Methyl farnesoate: Its site of synthesis and regulation of secretion in a juvenile crustacean

Analogy to Insecta suggests that JH(s) may play important roles in the development and reproduction of Crustacea. It has recently been shown by Laufer et al. (1987), using LC and GC/MS that the mandibular organ of adult crabs synthesized methyl farnesoate, the unepoxidated from of JH III, and that synthesis varied according to the sex, as a function of eyestalk ablation, and stage of vitellogenesis. In experiments reported here, we found that eyestalk removal from juvenile spider crabs, Libinia emarginata, resulted in a two-fold increase in the rate of MF synthesis by MOs in vitro. Furthermore, 2 h incubations of MOs from eyestalk ablated animals with eyestalk extracts inhibited the rate of synthesis of MF by about 60%. These results suggest that MF may be a gonad stimulating hormone (GSH) reported by other workers. Secretion by the MO is inhibited by an eyestalk factor (MO-IH), and MO-IH may be similar or identical to the gonad inhibiting hormone (GIH) reported by others.     

Biosynthesis and release of juvenile hormone and its precursors in insects and crustaceans: The search for a unifying arthropod endocrinology

It now appears that arthropods produce and release a wider variety of juvenile hormones (JH) and related compounds than previously thought. For instance, in the adult crayfish, Procambarus clarkii, the mandibular organs, the homologous structure to insect corpora allata (CA), release both farnesoic acid (FA) and methyl farnesoate (MF), the immediate precursors of JH III, but not JH III itself. In larvae of the cockroach Diploptera punctata, JH III production ceases during the last half of the 4th stadium, but the CA continue to produce and release FA throughout this period. The embryos of the same species also release JH III and a product that coelutes with MF on HPLC. In adult blowfly, Calliphora vomitoria, the CA release JH III bisepoxide and possibly the 6,7-epoxide, in addition to JH III. In the lepidopteran species Pseudaletia unipuncta, male CA produce and release JH acids I, II, and III as well as a product which we have tentatively identified as homo-(and/or) dihomo-FA. In the females, CA produce and release the three common JH homologues and a product that we believe is the esterified version of the male compound, homo/dihomo-MF. Although the release of JH precursors from their sites of synthesis might result in their conversion to the active hormone in peripheral tissues, there is only limited evidence for such a process. Studies on biological activities of these compounds and on the developmental changes in biosynthesis and its regulation should provide information necessary for the defining of these compounds as hormones or otherwise and should improve our understanding of the evolution of the JH biosynthetic pathway in the phylum Arthropoda.     

Methyl farnesoate induced ovarian maturation in the spider crab,Libinia emarginata

Summary

To overcome the problem of getting crustaceans to reproduce in captivity, eyestalk ablation or X-organ sinus gland removal is commonly utilized in commercially important species such as shrimp. We have investigated the effect of unilateral and bilateral eyestalk ablation on methyl farnesoate (MF) production by mandibular organs (MOs) and on ovarian maturation in female spider crabs Libinia emarginata, a useful model since these animals are in a terminal molt and are devoid of a functional Y-organ. Non-reproductive, over-wintering female L. emarginata were induced to be reproductive by feeding and increasing the holding temperature to stimulate the endocrine system. In addition, we removed X-organ sinus glands by eyestalk ablation either unilaterally (UEA) or bilaterally (BEA) to further stimulate MF synthesis by MOs. Endogenous MF in the hemolymph was extracted and quantified by means of HPLC and in some cases by GC/MS. Oocyte growth and egg quality were studied simultaneously to determine how they were related to MF levels found during vitellogenesis. The initial MF concentration in unablated controls was low, 0.31 ng/ml of hemolymph, and this increased (p<0.05) to about 1 ng/ml by 2 weeks, remaining at about that level for the remainder of the experiment. Eyestalk ablation significantly stimulated MF concentrations by week 1 to nearly 2 and 3.5ng/ml in the UEA (p <0.01) and BEA (p <0.001) animals, respectively. Oocytes appeared to respond to increased MF levels, as ovarian maturation was initiated from the point at which MF increased (p <0.05). Thereafter, the rate of oocyte growth was directly correlated with the extent of elevation of MF. The gonado-somatic index [(GSI) = gonad weight/body weight × 100] of controls at the start was about 1.5 and increased to 6.5 by week 4. Mature oocytes were reached at a GSI around 7. Oocyte maturation was accomplished at week 2 in BEA, week 3 in UEA, and later than week 4 in controls. After maturation, oocytes started to degrade in some ablated animals, particularly in the bilaterally ablated ones where the highest MF concentrations were observed. These data indicate that MF elevations are required for stimulating ovarian maturation in Crustacea. MF appears to accelerate gonad development during the vitellogenic process, but may be deleterious at high concentrations. These results have a significant and important application and implications for aquaculture.     

