Biosynthesis of (10R)-Juvenile hormone III from farnesoic acid by Aedes aegypti ovary

Synthesis of (10R)-juvenile hormone III (JH III) outside the corpora allata (CA) was investigated in female Aedes aegypti. Intact females or ligated abdomens of blood-fed and sugar-fed females synthesized in vivo [12-³H]JH III-like molecules from [12-³H]-methyl farnesoate, indicating that an organ(s) in the female abdomen, other than the CA, converted methyl farnesoate into JH III. To find out the organ(s) that synthesized JH III-like molecules, ovaries, fat bodies, and midguts were incubated in vitro with [12-³H]methyl farnesoate and the synthesis of JH III-like molecules was compared with JH III synthesized by CA. To identify tissue(s) having both farnesoic acid methyl transferase and farnesoate epoxidase, enzymes that convert farnesoic acid into JH III, ovaries, and fat bodies were removed from sugar and blood-fed females and incubated with [12-³H]farnesoic acid. Chemical derivatization by methoxyhydrin formation followed by esterification with (+)-α-methoxy- α-trifluoromethyl phenylacetic (MTPA) acid chloride and reversed phase liquid chromatography identified (10R)-JH III methoxyhydrin (+)-MTPA ester as the sole JH III-like molecule produced in tissue culture incubation of ovaries. Since only (10R)-JH III is produced and not racemic JH III, the oxidation of farnesoic acid must be enzymatically mediated. Ovaries and corpora allata of female A. aegypti also synthesized [³H,¹⁴C]JH III from L-[methyl-³H]methionine and [¹⁴C]acetate which was characterized by HPLC and gas chromatography. These results suggest that mosquito ovary can synthesize (10R)-JH III from farnesoic acid, and that this tissue synthesizes JH III-like molecules from L-methionine and acetate. © 1994 Wiley-Liss, Inc.     

Diapause of the southwestern corn borer, Diatraea grandiosella: Further evidence showing juvenile hormone to be the regulator

Further evidence is presented to demonstrate the involvement of juvenile hormone (JH) in regulating diapause in the final larval stage of the southwestern corn borer. Diatraea grandiosella. JH titres in the haemolymph were measured throughout the entire diapause period. Additional results showed that actively secreting corpora allata are necessary to maintain diapause because allatectomized larvae terminated diapause prematurely. A topical application of JH mimic 2 days after the allatectomy prevented this premature termination of diapause. Intact nervous connections between the brain and the corpora allata were necessary for the maintenance of JH secretion. Other surgical work showed that the brains of nondiapausing larvae exhibited a higher ecdysiotropic activity than those of pre-, early-or mid-diapausing larvae.A single application of a JH mimic was more effective in maintaining a diapause-like state in nondiapausing larvae than were repeated topical applications of C₁₈-JH or an implantation of active corpora allata, suggesting that JH was more rapidly metabolized than was the JH mimic. The oxygen consumption of diapausing larvae which had received repeated topical applications of JH mimic was not significantly elevated over that of the controls indicating that treated larvae maintained a low metabolic rate even though they reverted to the spotted morph. A single application of 0.03 μg JH mimic/larva was sufficient to prolong diapause, thereby confirming that JH is necessary for diapause maintenance.     

Ecdysis triggering hormone ensures proper timing of juvenile hormone biosynthesis in pharate adult mosquitoes

Juvenile hormones (JHs) are synthesized by the corpora allata (CA) and play a key role in insect development. A decrease of JH titer in the last instar larvae allows pupation and metamorphosis to proceed. 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 would play an essential role orchestrating reproductive maturation. In the present study, we provide evidence that ecdysis triggering hormone (ETH), a key endocrine factor involved in ecdysis control, acts as an allatotropic regulator of JH biosynthesis, controlling the exact timing of CA activation in the pharate adult mosquito. Analysis of the expression of Aedes aegypti ETH receptors (AeaETHRs) revealed that they are present in the CA and the corpora cardiaca (CC), and their expression peaks 4 h before eclosion. In vitro stimulation of the pupal CA glands with ETH resulted in an increase in JH synthesis. Consistent with this finding, silencing AeaETHRs by RNA interference (RNAi) in pupa resulted in reduced JH synthesis by the CA of one day-old adult females. Stimulation with ETH resulted in increases in the activity of juvenile hormone acid methyltransferase (JHAMT), a key JH biosynthetic enzyme. Furthermore, inhibition of IP₃R-operated mobilization of endoplasmic reticulum Ca²⁺ stores prevented the ETH-dependent increases of JH biosynthesis and JHAMT activity. All together these findings provide compelling evidence that ETH acts as a regulatory peptide that ensures proper developmental timing of JH synthesis in pharate adult mosquitoes.     

