Fungal Metabolism of trans-2-Octenoic Acid

Juvenile hormone esterases (JHEs) function in juvenile hormone (JH) degradation. In the silkworm, Bombyx mori, we have characterized authentic JHE (Bmjhe) and five other carboxyl/cholinesterase (CCE) genes (Bmcce-1 to -5) with GQSAG, a motif sequence of JHE. But none of the genes appeared to function in vivo as a JHE, except for Bmjhe. Recently it was reported that the GQSAG motif might be dispensable, and that the Thr-316 residue has functional significance for JHE activity. On the basis of these findings, we identified two novel JHE candidates, Bmcce-6 and Bmcce-7, that lack GQSAG but possess Thr-316. In the CCE phylogenetic tree, BmCCE-6 was close to the lepidopteran JHE cluster, while BmCCE-7 constituted the same cluster as pheromone-degrading esterases. The developmental expression profiles were different among Bmjhe, Bmcce-6, and Bmcce-7. None of the proteins hydrolyzed JH in vitro. Our results suggest that only one CCE (BmJHE) functions as JHE in the silkworm.     

Only one esterase of Drosophila melanogaster is likely to degrade juvenile hormone in vivo

Previously we identified juvenile hormone esterase (JHE) from Drosophila melanogaster by the criteria that it showed both appropriate developmental expression and kinetics for juvenile hormone (JH). We also noted three further esterases of D. melanogaster with some JHE-like characteristics, such as a GQSAG active site motif, a particular amphipathic helix, or close phylogenetic relationship with other JHEs. In this study, these JHE-like enzymes were expressed in vitro and their kinetic parameters compared with those of the previously identified JHE. Despite considerable phylogenetic distance between some of the esterases, they could all hydrolyse racemic JHIII. However, only the previously identified JHE had kinetic parameters (K(M) and k(cat)) towards various forms of JH (racemic or individual isomers of JHIII, JHII, JHI, and methyl farnesoate) consistent with a physiological role in JH regulation. Furthermore, only this JHE showed a preference for artificial substrates with acyl chain lengths similar to that of JH. This suggests that there is probably only one physiologically functional JHE in D. melanogaster but multiple esterases with JH esterase activity. Genomic comparisons of the selective JHE across 11 other Drosophila species showed a single orthologue in 10 of them but Drosophila willistoni has 16 full-length copies, five of them with the GQSAG motif and amphipathic helix.     

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.     

Expression pattern of enzymes related to juvenile hormone metabolism in the silkworm, <Emphasis Type="Italic">Bombyx mori</Emphasis> L.

The physiological balance of juvenile hormone (JH) in insects depends on its biosynthesis and degradation pathway. Three key enzymes namely, juvenile hormone esterase (JHE), juvenile hormone epoxide hydrolase (JHEH) and juvenile hormone diol kinase (JHDK) are required for degradation in insects. Our present results showed that JHE and JHEH exhibited expression in almost all the tissues. This indicated that JHE and JHEH might degrade JH simultaneously. In addition, the highest levels of JHDK were observed in the midgut, with trace level being found in the malpighian tubule and haemocytes. Since the midgut is a digestive organ and not a JH target, it was hypothesized that both JHE and JHEH hydrolyzed JH to JH diol (JHd) which was then transported to midgut and hydrolyzed further by JHDK, to be finally excreted out of the body. Also the expression studies on JH degradation enzymes in different tissues and stages indicated that the activities of the three enzymes are specific and coincident with the JH functions in silkworm, Bombyx mori L.     

Depletion of juvenile hormone esterase extends larval growth in Bombyx mori

Two major hormones, juvenile hormone (JH) and 20-hydroxyecdysone (20E), regulate insect growth and development according to their precisely coordinated titres, which are controlled by both biosynthesis and degradation pathways. Juvenile hormone esterase (JHE) is the primary JH-specific degradation enzyme that plays a key role in regulating JH titers, along with JH epoxide hydrolase (JHEH) and JH diol kinase (JHDK). In the current study, a loss-of-function analysis of JHE in the silkworm, Bombyx mori, was performed by targeted gene disruption using the transgenic CRISPR/Cas9 (clustered regularly interspaced short palindromic repeats/RNA-guided Cas9 nucleases) system. Depletion of B. mori JHE (BmJHE) resulted in the extension of larval stages, especially the penultimate and ultimate larval stages, without deleterious effects to silkworm physiology. The expression of JHEH and JHDK was upregulated in mutant animals, indicating the existence of complementary routes in the JH metabolism pathway in which inactivation of one enzyme will activate other enzymes. RNA-Seq analysis of mutant animals revealed that genes involved in protein processing in the endoplasmic reticulum and in amino acid metabolism were affected by BmJHE depletion. Depletion of JHE and subsequent delayed JH metabolism activated genes in the TOR pathway, which are ultimately responsible for extending larval growth. The transgenic Cas9 system used in the current study provides a promising approach for analysing the actions of JH, especially in nondrosophilid insects. Furthermore, prolonging larval stages produced larger larvae and cocoons, which is greatly beneficial to silk production.     

