Plodia interpunctella with sublethal doses of juvenile hormone repressed mating of the adults. This repression did not result from a reduced content of sex pheromone of females, but it may have been caused in part by reduced calling behaviour and abnormal antennae. An absence of juvenile hormone at the end of larval life is necessary for the development of normal reproductive behaviour of the adult.     

Biosynthesis and release of juvenile hormone during the reproductive cycle of the ring-legged earwig

Corpora allata of adult female Euborellia annulipes, incubated in medium containing ³H-methionine, synthesized and released juvenile hormone III. Labelled material co-migrating with methyl farnesoate was also found, suggesting this as an intermediate in the pathway of juvenile hormone III production. Juvenile hormone was not appreciably stored in the glands, but was released into the medium. In normal medium, 93.6 ± 1.6% of the total juvenile hormone III synthesized was released and 96.5% ± 0.3 in medium supplemented with 60 μM farnesoic acid. The rate of juvenile hormone III biosynthesis/release in vitro remained constant for at least 8 hr for glands of different activities. The rate of juvenile hormone production was closely correlated with the gonadotrophic cycle. In females with previtellogenic ovarian follicles (0.26 ± 0.004 mm), hormone production was only 0.59 ± 0.13 fmol hr⁻/corpus allatum; production increased to 1.52 ± 0.25 fmol hr⁻¹/corpus allatum when basal follicles were growing rapidly, and remained high during the period of oviposition. By 3 days following oviposition when females were brooding clutches, hormone production had declined to 0.46 ± 0.13 fmol hr⁻¹/corpus allatum. The addition of 60 μM farnesoic acid to the medium enhanced juvenile hormone biosynthesis at each stage examined. Lastly, elevating the level of l-methionine in the medium also enhanced hormone biosynthesis. Maximal hormone production was 32.8 ± 10.9 fmol hr⁻¹/corpus allatum, at an l-methionine concentration of 51 μM.     

Antigenic and electrophoretic variants of vitellogenin in Oncopeltus blood and their control by juvenile hormone

Antigenic analysis of adult female-specific blood and yolk proteins in Oncopeltus demonstrated an incomplete vitellogenin (A), which appears in the blood prior to yolk deposition and is later modified or joined by an antigenically complete molecule (AB). Vitellogenin AB is antigenically indistinguishable from the major yolk protein of mature eggs, though the electrophoretic mobilities of the two differ in 6% acrylamide gels. Vitellogenin A alone appears in the blood of adult females in which the corpora allata are known to be inactive, i.e., during starvation or photoperiodically induced diapause. Stimulation of these females with a juvenile hormone analog restores yolk deposition, and also induces the appearance of AB in the blood. While juvenile hormone is needed for the termination of diapause and the maturation of vitellogenin in this species, diapause begins with the vitellogenin-producing mechanism already partially assembled.     

Regulation of juvenile hormone synthesis during pregnancy in the cockroach, Diploptera punctata

Regulation of juvenile hormone synthesis during pregnancy was investigated after determining the normal rates of synthesis in pregnancy and the second gonadotrophic cycle in Diploptera punctata by direct in vitro radiochemical assay.The low rate of juvenile hormone synthesis during early pregnancy is maintained by three factors: (1) the small ovary which is incapable of eliciting increased rates of juvenile hormone synthesis (2) an inhibitory centre in the brain acting via intact nerves to the corpora allata (similar to that in virgin females) and (3) an inhibitory centre in the brain acting via the haemolymph (elicited by embryos in the brood sac).The existence of two inhibitory centres in the brain is supported by the additive effect of denervating the corpora allata and removing embryos. Whereas these operations alone activated the corpora allata in 54 and 31% of the females, respectively, together they activated 87%, similar to the 91% activated by denervation alone in late pregnancy.The inhibition which remains after denervation of the corpora allata can be removed by decapitation and restored by implantation of the protocerebrum from a pregnant female but not from one developing oöcytes.The inhibition elicited by embryos in the brood sac can be overcome by introduction of a stimulatory ovary and/or substitution of active corpora allata.     

The mode of regulation of the corpus allatum activity during starvation in adult females of the Colorado potato beetle, Leptinotarsa decemlineata (Say)

When two-day-old female Leptinotarsa decemlineata were starved, their corpus allatum activity, as measured by the radiochemical in vitro assay, was significantly reduced after 24 hr. Such a reduction was not observed when the nerve connections between the central nervous system and the retrocerebral complex were severed and the beetles starved up to 5 days. In some experiments, the rate of juvenile hormone biosynthesis in vitro, was substantiated by measurement of the juvenile hormone titre in the haemolymph by physico-chemical methods. It is concluded that intact nervous connections between the central nervous system and the corpora allata are essential for restraining the juvenile hormone biosynthesis during the initial stages of starvation.Corpora allata from 1-day starved insects were considerably stimulated in vitro by farnesenic acid indicating that juvenile hormone synthesis is controlled enzymatically at a stage prior to the final two steps in the pathway. However, on day 5 of starvation, rate-limitation may occur after formation of this intermediate, since farnesenic acid stimulation was much less at this time.Corpora allata of adult females newly emerged from the soil were activated within 4 hr regardless of feeding.     