The effects of octopamine on juvenile hormone biosynthesis,electrophysiology, and cAMP content of the corpora allata of the cockroach Diploptera punctata

Summary Juvenile hormone production by the corpora allata of the adult female cockroach, Diploptera punctata, can be modulated by treatment with the biogenic amine, octopamine. Endogenous octopamine has been identified within the CA, using HPLC and electrochemical detection. Treatment with octopamine results in a sinusoidal, dose-dependent inhibition of JH biosynthesis by CA from day 2 virgin females, with maximal inhibition occurring at 10^-10 M and 10^-4 M. In day 4 and day 8 mated female corpora allata octopamine inhibited JH biosynthesis at 5·10^-5 M. Although the elevation of either cAMP or cGMP within the CA is known to be associated with an inhibition of JH biosynthesis, treatment with high concentrations of octopamine results in an increase in the level of cAMP but not cGMP. This effect is both dose- and time-dependent.Octopamine treatment also initiates changes in the passive membrane responses of the CA. Superfusion of CA with octopamine results in a pronounced hyperpolarization of CA cells and an increase in the electrotonic potential (indicative of the degree of electrical coupling between CA cells). This effect could be blocked by the octopamine receptor blocker phentolamine. Treatment with octopamine or phentolamine also blocked the hyperpolarization of CA cells normally associated with electrical stimulation of the axon tracts innervating the CA.We hypothesize that octopamine may be a natural neuromodulator of JH production by CA, regulating ion channels in CA cells themselves as well as release of the inhibitory neuropeptide, allatostatin, from the terminals within the CA.Abbreviations 4-AP 4-aminopyridine - CA corpora allata - CC corpora cardiaca - cAMP cyclic adenosine monophosphate - cGMP cyclic guanosine monophosphate - EDTA ethylenediamine tetraacetic acid - HEPES N-2-hydroxyethylpiperazine-N2-ethanesulfonic acid - HPLC high pressure liquid chromatography - IBMX 3-isobutyl-1-methylxanthine - JH juvenile hormone - ms millisecond - nA nanoampere - NCA I nervi corporis allati I - OCT octopamine - TEA tetraethyl ammonium     

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.     

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.     

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     

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.     

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.     

The effect of l-methionine concentration on juvenile hormone biosynthesis by corpora allata of the cockroach Diploptera punctata

The effect of varying l-methionine (l-met) concentration on rates of juvenile hormone (JH) biosynthesis/release by corpora allata of females of the viviparous cockroach Diploptera punctata has been studied using a radiochemical assay. Both high activity glands (corpora allata from day 5 females) and low activity glands (corpora allata from day 11 females) were used to study the dose dependence of JH biosynthesis on l-met concentrations, under both de novo (spontaneous) conditions of JH biosynthesis and stimulated conditions (in the presence of the exogenous JH III precursor farnesoic acid). Maximal rates of JH biosynthesis/release were observed at l-met concentration of 20 μM (spontaneous) and 40 μM (stimulated). Below these concentrations, rates of JH biosynthesis declined linearly with decreasing l-met concentration. Optimal concentration of l-met appeared to be similar for both high and low activity corpora allata, under spontaneous and stimulated conditions of biosynthesis. Above 40 μM l-met, no increase in rates of JH biosynthesis was observed. It appears that the corpora allata of D. punctata are efficient scavengers of l-met and are able to utilize even low concentrations of the substrate for JH biosynthesis. The corpora allata of D. punctata may prove useful for the biosynthesis of authentic JH III, radiolabelled in the methyl position using as methyl donor, l[methyl-³H]met of high specific activity.     

Apparent inhibition of in vitro juvenile hormone biosynthesis by the corpus cardiacum of adult crickets (Gryllus bimaculatus and Acheta domesticus) is due to juvenile hormone esterase

When measuring the in vitro JH III-biosynthesis by corpora allata (CA) from adult female crickets in the presence of corpora cardiaca (CC), the amount of JH III in the medium decreased in a dose dependent manner. The CC of a 4-day-old female Gryllus bimaculatus contain 42 pmol.pair CC⁻¹ Grb-AKH, 0.62 pmol.pair CC⁻¹ octopamine, and a JH-esterase activity of 9.8 pmol JH.h⁻¹.pair CC⁻¹. Comparable values for Acheta domesticus are 21 pmol.pair CC⁻¹ Grb-AKH, 0.53 pmol.pair CC⁻¹ octopamine, and 6.5 pmolJH.h⁻¹.pair CC⁻¹ of JH-esterase activity. Even if the entire octopamine content of the CC were released into the medium, the concentration would be below the 10⁻⁵ M threshold for octopamine inhibition of JH synthesis. An in vitro AKH inhibition of JH III synthesis was observed, but only at a relatively high concentration (10⁻⁵ M). If the entire AKH content (10⁻⁶ M) of the CC were released into the medium, the AKH concentration would approach JH synthesis inhibiting levels. However, the rate of release of AKH in vitro was very low, and, therefore, AKH from the CC could not affect JH synthesis. In contrast, a specific JH-esterase, released by isolated CC into the medium, was sufficiently high in both cricket species to account for the observed decrease in JH III present. OTFP-sulfone (10⁻⁵ M) restored apparent JH synthesis of the CA to the control level. There was no reduction in the amount of JH released when CA were incubated with heat treated CC. The CA themselves contained almost no JH-esterase activity. © 1997 Wiley-Liss, Inc.     