Comparison of gregariousness in larvae and adults of four species of zetoborine cockroaches

Insects observed in groups in nature may be gathered either by attractants from the environment or by conspecifics. Field distribution data alone are thus insufficient to assess congregation by conspecifics and complementary laboratory tests of spacing patterns are required. Such tests were performed in four species of Zetoborinae (Insecta, Blattaria), for which field studies showed differences in spatial distribution (Schultesia lampyridiformis Roth, Phortioeca nimbata Burmeister, Lanxoblatta emarginata Burmeister and Thanatophyllum akinetum Grandcolas). Gregariousness, mobility, and sticking to shelters were compared between these four species. Tests were performed on pairs of adults of the same sex and opposite sexes, and also on first instar larvae, either in isolation or in groups of two and four individuals. In S. lampyridiformis, adults were strongly gregarious, whereas larvae dispersed early after birth and were very mobile during the first instar. In P. nimbata, larvae and adults were gregarious, while in L. emarginata larvae were weakly gregarious, and gregariousness decreased when density increased. Adults of L. emarginata seemed to be indifferent to each other. Larvae and adults of T. akinetum were solitary and they actively dispersed. The varying levels of gregariousness among species are discussed according to the known ecological habits in Zetoborinae.     

Effects of juvenile hormone analogues on larval metamorphosis in the barnacle Elminius modestus Darwin (Crustacea: Cirripedia)

Two analogues of insect juvenile hormones (JH) have been shown to interfere with the development of Elminius modestus Darwin larvae when dispersed as acetone solutions in sea water. Stage VI nauplii metamorphosed to morphologically abnormal larvae which were intermediate in size between the nauplius and cypris stages; although these larvae were cypris-like they apparently retained some nauplius characteristics. Cyprids either metamorphosed to non-attached adults or formed larvae which were larger or morphologically abnormal. There was evidence that the effects may be related to the physiological development of the larvae at time of exposure. These observations appear to be the first report of the induction of size and morphological abnormalities in a crustacean species by analogues of insect JH and resemble those arising from the hormonal imbalance which such compounds induce during the development of holometabolous insects.     

DrosophilaCG10527 mutants are resistant to juvenile hormone and its analog methoprene

Juvenile hormone (JH) is critical for development, metamorphosis, and reproduction in insects. While the physiological importance of JH has been appreciated for decades, its biosynthetic pathway and molecular action remain poorly understood. DrosophilaCG10527 encodes a protein with high homology to crustacean farnesoic acid methyltransferase (FAMeT) that converts farnesoic acid to methyl farnesoate (MF), a precursor of JH, but its in vivo functions remain unclear. Here we report that CG10527 is expressed widely in secondary cells in the male accessory glands, in ovarian follicle cells, and in glial cells in the nervous system. Furthermore, CG10527 is expressed abundantly in the corpora allata where JH is synthesized. To understand the physiological functions of CG10527, we generated specific CG10527 deletions. Phenotypic analysis showed that CG10527 null mutants are fully viable and fertile in both sexes, indicating that CG10527 is not essential for survival and fertility. Surprisingly, CG10527 mutants showed no defects in the biosynthesis of MF and JH. However, CG10527 mutants were 3-5 times more resistant than wild-type flies to topically applied MF and JH as well as the JH analog methoprene at both sub-lethal and lethal doses. Taken together, our data indicate that DrosophilaCG10527 plays little, if any, role in JH biosynthesis but may participate in the JH signaling pathway.     

