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.     

Ultrastructural localization of juvenile hormone biosynthesis by insect corpora allata

Summary The conversion of exogenous ³H-farnesenic acid to ³H-methyl farnesoate and ³H-C₁₆ juvenile hormone (JH) has been followed in the corpus allatum (CA) cells of the desert locust Schistocerca gregaria by means of electron microscopic autoradiography. Aerobic and anaerobic chase incubations have been used to modify the quantities of these three compounds within the CA cells. Under all incubation conditions, radiolabel is found associated almost exclusively with the subcellular membrane systems — smooth endoplasmic reticulum (SER) and Golgi elements —and with the mitochondria. CA cells are probably similar to vertebrate steroid-synthesizing cells in that the secretory product is synthesized in the SER and mitochondria.Radiolabel was found to be present in all cells of the CA suggesting that all cells are capable of at least the final two stages of JH biosynthesis (the esterification and epoxidation of ³H-farnesenic aid). This indicates that JH biosynthesis may be regulated through changes in the biosynthetic capabilities of individual cells rather than through changes in the total number of cells engaged in biosynthesis. Radiolabel was not observed to be associated with any distinctive cellular product, a result which provides additional evidence for the suggestion that the release of JH from the CA is governed by laws of simple physical diffusion.Supported by operating grants from the National Research Council of Canada to SST and ASMS. ³H-farnesenic acid was supplied by the late Dr. A.F. White of the Unit of Invertebrate Chemistry and Physiology, A.R.C., University of Sussex. We thank Dr. G.E. Pratt for helpful discussions     

The isolation and identification of juvenile hormone from cockroach corpora allata in vitro

Methyl (2E, 6E) - 10, 11 - epoxy - 3, 7, 11 - trimethyl - 2, 6 - dodecadienoate (JH III) is synthesized by corpora cardiaca/allata of the American cockroach $\text{Periplaneta americana in vitro}$ and released into the culture medium. It constitutes the principal part of the biologically detectable JH activity. A fully synthetic medium without terpenoid precursors or serum was used, which proves, that the entire molecule is synthesized $\text{de novo}$. The presence of JH III in orders as different as Blattodea, Orthoptera, Coleoptera and Lepidoptera indicates, that it is the most widely occuring JH of insects.     

Degradation of juvenile hormone and methylation of juvenile hormone acid by corpora cardiaca–corpora allata of the cockroach,Nauphoeta cinerea: I. Biochemical aspects

Corpora cardiaca-corpora allata (CC-CA) from vitellogenic females of Nauphoeta cinerea degraded, in vitro, racemic and (10R)-juvenile hormone III (JH III) at a rate of 249 pmol/CC-CA/h and 786 pmol/CC-CA/h, respectively. The major metabolite formed was JH III acid, together with some highly polar products. CC-CA homogenates degraded racemic JH III to a small extent, whereas (10R)-JH III was degraded efficiently to JH III acid. No highly polar products were formed by CC-CA homogenates. When CC-CA were incubated with racemic JH III acid, some of this substance was degraded to highly polar products, and a minor part was methylated to JH III. CC degraded very little JH III acid and did not methylate it to JH III. CC-CA homogenates methylated JH III acid very efficiently; we measured an apparent K_max of 37.8 μM and a V_max of 1,260 pmol/4 h/ CC-CA equivalent. The addition of JH III acid to CC-CA in vitro increased the rate of biosynthesis of JH III, as determined by measuring incorporation of methyl[¹⁴C]methionine into JH III. These data indicate that the metabolite JH III acid can enter the CA and be methylated to JH III.     

Chemical structure and absolute configuration of a juvenile hormone from grasshopper corpora allata in vitro

One juvenile hormone was isolated from culture medium containing isolated corpora allata of the grasshopper $\text{Schistocerca vaga}$ (Orthoptera: Acrididae) and was shown by microchemical methods to be methyl (2$\text{E}$, 6$\text{E}$) - (10$\text{R}$) - 10, 11-epoxy-3, 7, 11-trimethyldodeca-2, 6-dienoate. This compound (JH III), which occurs in a sphingid moth $\text{Manduca sexta}$, is the first juvenile hormone identified in an insect order other than the Lepidoptera. Grasshopper organs incorporate both [2?¹⁴C] acetate and [methyl-¹⁴C] methionine into JH III showing $\text{de novo}$ biosynthesis, but no indication of the synthesis of JH I or JH II was seen.     