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.     

Biosynthesis and regulation of juvenile hormone III,juvenile hormone III bisepoxide,and methyl farnesoate during the reproductive cycle of the grey fleshfly,Neobellieria (Sarcophaga) bullata

To study the effect of brain signals on the biosynthesis of juvenile hormone by the corpora allata of the grey fleshfly Neobellieria bullata, exposed corpora allata connected to the brain were surgically removed from sugar-fed flies and incubated in vitro with L -[³H-methyl]methionine. After incubation, the media together with the tissues were analyzed by HPLC. [³H]Juvenile hormone III (JH III), [³H]JH III bisepoxide (BE), [³H]methyl farnesoate (MF) and an unknown [³H]labeled metabolite (Un) were identified as the primary products. The rate of synthesis of [³H]JH III bisepoxide was higher than that of [³H]JH III, [³H]MF and [³H]Un. Two days after a liver meal, female flies synthesized more JH III, MF, BE, and the Un than did males. Synthesis of JH III, BE, and MF in females was lower during the previtellogenic, sugar-feeding period than during the vitellogenic liver-feeding period. Isolated corpus cardiacum–corpus allatum (CC-CA) complexes that were incubated in vitro synthesized less JH III, MF, and BE, as compared to complexes that were attached to the brain, indicating that the brain probably modulates the biosynthesis of JH III, MF, and BE in the corpora allata. Upon incubation of brain–CC–CA complexes with Neb-TMOF (10^–8 M), Neb-colloostatin (10^–8 M), ovarian, or brain extracts resulted in significant inhibition of JH III and BE biosynthesis in the presence of ovarian extracts. These results indicate that allatostatin-like factors are present in the ovary of the flesh fly. Arch. Insect Biochem. Physiol. 37:248–256, 1998. © 1998 Wiley–Liss, Inc.     

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.     

Mating in Heliothis virescens: Transfer of juvenile hormone during copulation by male to female and stimulation of biosynthesis of endogenous juvenile hormone

Studies were undertaken to determine whether adult males of Heliothis virescens transfer juvenile hormone (JH) to females during copulation, and an in vitro radiochemical assay was used to determine whether mating causes an allatotropic effect, i.e., stimulation of JH biosynthesis by corpora allata (CA). In vitro, CA from 3-day-old mated females synthesized and released approximately 2.5 times total JH as that of CA from comparably aged virgin females. Of the homologues, JH II exhibited significant increase in mated females; JH I also increased but not significantly. JH III remained similar to that of virgin females. This is the first demonstration of an allatotropic effect of mating in moths. In contrast to the female, CA of virgin males did not produce any JH, but accessory sex glands (ASG) in 3-day-old males synthesized small amounts of JH. Immediately after adult emergence, male ASG contained approximately 1.5 ng JH I and II, which increased by 12 h after emergence and remained at this high level up to 54 h after emergence. JH III was barely detected in ASG. JH in ASG of mated male immediately after uncoupling was depleted almost completely, and 24 h later recovered to levels comparable to that of 54-h-old virgin male. Virgin female bursa copulatrix did not contain any JH, but mated female bursa, immediately after uncoupling, had JH at levels comparable to that observed in virgin male ASG. By 6 h after uncoupling, JH levels decreased dramatically in mated female bursa. These data suggest the transfer of JH to females by the male. Arch. Insect Biochem. Physiol. 38:100–107, 1998. © 1998 Wiley-Liss, Inc.     

Responsiveness of the adult cricket (Gryllus bimaculatus andAcheta domesticus) retrocerebral complex to allatostatin-1 from a cockroach,Diploptera punctata