Methyl Farnesoate Plays a Dual Role in Regulating Drosophila Metamorphosis

Corpus allatum (CA) ablation results in juvenile hormone (JH) deficiency and pupal lethality in Drosophila. The fly CA produces and releases three sesquiterpenoid hormones: JH III bisepoxide (JHB3), JH III, and methyl farnesoate (MF). In the whole body extracts, MF is the most abundant sesquiterpenoid, followed by JHB3 and JH III. Knockout of JH acid methyl transferase (jhamt) did not result in lethality; it decreased biosynthesis of JHB3, but MF biosynthesis was not affected. RNAi-mediated reduction of 3-hydroxy-3-methylglutaryl CoA reductase (hmgcr) expression in the CA decreased biosynthesis and titers of the three sesquiterpenoids, resulting in partial lethality. Reducing hmgcr expression in the CA of the jhamt mutant further decreased MF titer to a very low level, and caused complete lethality. JH III, JHB3, and MF function through Met and Gce, the two JH receptors, and induce expression of Kr-h1, a JH primary-response gene. As well, a portion of MF is converted to JHB3 in the hemolymph or peripheral tissues. Topical application of JHB3, JH III, or MF precluded lethality in JH-deficient animals, but not in the Met gce double mutant. Taken together, these experiments show that MF is produced by the larval CA and released into the hemolymph, from where it exerts its anti-metamorphic effects indirectly after conversion to JHB3, as well as acting as a hormone itself through the two JH receptors, Met and Gce.     

Juvenile hormone acid synthesis and HMG-CoA reductase activity in corpora allata of Manduca sexta prepupae

Corpora allata (CA) of last instar larvae of Manduca sexta switch from juvenile hormone (JH) to JH acid secretion just before the onset of wandering behavior. JH acid secretion peaked during the prepupal period and ceased prior to pupal ecdysis. HMG-CoA reductase activity also peaked during the prepupal period and then declined. However, substantial enzyme activity was present in pupal and pharate adult glands. Removal of the brain at the wandering stage caused a reduction in JH acid secretion by prepupal CA. The profile of HMG-CoA activity in CA of debrained larvae resembled that of sham-operated larvae except that the prepupal peak was smaller than in control larvae. Addition of brain extracts to CA maintained in vitro neither stimulated not inhibited JH acid secretion and HMG-CoA reductase activity. It is suggested that the brain regulates CA activity in post-wandering stages via intact nerves.     

Activities of natural methyl farnesoids on pupariation and metamorphosis of Drosophila melanogaster

Methyl farnesoate (MF) and juvenile hormone (JH III), which bind with high affinity to the receptors USP and MET, respectively, and bisepoxy JH III (bisJH III) were assessed for several activities during Drosophila larval development, and during prepupal development to eclosed adults. Dietary MF and JH III were similarly active, and more active than bisJH III, in lengthening larval development prior to pupariation. However, the order of activity was changed (JH III > bisJH III > MF) with respect to preventing prepupae from eclosing as normal adults, whether administered in the larval diet or as topically applied at the white puparium stage. If endogenous production of all three larval methyl farnesoids was suppressed by a strongly driven RNAi against HMGCR in the corpora allata cells, most larvae did not attain pupariation. Farnesol (which has no demonstrated life-necessary function in larval life except in corpora allata cells as a precursor to methyl farnesoid biosynthesis) when incorporated into the diet rescued attainment of pupariation in a dose-dependent manner, presumably by rescuing endogenous production of all three hormones. A more mild suppression of endogenous methyl farnesoid production enabled larval attainment of pupariation. However, in this background dietary MF had increased activity in preventing puparia from attaining normal adult eclosion. The physiological relevance of using exogenous methyl farnesoids to block prepupal development to normally eclosed adults was tested by, instead, protecting in prepupae the endogenous titer of methyl farnesoids. JH esterase normally increases during the mid-late prepupal stage, presumably to clear endogenous methyl farnesoids. When JH esterase was inhibited with an RNAi, it prevented attainment of adult eclosion. Cultured adult corpora allata from male and female Aedes aegypti released both MF and JH III, and the A. aegypti nuclear receptor USP bound MF with nanomolar affinity. These A. aegypti data support the use of Drosophila as a model for mosquitoes of the binding of secreted MF to USP.     