Degradation of juvenile hormone and methylation of juvenile hormone acid by corpora cardiaca–corpora allata of the cockroach,Nauphoeta cinerea: II. Physiological aspects

In vitellogenic females of Nauphoeta cinerea, injected (10R)-juvenile hormone (JH) III was degraded more rapidly than racemic JH III: we measured a half-life of 21 min (with or without coinjection of lipophorin) for the former and 24 min (with coinjection of lipophorin) and 43 min (without coinjection of lipophorin) for the latter. One to two hours after injection, JH III acid was the major metabolite observed; in addition, several highly polar products were found. The half-life of injected racemic JH III acid was 19 min with coinjection of lipophorin and 4 min without. The JH III acid titer in hemolymph was low (around 5–10 pmol/ml) in last instar larvae and previtellogenic and pregnant females and reached higher values (40–100 pmol/ml) in vitellogenic and ovulating females. Racemic JH III acid could be methylated in vitro to JH III by corpora cardiaca–corpora allata (CC-CA) from penultimate instar larvae and females at stages between adult ecdysis and ovulation and at the very end of pregnancy, but not by CC-CA from last instar larvae and adult females at earlier stages of pregnancy. This indicates that CC-CA are capable of methylating JH III acid only at stages when JH III is detectable in the hemolymph. In double-labelling experiments with CC-CA from vitellogenic females and L-[¹⁴C]methionine and [³H]JH III acid as precursors, we observed that only a small proportion (1–8%) of total biosynthesized JH III was derived from JH III acid when the latter was present at physiological concentration. This suggests that in vivo recycling of JH III acid by CC-CA plays only a minor role in the regulation of the titer of JH III and JH III acid.     

Aldehyde dehydrogenase 3 converts farnesal into farnesoic acid in the corpora allata of mosquitoes

The juvenile hormones (JHs) play a central role in insect reproduction, development and behavior. Interrupting JH biosynthesis has long been considered a promising strategy for the development of target-specific insecticides. Using a combination of RNAi, in vivo and in vitro studies we characterized the last unknown biosynthetic enzyme of the JH pathway, a fatty aldehyde dehydrogenase (AaALDH3) that oxidizes farnesal into farnesoic acid (FA) in the corpora allata (CA) of mosquitoes. The AaALDH3 is structurally and functionally a NAD⁺-dependent class 3 ALDH showing tissue- and developmental-stage-specific splice variants. Members of the ALDH3 family play critical roles in the development of cancer and Sjögren–Larsson syndrome in humans, but have not been studies in groups other than mammals. Using a newly developed assay utilizing fluorescent tags, we demonstrated that AaALDH3 activity, as well as the concentrations of farnesol, farnesal and FA were different in CA of sugar and blood-fed females. In CA of blood-fed females the low catalytic activity of AaALDH3 limited the flux of precursors and caused a remarkable increase in the pool of farnesal with a decrease in FA and JH synthesis. The accumulation of the potentially toxic farnesal stimulated the activity of a reductase that converted farnesal back into farnesol, resulting in farnesol leaking out of the CA. Our studies indicated AaALDH3 plays a key role in the regulation of JH synthesis in blood-fed females and mosquitoes seem to have developed a “trade-off” system to balance the key role of farnesal as a JH precursor with its potential toxicity.     

An allatostatic factor and juvenile hormone synthesis by corpora allata in Locusta migratoria

The hemolymph juvenile hormone (JH) titer in sexually immature female adults of Locusta migratoria (Ibaraki strain, Japan) was lower than in sexually mature females; nevertheless, JH synthetic activity by the corpora allata (CA) in vitro was considerably higher in immature females than in sexually mature females ([Okuda et al., 1996]). We carried out experiments to explain this contradiction. The CA activity of sexually immature female adults was very low when the CA were incubated as a complex together with the corpora cardiaca (CC) and brain. When the same complex was assayed after cutting the nerve cord connecting the CC and CA (NCA1), JH synthesis by the CA was enhanced tenfold. When this pair of CA was incubated in fresh medium without the CC and brain, JH synthesis was further increased. Therefore, the higher in-vitro JH production by CA from immature female adults was the result of isolation of the CA from the brain and CC. A methanolic extract of brain-CC complexes contained a factor that inhibited JH synthetic activity by CA in vitro in both immature and mature insects, and this inhibition was reversible. The factor was heat-resistant but lost allatostatic activity after pronase digestion. These results indicate that the allatostatic factor is probably a heat-stable peptide.     