Characterization and affinity purification of juvenile hormone esterase from Bombyx mori

Juvenile hormone esterase (JHE) from hemolymph of the silkworm moth Bombyx mori was characterized for substrate specificity and inhibitor sensitivity. B. mori JHE hydrolyzed the juvenile hormone surrogate substrate methyl n-heptylthioacetothioate (HEPTAT) more efficiently than p-nitrophenyl acetate and 1-naphthyl acetate substrates widely used to assay total carboxylesterase activity. B. mori JHE was sensitive to 3-octylthio-1,1,1-trifluoro-2-propanone (OTFP), which was developed as a selective inhibitor for lepidopteran JHE, and relatively insensitive to diisopropyl fluorophosphate (DFP), an inhibitor of serine esterases but not of all JHEs. Affinity purification with a trifluoromethyl ketone ligand was more efficient for purification of B. mori JHE than DEAE ion exchange chromatography.     

Characterization of hemolymph juvenile hormone esterase from Lymantria dispar

A major peak of juvenile hormone esterase (JHE) activity approaching 330 nmol JH III hydrolyzed/min/ml of hemolymph was observed during the last larval growth stage in Lymantria dispar. A smaller peak of JHE occurred 3–5 days after pupation. The gypsy moth JHE was purified from larval hemolymph using a classical approach. A specific activity of 766 units per mg of protein and a K_m of 3.6 × 10⁻⁷ M for racemic JH III and the (10R, 11S) enantiomer of JH II was determined for the purified enzyme. The 62 kDa esterase was insensitive to inhibition by O,O-diisopropyl phosphorofluoridate (DFP), or by phenylmethylsulfonyl fluoride (PMSF). Two forms of JHE isolated by RP-HPLC were indistinguishable by HPLC tryptic peptide mapping and share an identical N-terminal amino acid sequence. Polyclonal antisera raised against gypsy moth enzyme cross-reacted with JHE from Trichoplusia ni but not with JHE from Manduca sexta. A weak cross-reactivity was observed with JHE from Heliothis virescens. Forty amino acid residues of the N-terminus were placed in sequence. The N-terminal sequence of JHE from L. dispar showed little homology to the sequence of JHE from H. virescens. The immunological and structural data support the conclusion that markedly different esterases, which catalyze the hydrolysis of juvenile hormone, are present in the hemolymph of different Lepidoptera.     

Juvenile hormone (JH) esterase of the mosquito Culex quinquefasciatus is not a target of the JH analog insecticide methoprene

Juvenile hormones (JHs) are essential sesquiterpenes that control insect development and reproduction. JH analog (JHA) insecticides such as methoprene are compounds that mimic the structure and/or biological activity of JH. In this study we obtained a full-length cDNA, cqjhe, from the southern house mosquito Culex quinquefasciatus that encodes CqJHE, an esterase that selectively metabolizes JH. Unlike other recombinant esterases that have been identified from dipteran insects, CqJHE hydrolyzed JH with specificity constant (k(cat)/K(M) ratio) and V(max) values that are common among JH esterases (JHEs). CqJHE showed picomolar sensitivity to OTFP, a JHE-selective inhibitor, but more than 1000-fold lower sensitivity to DFP, a general esterase inhibitor. To our surprise, CqJHE did not metabolize the isopropyl ester of methoprene even when 25 pmol of methoprene was incubated with an amount of CqJHE that was sufficient to hydrolyze 7,200 pmol of JH to JH acid under the same assay conditions. In competition assays in which both JH and methoprene were available to CqJHE, methoprene did not show any inhibitory effects on the JH hydrolysis rate even when methoprene was present in the assay at a 10-fold higher concentration relative to JH. Our findings indicated that JHE is not a molecular target of methoprene. Our findings also do not support the hypothesis that methoprene functions in part by inhibiting the action of JHE.     

Characterization of the esterase isozymes of Ips typographus (coleoptera,scolytidae)

