Induction and regulation of juvenile hormone esterases during the last larval instar of the cabbage looper, Trichoplusia ni

Juvenile hormone esterase titres were monitored in gate I and gate II last instar larvae of Trichoplusia ni using JH III as substrate. Two peaks of activity were observed for both gate I and gate II larvae, although the first and second juvenile hormone esterase peaks for the gate II larvae are extended and delayed one day, respectively. Head or thoracic ligations before the prepupal stage lower or block the appearance of both esterase peaks. Juvenile hormone I and II, as well as homo and dihomo juvenoids can induce the second juvenile hormone esterase peak in both normal and ligated larvae, and increase the esterase titre during the first peak in nonligated larvae. Induction of the juvenile hormone esterases is possible in non-ligated larvae as soon as the moult to the last instar has occurred and in ligated larvae as soon as the first esterase peak has started to decline. Distinct mechanisms of regulation are present for the first and second juvenile hormone esterase peaks. Juvenile hormone does not appear to be involved in regulating its own metabolism by directly inducing the first esterase peak; however, evidence is consistent with a brief burst of juvenile hormone which occurs prior to pupation inducing the production of the second peak of juvenile hormone esterase activity.     

Characterization and the developmental role of plasma juvenile hormone esterase in the adult cabbage looper,Trichoplusia ni

Juvenile hormone (JH) esterase was characterized from the plasma of adult females of the cabbage looper, Trichoplusia ni, and compared with that present in 4th and 5th instar larvae. Ester hydrolysis was the principal route of JH metabolism. Gel filtration of plasma resolved a single peak of JH esterase which was distinct from that of the α-naphthyl acetate (α-NA) esterase activity. The JH esterase apparent molecular weight was 62,000 in prepupae and virgin, female adults and 69,000 in 2-day-old 4th instar larvae. Broad range isoelectric focusing of plasma of prepupae and adults resolved a major peak of activity at pH 5.5 with a minor peak of activity at pH 6.1 and in 4th instar larvae at pH 5.45 and 5.8, respectively. By this method JH esterase was resolved from the α-NA esterase activity. The plasma of prepupae and adults metabolized JH I at about twice the rate of JH III. JH esterase activity from adult plasma was more stable than the α-NA esterase activity. Adult JH esterase activity was insensitive to inhibition by O,O-diisopropyl phosphorofluoridate in contrast to that of the α-NA esterase activity. Mated females oviposited 8 times more eggs than virgin females to 10 days after emergence. The total haemolymph protein content of virgin females remained high throughout the period of study whereas mated females showed a significant decline beginning on day 4. JH esterase activity remained unchanged in virgins whereas it declined drastically in mated females. The α-NA esterase activity declined to low levels shortly after emergence in both groups. JH and α-NA esterase activity was not affected by the application of the juvenoid, (RS)-methoprene. The present study provides evidence of a functional role for JH esterase in JH metabolism and reproduction in adult T. ni. JH esterases in the adult were identical to that of prepupae by the methods described above.     

Approaches to the purification of the juvenile hormone esterase from the cabbage looper,Trichoplusia ni

Several approaches to the purification of juvenile hormone (JH) esterase from second-day last-instar larvae of Trichoplusia ni were taken, including: ammonium sulphate precipitation, polyethylene glycol precipitation, hydrophobic interaction chromatography, anion exchange chromatography, and gel filtration chromatography. The most successful procedure involved a combination of polyethylene glycol precipitation with anion exchange chromatography on DEAE Sephacel which yielded a 134-fold purification of juvenile hormone esterase. When this preparation was subjected to semi-preparative electrophoresis followed by isoelectric focusing on a polyacrylamide slab gel, a single band of apparently homogeneous enzyme was obtained. Juvenile hormone esterase activity was unstable after electrophoresis and isoelectric focusing. The stability of juvenile hormone esterase activity in a water solution is influenced by protein concentration and by agents protecting sulphydryl groups. The results of this study support the hypothesis that a single protein is responsible for the majority of the JH hydrolysis catalyzed by haemolymph from the larvae of T. ni used in this study.     

Haemolymph juvenile hormone esterase during the life cycle of the tobacco hornworm,Manduca sexta (L.)