Brain-retrocerebral complexes of female crickets,Gryllus bimaculatus andAcheta domesticus, treated with antibody to allatostatin-1 from a cockroach,Diploptera punctata, show extensive immunoreactivity. The results suggest that allatostatins or allatostatin-like molecules are produced in neurosecretory cells of the brain and are delivered to the corpora allata through nervous connections and/or via haemolymph. Radiochemical measurements of juvenile hormone III biosynthesis by isolated corpora cardiaca-corpora allata complexes from adultG. bimaculatus have been used to demonstrate an in vitro sensitivity of these glands to allatostatin-1 fromD. punctata. Allatostatin-1 is a relatively potent inhibitor of juvenile hormone III biosynthesis in corpora allata of both young adult females and males. In glands taken from 3-day virgin females, 50% inhibition of hormone biosynthesis is reached at ca. 3 nmol·l^-1 allatostatin-1. The inhibitory action of allatostatin-1 is rapid, dose-dependent and reversible. Addition of 200 mol·l^-1 farnesol to the incubation medium prevents inhibition of juvenile hormone III biosynthesis by allatostatin-1. Juvenile hormone III biosynthesis by isolated corpora allata of 3-day female house crickets,A. domesticus, is also susceptible to inhibition by 1 mol·l^-1 allatostatin-1.Abbreviations ASB2 Diploptera punctata allatostatin-5 - CA corpora allata - CC corpora cardiaca - Dip A-1 Diploptera punctata allatostatin-1 - HEPES 4-(2-hydroxyethyl)piperazine-1-ethanesulphonic acid - JH juvenile hormone(s) - Mas-AS Manduca sexta allatostatin - MF methyl farnesoate - NCA nervus corporis allati - NCC nervus corporis cardiaci - SEM standard error of mean - TRIS Tris(hydroxymethyl)aminomethane     

Allatostatin-C reversibly blocks the transport of citrate out of the mitochondria and inhibits juvenile hormone synthesis in mosquitoes

Aedes aegypti allatostatin-C (AeaAST-C or PISCF-AST) is a strong and fast reversible inhibitor of juvenile hormone III (JH III) synthesis by the corpora allata (CA) of mosquitoes; however, its mechanism of action remains poorly understood. AeaAST-C showed no inhibitory activity in the presence of any of the intermediate precursors of JH III indicating that the AeaAST-C target is located before the entry of acetyl-CoA in the pathway. Stimulation experiments using different sources of carbon (glucose, pyruvate, acetate and citrate) suggest that AST-C acts after pyruvate is transformed to citrate in the mitochondria. In vitro inhibition of the citrate mitochondrial carrier (CIC) mimicked the effect of AeaAST-C, and was overridden by addition of citrate or acetate. Our results provide compelling evidence that AeaAST-C inhibits JH III synthesis by blocking the CIC carrier that transports citrate from the mitochondria to the cytosol, obstructing the production of cytoplasmic acetyl-CoA that sustains JH III synthesis in the CA of mosquitoes.     

Role of juvenile hormone and allatotropin on nutrient allocation, ovarian development and survivorship in mosquitoes

Teneral reserves are utilized to initiate previtellogenic ovarian development in mosquitoes. Females having emerged with low teneral reserves have reduced juvenile hormone (JH) synthesis and previtellogenic development. We investigated what role JH, allatotropin (AT) and other head-factors play in the regulation of previtellogenic ovarian development and adult survivorship. Factors from the head are essential for corpora allata (CA) activation and reproductive maturation. We have shown that decapitation of females within 9-12h after adult ecdysis prevented normal development of the previtellogenic follicles; however maximum previtellogenic ovarian development could be induced in decapitated females by topically applying a JH analog. When females were decapitated 12 or more hours after emergence nutritional resources had been committed to ovarian development and survivorship was significantly reduced. To study if allatotropin levels correlated with teneral reserves, we measured AT titers in the heads of two adult phenotypes (large and small females) generated by raising larvae under different nutritional diets. In large mosquitoes AT levels increased to a maximum of 45 fmol in day 4; in contrast, the levels of allatotropin in the heads of small mosquitoes remained below 9 fmol during the 7 days evaluated. These results suggest that only when nutrients are appropriate, factors released from the brain induce the CA to synthesize enough JH to activate reproductive maturation.     

Spatial expression of the mevalonate enzymes involved in juvenile hormone biosynthesis in the corpora allata in Bombyx mori

The developmental expressions of the mRNA of JH synthetic enzymes have been studied using homogenates of the corpora cardiaca-corpora allata (CC-CA) complexes in Bombyx mori [Kinjoh, T., Kaneko, Y., Itoyama, K., Mita, K., Hiruma, K., Shinoda, T., 2007. Control of juvenile hormone biosynthesis in Bombyx mori: cloning of the enzymes in the mevalonate pathway and assessment of their developmental expression in the corpora allata. Insect Biochemistry and Molecular Biology 37, 808-818]. The in situ hybridization analyses in the CC-CA complex showed that the distribution of the mRNAs of all the mevalonate enzymes and juvenile hormone (JH) acid O-methyltransferase occurred only in the CA cells, indicating that the fluctuations of the enzyme mRNA amounts in the CC-CA complexes were derived solely from the CA. In addition, the size of the CA and their nuclei was not associated with the JH synthetic activity by the CA until the pharate adult. Only female adult CA synthesized JH in B. mori, and the CA and the nuclei were significantly larger than those of male CA which do not synthesize JH.