20-hydroxyecdysone stimulation of juvenile hormone biosynthesis by the mosquito corpora allata

Juvenile hormone III (JH) is synthesized by the corpora allata (CA) and plays a key role in mosquito development and reproduction. JH titer decreases in the last instar larvae allowing pupation and metamorphosis to progress. As the anti-metamorphic role of JH comes to an end, the CA of the late pupa (or pharate adult) becomes again “competent” to synthesize JH, which plays an essential role orchestrating reproductive maturation. 20-hydroxyecdysone (20E) prepares the pupae for ecdysis, and would be an ideal candidate to direct a developmental program in the CA of the pharate adult mosquito. In this study, we provide evidence that 20E acts as an age-linked hormonal signal, directing CA activation in the mosquito pupae. Stimulation of the inactive brain-corpora allata-corpora cardiaca complex (Br-CA-CC) of the early pupa (24 h before adult eclosion or −24 h) in vitro with 20E resulted in a remarkable increase in JH biosynthesis, as well as increase in the activity of juvenile hormone acid methyltransferase (JHAMT). Addition of methyl farnesoate but not farnesoic acid also stimulated JH synthesis by the Br-CA-CC of the −24 h pupae, proving that epoxidase activity is present, but not JHAMT activity. Separation of the CA-CC complex from the brain (denervation) in the −24 h pupae also activated JH synthesis. Our results suggest that an increase in 20E titer might override an inhibitory effect of the brain on JH synthesis, phenocopying denervation. All together these findings provide compelling evidence that 20E acts as a developmental signal that ensures proper reactivation of JH synthesis in the mosquito pupae.     

Gas chromatography-mass spectroscopy analysis of juvenile hormone released by insect corpora allata

Corpora allata incubated in appropriate medium release several compounds including juvenile hormones. Juvenile hormones (14C labeled or unlabeled) were extracted with hexane and directly analyzed by gas chromatography-mass spectroscopy. This method allowed the qualitative and quantitative analysis of total released juvenile hormone. It could also be used as a routine assay for evaluation of corpus allatum activity. Data obtained by this method were compared to those obtained by radiochemical assay.     

Farnesoic acid stimulation of C16 juvenile hormone biosynthesis by corpora allata of adult female Diploptera punctata

Biosynthesis of C₁₆ juvenile hormone (C₁₆JH) by isolated corpora allata (CA) of the viviparous cockroach Diploptera punctata has been studied by a radiochemical assay. This assay uses the incorporation from methyl labelled l-methionine in the methyl ester moiety of C₁₆JH. The optimal concentration of l-methionine in the medium has been determined. When varying proportions of (methyl-³H)- and (methyl-¹⁴C)-labelled l-methionine are used in the assay, no isotope effect was observed indicating that labelled l-methionine can be used as a mass marker to quantify C₁₆JH synthesis in D. punctata. C₁₆JH synthesis was stimulated by addition of farnesoic acid (FA) to the medium (maximum at 30–40 μM). When stimulated with 30 μM FA, the C₁₆JH release rate was directly dependent on C₁₆JH synthesis rate, and no intraglandular accumulation of either C₁₆JH or its immediate precursor methyl farnesoate were observed. Spontaneous and FA-stimulated rates of C₁₆JH release were studied during the first reproductive cycle of the adult female. The two final steps of C₁₆JH biosynthesis are not physiologically rate-limiting, as the ratio of spontaneous to FA-stimulated C₁₆JH release (fractional endocrine activity ratio) is always lower than unity. There is a precise relationship between the length of the basal oöcytes and the rate of C₁₆JH release.     

Action of a juvenile hormone analogue on the activity of Periplaneta americana corpora allata in vitro and on juvenile hormone III levels in vivo

The effects of the juvenile hormone (JH) analogue fenoxycarb (ethyl[2-(4-phenoxyphenoxy)-ethyl]carbamate) on the activity of corpora allata (CA) from adult female Periplaneta americana have been investigated. The in vitro biosynthesis of JH III by isolated CA was inhibited by about 85% in the presence of a high concentration (1 × 10⁻⁴ M) of fenoxycarb. However, at lower concentrations (1 × 10⁻⁶ M and 1 × 10⁻⁸ M) no inhibition of JH biosynthesis was apparent. Topical treatment of adult female cockroaches with fenoxycarb (100 μg/insect) did not reduce the subsequent rate of JH III biosynthesis by CA in vitro. By contrast, the same treatment markedly reduced the titre of endogenous JH III in intact cockroaches. These results suggest that CA activity in adult female P. americana may be controlled by negative feedback, and that this system of control is dependent on the maintenance of contact between the CA and nervous or humoral factors in the intact insect. Alternatively, it is possible that treatment with fenoxycarb increases the rate at which endogenous JH is metabolized.     