Four esterase isozymes hydrolyzing α-naphthyl acetate (α-NA) were detected screening whole body homogenates of larvae and adults of Ips typographus by electrophoresis. Two of the four isozymes (isozymes 3 and 4) were not detected by α-NA staining in the pupal stage, but topical application of juvenile hormone III (JH III) on the pupa induced these isozymes. The JH esterase (JHE) activity on the gel was associated with the proteins of isozyme 2. The compounds OTFP, PTFP, and DFP inhibited this catalytic activity of isozyme 2 on the gel at low concentrations, whereas the proteins of isozyme 3 and 4 were affected only at higher concentrations. A quantitative developmental study was performed to characterize which of the esterases hydrolyzed JH III, using a putative surrogate substrate for JH (HEXTAT) and α-NA. The I₅₀ of several esterase inhibitors and the JH metabolites were also defined. All findings supported the results that a protein associated with isozyme 2 is catabolizing JH and that isozymes 3 and 4 are the main contributors to the general esterase activity on α-NA. The JHE from Tenebrio molitor was purified by affinity chromatography. Although the recovery was low, an analytical isoelectric focusing gel showed that the JHE activity of the purified enzyme. T. molitor cochromatographed at the same pl as the JHE activity of I. typographus. Arch. Insect Biochem. Physiol. 34:203–221, 1997. © 1997 Wiley-Liss, Inc.     

Juvenile hormone catabolism and oviposition in the codling moth, Cydia pomonella, as functions of age, mating status, and hormone treatment.

In vitro catabolism of juvenile hormone (JH) in haemolymph of adult female Cydia pomonella was ascribed mainly to juvenile hormone esterase (JHE) activity. No significant differences were noted between virgin and mated females 0-96 h post-emergence. Changes in JHE activity did not appear dependent upon fluctuations in JH titre; conversely, changes in JHE activity could not explain the changes in JH titres. Maximal JHE activity was recorded at 24 h (331.47 +/- 47.25 pmol/h/microl; 355.93 +/- 36.68 pmol/h/microl, virgin; mated insects, respectively) and preceded the peak in JH titres at 48 h. Topical application of JH II (10 ng-10 microg) or fenoxycarb (50 ng) enhanced JHE activity up to 640 and 56%, respectively. Treatment upon emergence with 10 microg JH II induced enzymic activity for less than 24 h, and when 10 microg JH II or 50 ng fenoxycarb were applied, circulating JH titres returned to control levels within 24 h. Oviposition was highly sensitive to exogenous JH and declined significantly with dosages >100 pg. To allow a degree of oocyte maturation before JH treatment, the hormone was administered at 6, 12, 24, or 48 h post-emergence and/or females were mated. Neither measure "protected" the system; oviposition declined immediately after JH application.     

Distinctive structural and kinetic properties of an unusual juvenile hormone-hydrolyzing esterase

The insect juvenile hormone specific esterases (JHEs), related to acetylcholinesterases but exhibiting substrate specificity for juvenile hormone (JH), are essential enzymes for normal insect development, making them attractive targets for biorationally designed, environmentally safe pesticides. We examine here a new enzyme, JHER, related to, but yet structurally, biochemically, and kinetically distinct from, the classical JHE. Both classical JHE and baculovirus-expressed JHER hydrolyze JH show disproportionately higher catalytic rates at higher substrate concentrations (in contrast to substrate inhibition reported for acetylcholinesterase) and are similarly inhibited by an organophosphate. However, JHER, which possesses an unusual cysteine residue at +1 to the catalytic serine, is less sensitive to trifluoromethyl ketone transition state analogs designed around the structure of JH. We propose a model in which JHER is expressed just prior to metamorphosis for hydrolysis of a JH-like substrate with hydrophobic backbone, a proximal ester, and a terminal expoxide or related substitution.     

Multiple forms of juvenile hormone esterase active sites in the hemolymph of larvae of Trichoplusia ni

Kinetic analysis was performed on the juvenile hormone (JH) esterase activity in the hemolymph of feeding, last instar larvae of Trichoplusia ni (Lepidoptera: Noctuidae). When the results were analyzed by several different graphical and regression procedures, all approaches yielded the same conclusion that at least two forms of JH esterase active sites exist in the hemolymph. The apparent Km for one site for JH I, II and III was 8.5 X 10(-8) M, and 6.6 X 10(-8) M, respectively. The Km for the other site for JH I, II and III was 6.6 X 10(-7) M, 7.6 X 10(-7) M, 40 X 10(-7) M, respectively. When hemolymph JHE activity was subjected to high resolution isoelectric focusing (IEF), two distinct large peaks of JHE activity were observed, with pIs of 5.3 and 5.5, as well as a small peak at pI 5.1. Separate kinetic analysis of the JHE activity in each peak showed that only the higher Km active site for each substrate was present (in the 10(-7) M range). These data necessitate a change in the current model for JHE in T. ni, and some other insects, which states that a single active site is responsible for most or all of the JH esterase activity in vivo. The data also explain the different estimates of the Km of JHE in T. ni obtained by different laboratories. Studies on the purification of, and the development of inhibitors for, JHE esterase must consider the role of both JHE forms and sites in regulation of T. ni metamorphosis.     