Juvenile hormone (JH) esterase activity was found in the plasma of larvae, pupae and adults of wild-type tobacco hornworms, Manduca sexta. There was a single peak of plasma JH esterase activity approx. 28 h prior to ecdysis in each instar from the second through the fourth instar and a peak of activity prior to both wandering and pupation in the fifth (last) instar. JH esterase activity was high in newly formed male and female pupae but declined to minimal levels by day 1 of the pupal stage. For the remainder of the pupal period, activity was at background levels. JH esterase activity increased again in newly emerged, virgin male and female adults but declined and remained at a low level 1 day after emergence through death. Gel filtration analysis of larval, pupal and adult plasma resolved a single peak of JH esterase activity with an apparent molecular weight of 66,000. However, isoelectric focusing revealed three forms with isoelectric points of 5.5, 5.8 and 6.1. These isoelectric forms were also found in black and white mutants of last instar M. sexta and in purified JH esterase from wild-type larvae. The plasma JH esterase activity metabolized JH I 2–3 times faster than JH III and was sensitive to inhibition by octylthio-1,1,1-trifluoro-2-propanone and insensitive to O,O-diisopropyl phosphorofluoridate. Gel filtration, isoelectric focusing, substrate specificity and developmental studies suggest that the same JH esterases are found in the plasma of larvae, pupae and adults and appear to be different from general (α-NA) esterase.     

The occurrence of an adult reproductive diapause in the univoltine life cycle of the beech leaf mining weevil,Rhynchaenus fagi L.

Summary

Juvenile hormone (JH) and α-naphthyl acetate (α-NA) esterase activity was measured on a daily basis during embryogenesis of the house cricket, Acheta domesticus. In eggs dissected from the lateral oviducts and embryos through blastokinesis, there were elevated levels of nonspecific JH esterase activity. The JH esterase activity could not be resolved from the α-NA esterase activity by gel filtration chromatography and the metabolism of both substrates was inhibited equally by 0,0-diisopropyl phosphorofluoridate (DFP). From blastokinesis through egg hatch, the JH esterase activity was maintained at relatively low levels and was resolved from the α-NA esterase activity by gel filtration. The α-NA esterase activity was inhibited by DFP while the JH esterase activity was relatively unaffected. Low JH titers in eggs must be maintained through blastokinesis for normal development. Elevated JH esterase activity in eggs during this period appears to have a functional role in the metabolism of maternal JH in the egg.     

In vivo fluctuation of JH,JH acid,and ecdysteroid titer,and JH esterase activity,during development of fifth stadium Manduca sexta

Juvenile hormone (JH), JH acid, and ecdysteroid titer, and JH esterase activity, were measured in hemolymph from synchronous last stadium larvae of Manduca sexta. JH and JH acids were identified and quantified by GC-MS: JH I and II (and the corresponding acids) were the predominant JH homologs detected in males or females. Maximum levels of JHs and JH acids were observed just following ecdysis to the fifth (last) stadium (day 0, 0 hr) and at the prepupal stage (day 6–day 7). JH titer (≥ 1 ng JH I or II/ml) was higher than JH acid titer (∼0.7 ng JH I acid or JH II acid/ml) in very early fifth stadium larvae. However, this was reversed at the prepupal stage when higher titers of JH acids than JH were observed. JH acid titer began to rise prior to JH titer at the prepupal stage. JH esterase activity rose significantly only after JH or JH acid titers had begun to decline; maximum JH esterase activity was observed at day 3 and day 8. Ecdysteroid titer (measured by RIA) decreased during the last larval molt to a low level by day 0 (0 hr) and to undetectable levels at day 0 (12 hr) of the fifth stadium, by which time JH and JH acid levels had also declined substantially. Just prior to wandering, a small ecdysteroid peak was noted and a slightly elevated level of ecdysteroid was maintained for a further 2 days before a surge in ecdysteroid titer occurred at the prepupal stage, in synchrony with JH and JH acid titer maxima. There was no sexual dimorphism in timing or magnitude of JH, JH acid, and ecdysteroid titer or JH esterase activity.     

A Biochemical Evidence of the Inhibitory Effect of Diflubenzuron on the Metamorphosis of the Silkworm,Bombyx mori

Diflubenzuron (DFB) has been known to prevent metamorphosis of silkworm, Bombyx mori, from larval to pupal stage at low dose exposure. To explain this inhibitory action of DFB, a hypothesis was raised that DFB acts like juvenile hormone (JH) or DFB inhibits JH esterase to increase endogenous JH titer. A JH bioassay using isolated abdomen clearly indicates that DFB does not act as JH analog because DFB did not induce vitellogenesis in the isolated female abdomen, while endogenous JHs did significantly. General esterase activities in hemolymph were lower in DFB-treated fifth instar larvae than in the control larvae, but there was no difference between fat body esterase activities in both groups. Two hemolymph esterases (‘E1’ and ‘E2’) of the fifth instar larvae were separated and visualized by α-and β-naphthyl acetate. From in vitro incubation experiment, the cathodal esterase (‘E1’) was sensitive to DFB at its nanomolar range. Considering the fact that early fifth instar larvae have high level of JH esterase in the hemolymph, these results suggest that DFB inhibit larval to pupal metamorphosis by blocking JH degradation, which increases endogenous JH titer especially at the critical period when the larvae determine metamorphic development at the following molt.     