Inhibition of juvenile hormone III biosynthesis in cockroach corpora allata by interference with the S-adenosylmethionine-dependent transmethylation

The synthesis of juvenile hormone-III by corpora allata of the cockroach Diploptera punctata is dependent under in vitro conditions upon a supply of exogenous methionine. Radiolabelled S-adenosylmethionine was identified by HPLC in extracts of corpora allata incubated with either [methyl-³H]methionine or [³⁵S]methionine. Juvenile hormone (JH) synthesis by intact glands in vitro was inhibited by cycloleucine and selenomethionine, but this inhibition could be relieved by increasing the concentration of methionine. S-adenosylhomocysteine or sinefungin had little or no inhibitory effect on JH synthesis by intact glands, but 5′-deoxy-5′-methylthioadenosine was inhibitory. Adenosine and homocysteine synergistically inhibited JH synthesis. These results show that JH-III synthesis by intact glands can be inhibited by interfering with the S-adenosylmethionine-dependent transmethylation, and suggest that the product and inhibitor of that reaction, S-adenosyl-homocysteine, is rapidly hydrolyzed to adenosine and homocysteine in the corpora allata.     

Structural basis for juvenile hormone biosynthesis by the juvenile hormone acid methyltransferase

Juvenile hormone (JH) acid methyltransferase (JHAMT) is a rate-limiting enzyme that converts JH acids or inactive precursors of JHs to active JHs at the final step of JH biosynthesis in insects and thus presents an excellent target for the development of insect growth regulators or insecticides. However, the three-dimensional properties and catalytic mechanism of this enzyme are not known. Herein, we report the crystal structure of the JHAMT apoenzyme, the three-dimensional holoprotein in binary complex with its cofactor S-adenosyl-l-homocysteine, and the ternary complex with S-adenosyl-l-homocysteine and its substrate methyl farnesoate. These structures reveal the ultrafine definition of the binding patterns for JHAMT with its substrate/cofactor. Comparative structural analyses led to novel findings concerning the structural specificity of the progressive conformational changes required for binding interactions that are induced in the presence of cofactor and substrate. Importantly, structural and biochemical analyses enabled identification of one strictly conserved catalytic Gln/His pair within JHAMTs required for catalysis and further provide a molecular basis for substrate recognition and the catalytic mechanism of JHAMTs. These findings lay the foundation for the mechanistic understanding of JH biosynthesis by JHAMTs and provide a rational framework for the discovery and development of specific JHAMT inhibitors as insect growth regulators or insecticides.     

Control of C-16 juvenile hormone biosynthesis in active corpora allata of female African locusts

Summary

Corpora allata from 8-day-old female Locusta migratoria, during the phase of yolk deposition, exhibit high rates of C-16 juvenile hormone (JH) biosynthesis. The effect of different potential factors which may be involved in the regulation of corpora allata activity is reported. The biosynthetic activity of corpora allata was determined by radiochemical assay.

In maturing females, no changes in corpora allata activity are detected during one daily cycle. Starvation reduces JH biosynthesis only 3 days after the beginning of the food deprivation. Suppression of the median neurosecretory material by electrocoagulation of the internal cardiaca tract (TCC-I) does not disturb JH biosynthesis whereas the transection of the allata I nerve fibres (NCA-I) or the electrocoagulation of the lateral neurosecretory pericarya results in a rapid decline of JH biosynthesis. These data indicate that the median and lateral allatotropins are different, and that only the lateral neurosecretory material exerts an allatostimulating action on corpora allata at the time of vitellogenesis. The corpora allata response to the median allatotropin changes during oocyte growth. C-16 JH and/or 20-hydroxyecdysone treatments in vitro (addition in the culture medium) and in vivo (injection in female) do not influence JH production in our experimental conditions.     