Methyl farnesoate synthesis is necessary for the environmental sex determination in the water flea Daphnia pulex

Sex-determination systems can be divided into two groups: genotypic sex determination (GSD) and environmental sex determination (ESD). ESD is an adaptive life-history strategy that allows control of sex in response to environmental cues in order to optimize fitness. However, the molecular basis of ESD remains largely unknown. The micro crustacean Daphnia pulex exhibits ESD in response to various external stimuli. Although methyl farnesoate (MF: putative juvenile hormone, JH, in daphnids) has been reported to induce male production in daphnids, the role of MF as a sex-determining factor remains elusive due to the lack of a suitable model system for its study. Here, we establish such a system for ESD studies in D. pulex. The WTN6 strain switches from producing females to producing males in response to the shortened day condition, while the MFP strain only produces females, irrespective of day-length. To clarify whether MF has a novel physiological role as a sex-determining factor in D. pulex, we demonstrate that a MF/JH biosynthesis inhibitor suppressed male production in WTN6 strain reared under the male-inducible condition, shortened day-length. Moreover, we show that juvenile hormone acid O-methyltransferase (JHAMT), a critical enzyme of MF/JH biosynthesis, displays MF-generating activity by catalyzing farnesoic acid. Expression of the JHAMT gene increased significantly just before the MF-sensitive period for male production in the WTN6 strain, but not in the MFP strain, when maintained under male-inducible conditions. These results suggest that MF synthesis regulated by JHAMT is necessary for male offspring production in D. pulex. Our findings provide novel insights into the genetic underpinnings of ESD and they begin to shed light on the physiological function of MF as a male-fate determiner in D. pulex.     

cDNA cloning of a mandibular organ inhibiting hormone from the spider crabLibinia emarginata

Mandibular organs (MO) produce a crustacean juvenile hormone, methyl farnesoate (MF). MO activity is negatively regulated by factors, called mandibular organ inhibiting hormones (MOIHs), from the crustacean sinus gland X-organ complex in the eyestalks. Three MOIHs have been isolated previously from the spider crabLibinia emarginata and are characterized as members of the crustacean hyperglycemic hormone (CHH) neuropeptide family. In the research reported here, a full length cDNA sequence of 972 bp of a MOIH was isolated by screening a cDNA library constructed from the eyestalks ofLibinia emarginata. This cDNA sequence encodes a preprohormone peptide with 137 amino acid residues, including a 26-amino acid long signal peptide, a 34-amino acid long precursor peptide, a dibasic peptide, the full length of 72-amino acid long MOIH, and a tri-peptide Gly-Lys-Lys which designates the potential amidation site at the C-terminus of the mature peptide.     

Spiny lobster development: mechanisms inducing metamorphosis to the puerulus: a review

This review outlines current knowledge of mechanisms effecting metamorphosis in decapod crustaceans and insects. The comparative approach demonstrates some of the complexities that need resolving to find an answer to the question raised frequently by ecologists: “What triggers metamorphosis in spiny lobsters?” It is evident that crustacean moulting and metamorphosis are genetically controlled through endocrine systems that mediate gene expression. The molecular mechanisms underlying these developmental processes have been studied intensively in insects, particularly in the fruitfly, Drosophila melanogaster (Diptera), and some lepidopteran species. Comparatively, there is minimal information available for a few decapod crustacean species, but none for spiny lobsters (Palinuridae). Nothing was known of hormone signalling transduction pathways, via nuclear receptors (NRs) and gene activation during larval moults in palinurids—until a recent, ground-breaking study of early phyllosomal development of Panulirus ornatus by Wilson et al. (Rock Lobster Enhancement and Aquaculture Subprogram. FRDC Project 2000/263, Australian Govt, Fisheries Research and Development Corporation and Australian Institute of Marine Science, Nov 2005). Their study not only identified homologues of five hormone NRs of D. melanogaster, but also patterns of gene regulation showing strong similarities to those of gene expression found in insect larval development. Their results indicated that control of moulting and metamorphosis in palinurids closely parallels that in insects, suggesting that insects can serve as model systems for elucidating molecular mechanisms in larval decapods. In insects and crustaceans, the steroid hormone, ecdysone, (20E) initiates moulting. In insects, juvenile hormone (JH) mediates the type of larval moult that occurs, either anamorphic or metamorphic. The latter results when the level of JH in the haemolymph drops in the final larval instar. High levels of JH inhibit the metamorphic moult during insect larval development. The interaction of 20E and JH is not fully understood, and the operative molecular mechanisms are still being elucidated. No nuclear receptor for JH has been identified, and alternative JH signalling pathways await identification. In decapod crustaceans, methyl farnesoate (MF), a precursor of JH, replaces the latter in other functions mediated by JH in insects; but there is little evidence indicating that MF plays a similar ‘antimetamorphic’ role in decapod larval moults.     