The interactions between juvenile hormone (JH), lipophorin, vitellogenin, and JH esterases in two cockroach species

For the cockroach species Leucophaea maderae and Periplaneta americana two major juvenile hormone (JH)-binding proteins have been identified: lipophorin (Lp) and vitellogenin (Vg). Each of these macromolecules binds JH with an approximate affinity of K(d) of 10 nM. In Leucophaea the concentration of Lp is augmented by JH during vitellogenesis at the same time when Vg is induced de novo. The circulating levels of each of Lp and Vg at mid-vitellogenesis are in the 10 microM range. Similar values have been determined for Periplaneta. Total JH concentrations (bound and free) can be as high as micromolar in Leucophaea. However, because of the large quantities of the two major JH-binding proteins and their high affinity for JH, we can assume that the amount of free (unbound) JH in circulation is extremely low (the actual values are not know).The JH esterases (JHEs) of the hemolymph in both cockroach species have been isolated by anion exchange chromatography. The JHEs of Leucophaea bound to the anion exchange resin more tightly than the JHE of Periplaneta. The V(max) of the Leucophaea esterases fluctuated by a factor of 2 to 3 during vitellogenesis. The K(m) values for the two distinct esterases of Leucophaea were similar (about 0.15x10(-6) M). On the other hand, k(cat) of the JHEs for Leucophaea at ovulation time was two to three times higher than earlier during vitellogenesis, i.e. 23.30 min(-l) compared to 6.20 min(-1). The JHE of Leucophaea is shown to bind JH III with high affinity: K(d)=3x10(-9) M. However, since there are only very small amounts of JH available for degradation (due to the binding to Lp and Vg), the quantitative removal of JH from circulation, and this includes the release of bound JH, is indeed slow, with a measured half-life of 6-8 h. Classical kinetic assumptions are not met in conditions where the enzyme concentrations exceed by far that of the available substrate. Nonetheless, we attempted to determine the initial velocity of JH hydrolysis under natural conditions, i.e. for undiluted hemolymph, by measuring the initial velocities of JH hydrolysis in serially diluted hemolymph and extrapolating to zero dilution. For in vivo conditions we estimated an initial velocity of JH hydrolysis of <0.1 fmol microl hemolymph(-1) min(-1), i.e. four to five orders of magnitude lower than that measured at substrate saturation in vitro.     

Homology model of juvenile hormone esterase from the crop pest, Heliothis virescens

Juvenile Hormone Esterase (JHE) plays an essential role in the development of insects since it is partially responsible for clearing juvenile hormone (JH), one of the hormones that is responsible for insect metamorphosis. JHE is a 60 kDa enzyme that selectively hydrolyzes the alpha/beta unsaturated ester of JH. Because of its pivotal role in insect development, we have targeted JHE for use as a biopesticide. In this study, we have constructed a homology-based molecular model of JHE from the agricultural crop pest, Heliothis virescens. JHE is a member of the alpha/beta hydrolase fold family of enzymes and was built according to two structures in the same family: acetylcholinesterase from Torpedo californica and lipase from Geotrichum candidum. Analysis of the active site region reveals extensive conservation between JHE and its templates. A surprise was the presence of a conserved Ser near the catalytic triad. Docking of JH III into the active site has provided insight into protein-substrate interactions that are corroborated by experimental observation. The model is being used as a predictive basis to design biopesticides. In this regard, we have identified a site on the protein surface that is suggestive of a recognition site for the putative JHE receptor.     

Juvenile hormone-specific esterases in the haemolymph of the tobacco hornworm, Manduca sexta

A new sensitive method for determining juvenile hormone (JH) hydrolysis has been developed which measures the release of tritiated methanol from JH labelled in the methyl ester group. Using this assay we investigated the interaction of JH with haemolymph esterases and haemolymph JH-binding protein. Haemolymph from fifth instar larvae of Manduca sexta contains two families of esterases which can be distinguished by their reactivity with diisopropylphosphorofluoridate (DFP). One group consists of general esterases which are capable of hydrolysing free JH but not JH complexed to the binding protein and are completely inhibited by low concentrations of DFP (10⁻⁴ M). The other group (JH-specific esterases), relatively DFP resistant, has little detectable general esterase activity but can hydrolyse JH bound to the binding protein as well as free JH. The major JH-esterase has a sedimentation coefficient of 4·98 S and a diffusion coefficient of 6·4 × 10⁻⁷ cm² sec⁻¹. The molecular weight calculated from these values is 6·7 × 10⁴. The general esterases are present throughout the larval stage, but the JH-specific esterases are barely detectable until the fourth day of the fifth instar when they suddenly appear at a high concentration. Since the general esterases cannot hydrolyse bound JH, one function of the binding protein is to protect JH during transport in the early instars, thus confirming that the binding protein is a true carrier of JH. In the late fifth instar prior to metamorphosis, however, JH-specific esterases appear in the haemolymph resulting in the hydrolysis of JH complexed to the carrier protein. Thus, by lowering JH titre, the JH-esterases play an important rôle in development in M. sexta.