保幼激素的代谢

保幼激素的代谢由保幼激素酯酶、保幼激素环氧水解酶和保幼激素二醇激酶等共同催化完成。在这些代谢酶的作用下,保幼激素代谢成保幼激素酸、保幼激素二醇、保幼激素酸二醇和保幼激素二醇磷酸。作者总结了保幼激素代谢的研究方法;按实验室和昆虫种类为线索,归纳和概括了每一种保幼激素代谢酶的研究进程;对保幼激素酯酶和保幼激素环氧水解酶作了序列分析;最后对保幼激素的代谢研究进行了展望。     

Genetics of esterases inDrosophila. IX. Characterization of the JH-esterase inD. virilis

The kinetic characteristics of the main isozymes of Drosophila virilis esterase were studied and Km values of esterase-2, -4, and -6 and p-esterase for alpha- and beta-naphthyl acetate were obtained. Juvenile hormone (JH) was shown to inhibit the p-esterase activity when in competition with beta-naphthyl acetate and the general esterase inhibitor, diisopropylphosphofluoridate (DFP), was shown to inhibit all the components of the D. virilis esterase patterns except p-esterase. While studying the changes of p-esterase activity in D. virilis ontogenesis, the increase in p-esterase activity in the wandering larvae, prepupae, and early pupae was found to correlate with a decrease in JH titer at these stages. The decrease in JH level in a temperature-sensitive lethal mutant larvae of D. virilis at high temperatures was shown to correlate with increased p-esterase activity. These results confirm that p-esterase of D. virilis is JH-esterase.     

A whole genome screening and RNA interference identify a juvenile hormone esterase-like gene of the diamondback moth,Plutella xylostella

Juvenile hormone (JH) plays a crucial role in preventing precocious metamorphosis and stimulating reproduction. Thus, its hemolymph titer should be under a tight control. As a negative controller, juvenile hormone esterase (JHE) performs a rapid breakdown of residual JH in the hemolymph during last instar to induce a larval-to-pupal metamorphosis. A whole genome of the diamondback moth (DBM), Plutella xylostella, has been annotated and proposed 11 JHE candidates. Sequence analysis using conserved motifs commonly found in other JHEs proposed a putative JHE (Px004817). Px004817 (64.61 kDa, pI = 5.28) exhibited a characteristic JHE expression pattern by showing high peak at the early last instar, at which JHE enzyme activity was also at a maximal level. RNA interference of Px004817 reduced JHE activity and interrupted pupal development with a significant increase of larval period. This study identifies Px004817 as a JHE-like gene of P. xylostella.     

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.     

Characterization of affinity-purified juvenile hormone esterase from Trichoplusia ni

Juvenile hormone (JH) esterase was purified greater than 1000-fold in one step from hemolymph and whole larval homogenates from the last larval instar of Trichoplusia ni to give a single diffuse band that migrates at Mr = 64,000 on sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The purification was based on an affinity chromatography procedure that employs trifluoromethyl ketone ligands. Isoelectric focusing of the purified preparations resulted in multiple bands that coincided to all significant hydrolysis of juvenile hormone detected in this manner. Kinetic experiments using optically pure enantiomers of JH II as substrates showed the two main electromorphs of JH esterase from the hemolymph to have apparently identical kinetic parameters as well as a similar capability to distinguish between substrates that differ in the orientation of the epoxide moiety of JH. However, the enzyme could hydrolyze esters lacking the JH structure. The proteins were shown to be monomers and to have asparagine-linked oligosaccharides, most likely of hybrid structure. Immunochemical and other evidence showed that the affinity-purified proteins were responsible for all significant JH esterase activity during periods of rapid esterolysis in vivo.     

Isolation of juvenile hormone esterase and its partial cDNA clone from the beetle, Tenebrio molitor

Juvenile hormone esterase (JHE) plays an essential role in insect development. It is partially responsible for the clearance of juvenile hormone (JH) which regulates various aspects of insect development and reproduction. Because of its role in regulating JH titer, this enzyme has been targeted for development of biologically-based insecticides. JHE was partially purified from the beetle, Tenebrio molitor, using a transition state analog as the affinity ligand. Two forms of JHE were characterized by activity analysis, isoelectric focusing, two-dimensional SDS-PAGE and N-terminal sequence analysis. The esterase is associated with two proteins of sizes 71 and 150 kDa, both of which are active on JH III. A partial cDNA clone for the enzyme was isolated based on the sequence of N-terminal and internal peptides. Its sequence indicates that JHE from T. molitor and Heliothis virescens may have a common origin.     