Unifying Concepts Learned from Methyl Farnesoate for Invertebrate Reproduction and Post-Embryonic Development

Since the discovery that methyl farnesoate (MF), the unepoxidatedform of the insect juvenile hormone (JHIII), is produced bymandibular organs of numerous crustaceans, extensive evidencehas accumulated that this compound appears to perform similarfunctions in the Crustacea as JH performs in insects. A majorfunction of MF appears to be in enhancing reproductive maturation.This was first shown by indirect experimentation with eyestalkablation, which augmented MF production. Subsequently, directtreatments of several species of crustacea with MF showed thatreproductive maturation was enhanced. A second function of MF, similar to that of the JH of insects,is in the maintenance of juvenile morphology. This is especiallytrue in the late larval transformations into juveniles, whereMF plays an inhibitory role, as well as during the transformationof juveniles into adults. These results were inferred from eyestalkremoval experiments. In the case of the larval-juvenile transition,inhibitory results were also obtained with MF by direct hormonetreatments. However, the transition from very early larval stages,such as one nauplius stage proceeding to the next, which inmany cases also involves morphogenetic changes, may be occurringin the presence of MF. Indeed, MF appears to be stimulatoryto early postembryonic larval stages of Crustacea. Again, thisfunction of MF in Crustacea appears to be similar to functionsof JH in early postembryonic insects. However, it should bepointed out that there are many more "early" stages in Crustaceathan there are in insects, and very few of these cases havebeen investigated. When considering the animal kingdom and larval metamorphosis,the question may be raised whether there are other members ofthe JH family regulating metamorphosis and reproduction. Oneplausible example appears to be among certain annelids. Thetrochophores of Capitella respond to various juvenoids, butare most responsive, within one hour, to MF and eicosatrienoicacid. This latter compound is present also in adult annelids,where it has been named "Sperm Maturation Factor," since itseems to function in the maturation of sperm in Arenicola. Therefore,eicosanoids perform in annelids two functions performed in insectsby JHs. In conclusion, it seems that there are morphogenesis promotingresponses to JHs in early larval development in crustaceans,annelids, and possibly other forms, which differ from thoseMF effects in later larvae of Crustacea where MF retards morphogenesis.Such early responses as noted here have recently also been describedfor insects. Furthermore, it is clear that the polyunsaturated8,11,14-eicosatrienoic and aracidonic acids seem to be juvenoids,and appear to function as such in annelids, and may also befunctionally active in insects and crustaceans. It seems reasonableto conclude therefore that new and novel juvenoids exist, whileothers still await discovery.     

Uptake of the yolk protein, lipovitellin, by developing crustacean oocytes

A variety of cytochemical techniques were used to demonstrate how crustacean lipovitellin accumulates within the egg. It was found that a protein serologically identical to the lipovitellin of yolk spheres was present in the hemolymph of vitellogenic crustaceans, but was absent from the hemolymph of males and immature females.In the three crustacean species studied (Uca pugilator, Cambarus clarkii, and Libinia emarginata), pinocytosis of fluorescein-conjugated lipovitellin and trypan blue occurred only during those periods when oocytes were accumulating yolk.It may be concluded from the present studies that yolk spheres develop in crustacean eggs primarily through micropinocytotic uptake of lipovitellin from the hemolymph, although other oocyte proteins appear to be made in the oocyte.     