Follicle cell polyploidy in Leucophaea maderae: Regulation by juvenile hormone

Microspectrophotometric analysis of Feulgen-stained nuclei of the terminal follicle cells in the cockroach Leucophaea maderae showed that during maturation the follicle cells became polyploid. In virgin females, the follicle cell nuclei were diploid. After mating, and during vitellogenesis, the ploidy of the follicle cells increased from 2 C to 32 C with a small percentage of 64 C nuclei. There was no further increase in the ploidy levels during the chorionic stage of development.Injections of juvenile hormone III into decapitated virgin females elevated the ploidy levels in the follicle cells. The DNA content of these nuclei at 96–120 h after injection of juvenile hormone III increased from 2 C to 4 C. Such polyploidization of nuclei was dose-dependent with the highest DNA content occurring in response to 25–50 μg juvenile hormone III. The juvenile hormone-induced increase in DNA content correlated with an increase in the rate of [³H]thymidine incorporation into DNA.Our data suggest that the role of juvenile hormone in follicle cell development during the vitellogenic period, whether direct or indirect, is to promote selectively a large increase in the DNA content of the cells. This may facilitate the next stage of follicle cell development, choriogenesis.     

Precocene causes male determination in the aphid Myzus persicae

When adult apterous viviparous females of Myzus persicae, reared in short night conditions at 21–23°C, are treated with the precocene analogue 6-methoxy-7-ethoxy-2,2-dimethylchromene, they deposit males towards the end of their reproductive lives. The first-born normal daughters of the treated females also deposit some males at various times in their reproductive lives. Karyotypic analysis was used to investigate the sequence of male and female embryos in the ovarioles of precociously metamorphosed aphids. The experiments support the hypothesis (Mittler et al., 1979) that juvenile hormone level controls the sex determination process in aphids. Since male aphids have an XO sex chromosome constitution, this implies that juvenile hormone level influences the behaviour of the X-chromosomes at or before the single maturation division of the egg. At this division one X-chromosome is eliminated from eggs which will develop as males. Aphids provide the first example of a specific endocrine influence on chromosome behaviour in sex determination.     

Effects of food and water availability,and of NCA-1 section,upon juvenile hormone biosynthesis and oöcyte development in adult female Periplaneta americana

The combined stimuli from feeding, drinking, mating and crowding are required for the highest rates of oöcyte development in maturing adult female Periplaneta americana. A graded series of “sexually suppressed” females can be produced by withholding one or more of these stimuli, and this stepwise retardation of ovarian development appears to be achieved by a progressive increase in corpus allatum restrain. It seems that all of these environmental cues are centrally integrated such that juvenile hormone-dependent processes can proceed at an appropriate pace. Water availability is evidently the most important factor. Water-deprived females are sexually unreceptive, and are found to have very low rates of juvenile hormone biosynthesis and ovarian development. This holds true even when they are provided with food. In contrast, 75% of starved females are sexually receptive if allowed free access to drinking water. At the same time they have enhanced corpus allatum activity, and show significant oöcyte growth.The mode of regulation of corpus allatum function in adult female P. americana appears to be significantly different to the model proposed for the cockroaches Leucophaea maderae and Diploptera punctata. Allatotropic signals may be more important than inhibitory signals in the former species. The glands continue to be moderately active in fed, mated female P. americana after NCA-1 section (although a major peak of corpus allatum activity is not obvious), and the rate of oöcyte development is not greatly reduced. However, NCA-1 mediated inhibition of juvenile hormone biosynthesis is less readily demonstrated. We could observe no enhancement of corpus allatum activity nor stimulation of oöcyte growth after unilateral NCA-1 section when the operation was performed on starved virgins, and the same result was found after bilateral NCA-1 section when starvation or virginity were separately enforced. A slight stimulation of juvenile hormone biosynthesis, together with a small increase in oöcyte development, could only be demonstrated after both NCA-1 were cut in starved virgins.We conclude that neurally mediated corpus allatum inhibition in has yet to be adequately verified, and that the available evidence does not contradict the theory that juvenile hormone biosynthesis in adult females could be regulated predominantly by chemicals released into the haemolymph.