1,5-Disubstituted imidazoles inhibit juvenile hormone biosynthesis by the corpora allata of the mosquito Aedes aegypti

We investigated the effect of fifteen 1,5-disubstituted imidazoles (1,5-dis) on juvenile hormone III (JH III) and methyl farnesoate (MF) biosynthesis by the corpora allata (CA) of the mosquito Aedes aegypti in vitro. Four compounds (TH-35, TH-83, TH-62 and TH-28) significantly decreased JH biosynthesis in the CA dissected from 3-day old sugar-fed females. The decrease of JH synthesis was not always associated with increased MF. TH-30 and TH-83 increased MF levels, while TH-85 and TH-61 significantly decreased MF levels. Five compounds (TH-26, TH-60, TH-83, TH-35 and TH-30) significantly inhibited JH biosynthesis in the CA dissected from females 15 h after a blood meal. Four 1,5-dis (TH-30, TH-26, TH-28 and TH-66) caused MF increases in CA from blood-fed females. 1,5-Disubstituted imidazoles had higher inhibitory activity on JH synthesis when substituted at position 5 by a 3-benzyloxyphenyl group and at position 1 by a benzyl group (such as TH-35). Inhibition of JH and MF biosynthesis by TH-35 was age-dependent and influenced by nutritional status; inhibition differed when evaluated in the CA dissected from sugar-fed females at different days after emergence and in the CA dissected from females at different hours after a blood meal. Inhibition was always higher when the CA was more active. The addition of TH-35 significantly reduced the stimulatory effect of Aedes-allatotropin and farnesoic acid on JH synthesis. This is the first report of an inhibitory effect of 1,5-disubstituted imidazoles on JH synthesis in Diptera.     

Allatotropin regulation of juvenile hormone synthesis by the corpora allata from the lubber grasshopper, Romalea microptera

The in vitro synthesis of juvenile hormone (JH) by corpora allata (CA) from the lubber grasshopper (Romalea microptera) was stimulated by low concentrations of brain extract and this effect was reduced at higher concentrations, suggesting the presence of allatotropin (AT) and allatostatin (AST) factors in the brain. The AT activity of brain extracts caused a rapid and reversible stimulation and appeared to be a peptide(s). Reversed phase (C18) HPLC analysis of brain extracts disclosed two peaks of AT activity but no significant AST activity. Manse-AT, Schgr-NPF, and Locmi-FLRF had no effect on JH synthesis by lubber CA, indicating that the Rommi-AT factors are distinct from these peptides. High concentrations of Dippu-AST-7 and Grybi-AST-1 inhibited JH synthesis, implying that AST factors might be present in lubber grasshoppers. CA response to AT activity of brain extracts varied during the oviposition cycle ( approximately 35 days), with the maximum response occurring on days 16-18. AT activity of brain extracts also varied during the cycle, being highest on day 25. Our data suggest that the lubber CA is largely regulated by AT activity, and that JH synthesis reflects both CA response to AT activity and the level of AT activity in the brain.     

A factor causing stable stimulation of juvenile hormone synthesis by Diploptera punctata corpora allata in vitro

Co-incubation of corpora allata (CA) from the cockroach, Diploptera punctata, with ovaries, fat body or muscle but not brain or testis, leads to a substantial increase in juvenile hormone synthesis. Incubation of the glands in medium pre-conditioned with ovaries also stimulates JH synthesis. The ovary was used as a convenient source of stimulatory factor for a detailed analysis of its physiological effects on the CA. The increase in JH synthesis is stable, maintained over 24h after exposure to the stimulatory factor. Stimulation is dose-dependent, and the corpora allata show an exquisite relationship between sensitivity to this factor and developmental stage. Day 0 and day 1 glands, as well as glands from post-vitellogenic females, are sensitive to stimulation, whereas glands from vitellogenic females are not sensitive. Corpora allata attached to the brain do not respond to the stimulatory factor, and denervation in vivo leads to an increase in JH synthesis by the glands and a loss in sensitivity to the factor. These data suggest that glands from pre- and post-vitellogenic females are inhibited by their nervous connection to the brain. In contrast, glands from vitellogenic females are normally responding to the endogenous stimulatory factor and are thus no longer stimulated in vitro. Co-incubation of CA with allatostatin and conditioned medium still leads to a stimulation of JH synthesis, suggesting that the restraining effect of the nervous connections to the brain is not caused by allatostatin. The CA cell number increases between emergence and day 2, then remains stable until after oviposition. The stimulatory factor accelerates the increase in cell number in young adult females. The results are interpreted as providing evidence for a constitutive change in CA activity caused by a humoral factor produced by various tissues including the ovary, and modulated by nervous connections to the brain.