Regulation and significance of ecdysteroid titre fluctuations in lepidopterous larvae and pupae

The last larval moult of Galleria mellonella is induced by an elevation of ecdysteroid titre to more than 200 ng/g. After ecdysis the titre remains very low until 70 hr of the last-instar when a slight elevation in ecdysteroid concentration initiates the onset of metamorphosis. An ecdysteroid peak (275 ng/g), which occurs between 108 and 144 hr, is associated with wandering and cocoon spinning. Pupal ecdysis follows about 20 hr after a large ecdysteroid peak (780 ng/g) with a maximum in slowly-mobile prepupae (160 hr of the last larval instar). The ecdysteroid decrease between the two peaks coincides with the period when the larvae exposed to unfavourable conditions enter diapause. The pupal-adult moult is initiated by a high ecdysteroid peak (1500–2500 ng/g) in early pupae and imaginal cuticle is secreted in response to a smaller peak (ca. 500 ng/g) in the middle of pupal instar.Until early pupae, the ecdysteroid content is regulated by the prothoracic glands. In decapitated larvae the glands become spontaneously active after 30–40 days and the body titre of ecdysteroids undergoes an increase; the glands revert to inactivity when the insects accomplish secretion of pupal cuticle. A similar ecdysteroid increase occurs within 10 days when the decapitated larvae receive implants of brains releasing the prothoracicotropic neurohormone (PTTH). In either case, the pupation-inducing increase of ecdysteroids is 3 times higher than the large ecdysteroid peak in the last-instar of intact larvae. This indicates that the function of prothoracic glands in intact larvae is restrained, probably by the juvenile hormone (JH). Exogenous JH suppresses the spontaneous activation of the prothoracic glands in decapitated larvae and reduces the ecdysteroid concentration in those larvae (both decapitated and intact), whose glands were activated by PTTH. Furthermore, JH influences the PTTH release from the brain in situ: depending on JH concentration and the age and size of treated larvae, the PTTH liberation is either accelerated or delayed.Neither in G. mellonella larvae, nor in the diapausing pupae of Hyalophora cecropia and Celerio euphorbiae, does JH directly activate the prothoracic glands. It is suggested that the induction of the moult by JH in decerebrate insects, which has been observed in some species, is either due to indirect stimulation of ecdysteroid production or to increased sensitivity of target tissues to ecdysteroids. In G. mellonella, a moult occurs at a 5–15 times lower than usual ecdysteroid concentration when the last-instar larvae are exposed to JH.     

Juvenile hormone pathway in honey bee larvae: A source of possible signal molecules for the reproductive behavior of Varroa destructor

The parasitic mite Varroa destructor devastates honey bee (Apis mellifera) colonies around the world. Entering a brood cell shortly before capping, the Varroa mother feeds on the honey bee larvae. The hormones 20‐hydroxyecdysone (20E) and juvenile hormone (JH), acquired from the host, have been considered to play a key role in initiating Varroa''s reproductive cycle. This study focuses on differential expression of the genes involved in the biosynthesis of JH and ecdysone at six time points during the first 30 hr after cell capping in both drone and worker larvae of A. mellifera. This time frame, covering the conclusion of the honey bee brood cell invasion and the start of Varroa''s ovogenesis, is critical to the successful initiation of a reproductive cycle. Our findings support a later activation of the ecdysteroid cascade in honey bee drones compared to worker larvae, which could account for the increased egg production of Varroa in A. mellifera drone cells. The JH pathway was generally downregulated confirming its activity is antagonistic to the ecdysteroid pathway during the larva development. Nevertheless, the genes involved in JH synthesis revealed an increased expression in drones. The upregulation of jhamt gene involved in methyl farnesoate (MF) synthesis came into attention since the MF is not only a precursor of JH but it is also an insect pheromone in its own right as well as JH‐like hormone in Acari. This could indicate a possible kairomone effect of MF for attracting the mites into the drone brood cells, along with its potential involvement in ovogenesis after the cell capping, stimulating Varroa''s initiation of egg laying.     