Factors influencing juvenile hormone esterase activity in the wax moth, Galleria mellonella

The effects of juvenile hormone, antiallatotropins, selected surgical procedures and starvation on the juvenile hormone esterase levels in Galleria larvae and pupae were investigated. JH reduced JH esterase activity in larvae but induced the enzyme in 1-day-old pupae. In vitro studies confirmed that the peak of synthesis and/or release of JH esterase from the fat body of last instar larvae occurred 4 days after ecdysis. These studies also showed that fat body from JH-treated larvae released much less enzyme than controls. Antiallatotropins, precocene 2 and ZR 2646 also reduced JH esterase levels in larvae, but ZR 2646 induced JH esterase in pupae. In starved larvae, JH esterase did not increase during the first five days. A minimum of 36 hr of feeding was necessary for the larval esterase activity to increase on schedule on day 4 of the last larval stadium. When day-l larvae were ligated behind the head or the prothorax, they had lower JH esterase levels and yet showed a slight increase in the enzyme when the larvae reached the age of 4 days. The significance of these results is discussed in relation to the possible control of esterase activity during metamorphosis.     

Juvenile hormone metabolism in the plasma,integument, midgut,fat body,and brain during the last instar of the tobacco hornworm,Manduca sexta (L.)

Juvenile hormone (JH) III esterase and JH III epoxide hydrolase activity was found in the integument, midgut, fat body, and brain during last instar development of the tobacco hornworm, Manduca sexta. JH esterase activity was primarily located in the cytosol in these tissues while the majority of the JH epoxide hydrolase activity was found in the microsomes. A prewandering (on day 3) and postwandering (on day 8) peak in plasma JH III esterase activity occurs in the last instar of gate I M. sexta. The JH esterase activity profile in integument, midgut, fat body, and brain followed a similar pattern to that of the plasma. The only exception to this was the absence of the postwandering, prepupal (on day 8) JH esterase peak in the fat body. The topical application of the juvenoid, (RS)-methoprene, failed to induce fat body JH esterase activity but increased activity in the plasma, integument, midgut, and brain in M. sexta prepupae. These results indicate that the source of plasma JH esterase activity is not always the fat body as previously hypothesized. The developmental profile of tissue JH epoxide hydrolase activity was also similar to that of JH esterase suggesting that both enzymes may be regulated partly by the same factors and that JH epoxide hydrolase may also have an important, previously unrecognized functional role in JH regulation and insect metamorphosis. Multiple isoelectric forms of tissue-specific JH esterases and JH epoxide hydrolases were found in integument, midgut, fat body, and brain. The JH esterases in these tissues had isoelectric points more acidic than that for plasma. Tissue α-naphthyl acetate esterase, developmental profiles, and inhibitor sensitivity to 3-(octylthio)-1,1,1-trifluoropropan-2-one differed significantly from that for JH esterase, suggesting that they represent different enzymes. ©1992 Wiley-Liss, Inc.     

Juvenile hormone action on locust fat body

Production of vitellogenin (Vg) in fat body of adult female Locusta migratoria is abolished by removal or inactivation of the corpora allata and restored by administration of (RS)-methoprene. Juvenile hormone III injection alone has little effect, but when it is injected together with the JH esterase inhibitor OTFP, active Vg synthesis is induced. This supports the assumption that methoprene acts in place of the natural hormone in this system. When fat body from vitellogenic females is maintained in synthetic medium for 48 hr, the proportion of Vg in the secreted protein drops greatly, but when methoprene is present in the medium the proportion of Vg is sustained. When fat body from JH-withdrawn locusts, in which Vg synthesis has declined to zero, is cultured with methoprene, Vg synthesis is re-induced. These results show that the JH analog can act directly on locust fat body to bring about expression of the Vg genes. Experiments to optimize JH action on fat body in vitro are continuing.     

Effects of the anti hormone-hormone mimic ETB on the induction of insect juvenile hormone esterase in Trichoplusia ni.

Juvenile hormone (JH) esterases can be artificially induced to appear in the hemolymph of last instar larvae of the lepidopterous insect $\text{Trichoplusia}$$\text{ni}$ (Noctuidae) by topical treatment with JH I, JH II, or dihomo branched juvenoids. ETB (ethyl-4-[2-(t-butylcarbonyloxy) butoxy] benzoate; ZR-2646) at high doses is a weak inducer of JH esterase (JHE). However, at doses of ETB that induce only low levels of JHE activity, ETB will block the JHE induction caused by the dihomo juvenoid epofenonane and at higher doses will reduce the induction caused by JH I or JH II. ETB is not a JHE inhibitor; rather, it appears to be acting as a JH agonist/antagonist in normal larvae and in isolated abdomens. These effects of ETB on JHE induction may illustrate a new mode of action of anti-JH's.