Seasonal differences in methyl farnesoate esterase activity in tissues of the spider crab Libinia emarginata

Summary

Methyl farnesoate (MF), an unepoxidated form of insect JH III, is present in Crustacea. MF is synthesized by the mandibular organs and is degraded to fomesoic acid (FA) by peripheral tissues. In this study we investigated MF degradation by esterases in hepatopancreas, ovary, testes and hemolymph of the spider crab Libinia emarginata collected at different times of the year to determine seasonal differences. The conversion of MF to FA varied among the tissues. In the summer, the hepatopancreas showed the greatest esterase activity (52.8% conversion in females and 59.16% in males), and it was twice as high (28.86%) in ovaries than in the testes (12.16%), but was low in the hemolymph of both sexes (10.84% in males, and 6.97% in females). In the fall, the conversion of MF to FA was significantly reduced in all tissues (ovary 8.55%, testes 6.21%, hepatopancreas 10.22%, hemolymph 3.96%). Eyestalk ablation of animals in the fall restored MF esterase activity to summer levels. When tissues from these animals were incubated with OTFP, a specific inhibitor of JH esterase, MF metabolism was significantly reduced. These results suggest that MF esterase activity depends on direct induction by MF, and its degradation is by a specific esterase(s).     

Studies on the de novo synthesis of juvenile hormone III and methyl farnesoate by isolated corpora allata of adult female Gryllus bimaculatus

Activity of the corpora allata (CA) in vitro of adult female Gryllus bimaculatus was studied following incorporation of radioactivity from [2-¹⁴C]acetate and l-[methyl-³H]methionine into juvenile hormone III (JH III) and its immediate precursor methyl farnesoate (MF). Spontaneously active glands from females reared at 27°C utilized exogenous labelled acetate extensively for synthesis of MF and JH III (incorporation 80–84% at 2 mM acetate). 10⁻⁷ to 10⁻⁵ M exogenous JH III in the incubation medium had no effect on the rate of JH biosynthesis in spontaneously active glands. At 10⁻⁴ M JH III incorporation of acetate into JH III was reduced. The amount of MF was also lowered. JH III treatment (10⁻⁸–10⁻⁶ M) of spontaneously inactive glands led to an increase in the amount of MF. This increase was due to a de novo synthesis. Exogenous farnesol (20–200 μM) increased JH III biosynthesis and the amount of MF, but suppressed [2-¹⁴C]acetate incorporation. Dilution of the endogenous precursors is probably the most important cause of this suppression. As shown by the abnormally high MF levels in farnesol treated glands, epoxidation seems to be a rate-limiting step under certain experimental conditions.     

Juvenile hormone biosynthesis by corpus cardiacum-corpus allatum complexes of larval Lymantria dispar

• 1.1. A radiochemical assay was used to examine juvenile hormone (JH) synthesis and secretion in vitro by incubating two pairs of larval corpus cardiacum-corpus allatum complexes (CC-CA) from, Lymantria dispar, in 50 μl of osmotically balanced Grace's medium containing 1 μC1 [³H-methyl]-methionine for 6 hr.
• 2.2. For CC-CA of fourth instar female larvae, maximal incorporation of ³H-methyl was 0.15 pmol/pr/hr between days 2 and 3. High pressure liquid chromatographic (HPLC) analysis suggested that the biosynthetic products are mainly JH III with a little JH II at times.
• 3.3. For CC-CA of last instar female larvae, incorporation of ³H-methyl was 0.48 pmol/pr/hr at the beginning of the stadium and decreased to negligible levels by day 10. HPLC analysis suggested that CC-CA of last instar larvae produced only JH III. Volume increases in CA during the last instar were associated with declining activities of JH secretion.
• 4.4. Comparisons of maximal rates of ³ H-methyl incorporation by each unit volume of CA revealed that in the last instar each unit volume (μm³) of glandular tissue secreted 50% more JH than in the fourth instar.