Identification and quantification of juvenile hormones from different developmental stages of the cockroach Nauphoetacinerea

By the combined use of high-pressure liquid chromatography, $\text{Galleria}$ bioassay and gas chromatography/ chemical ionization/mass spectrometry we were able to isolate and identify the three known natural juvenile hormones (JHs) from haemolymph extracts of larval and adult females of the cockroach $\text{Nauphoeta}$$\text{cinerea}$. This is the first demonstration of the simultaneous occurrence of the three JHs in the same insect and the first time JH I and II have been identified in a hemimetabolous insect. Quantitative investigations show that the composition of the three JHs is different at different developmental stages. The haemolymph of larvae contains a high percentage of JH I and II, whereas the haemolymph of adult females in the oocyte maturation stage contains mostly JH III. This suggests more juvenilizing functions for JH I and II and more gonadotropic functions for JH III.     

Influence of the braconid Glyptapanteles liparidis on the juvenile hormone titer of its larval host,the gypsy moth,Lymantria dispar

The increase in the juvenile hormone (JH) III titer in the hemolymph of Lymantria dispar larvae that were parasitized by the endoparasitoid braconid, Glyptapanteles liparidis, during the host's premolt to third instar, coincided with the molt of the parasitoid larvae to the second instar between day 5 and 7 of the fourth host instar. It reached a maximum mean value of 89 pmol/ml on day 7 of the fifth instar while it remained below 1 pmol/ml in unparasitized larvae. Only newly molted fifth instar hosts showed a low JH III titer similar to that of the unparasitized larvae. JH II, which is the predominant JH homologue in unparasitized gypsy moth larvae, also increased relative to controls in the last two samples (days 7 and 9) from parasitized fourth and fifth instars. Compared to unparasitized larvae, a generally reduced activity of JH esterase (JHE) was found in parasitized larvae throughout both larval stages. The reduction in enzyme activity at the beginning and at the end of each instar, when the JHE activity in unparasitized larvae was high, may be in part responsible for the increased JH II and JH III titers in parasitized larvae. Ester hydrolysis was the only pathway of JH metabolism in the hemolymph of unparasitized and parasitized gypsy moth larvae as detected by chromatographic assays. © 1996 Wiley-Liss, Inc.     

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.     

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

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

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 role of juvenile hormone esterase in terminating larval feeding and initiating metamorphic development in Trichoplusia ni

This study shows, first, that when JH degradation by JHE is blocked with an inhibitor (EPPAT, O-ethyl-S-phenyl-phosphoramidothiolate), prothoracicotropic/ecdysone release/effects are postponed in the cabbage looper Trichoplusia ni (Hübner) (Noctuidae). Thus, JHE is an important component of JH degradation, implying that without normal degradation the JH titer will become abnormally high. Second, this accumulation of endogenous JH in EPPAT treated larvae results in an extra larval molt. Therefore, JHE is also important in the control of the nature of the molt, by controlling the JH titer. Third, this study demonstrates that EPPAT at proper doses is a viable probe for studying enzyme and hormone action in vivo without pharmacological artifacts.

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Résumé Cette étude indique d'abord que, lorsque la dégradation de l'hormone juvénile (JH) par la JHE est bloquée par un inhibiteur (EPPAT, O-éthyl-S-phényl-phosphoramidothiolate) les effets prothoracicotropiques—libération d'ecdysone—sont retardés chez Trichoplusia ni Hübner. Ainsi, la JHE est un élément important de la dégradation de JH, impliquant que sans une dégradation régulière, la teneur en JH deviendra anormalement élevée. Cette accumulation d'hormone juvénile endogène chez les larves traitées à l'EPPAT provoque de plus une mue larvaire supplémentaire. Par conséquent, JHE est importante aussi dans le contrôle de la nature de la mue, en déterminant la teneur en JH. Enfin, cette étude a montré que l'EPPAT à des doses appropriées est un moyen efficace pur étudier l'action hormonale in vivo sans artéfacts pharmaceutiques.

     

Juvenile hormone production by corpora allta of Tenebrio molitor in vitro

$\text{In vitro}$ organ cultures of corpora allata or corpora cardiaca-corpora allata complexes from $\text{Tenebrio molitor}$ were found to produce methyl-(2E, 6E)-(10R)-10, 11- epoxy-3, 7, 11 trimethyl-2, 6-dodecadienoate (JH III). No detectable JH I or II was produced. The hormone was identified by derivation, chromatography and mass spectral analysis. A ¹⁴C radiolabel was incorporated into the methyl carbon of the ester function from precursor L-[$\text{methyl}$-¹⁴C]-methionine added to the culture medium.     

The substrate specificity of juvenile hormone esterase from Manduca sexta haemolymph

Haemolymph of $\text{Manduca sexta}$ fifth instar larvae contains a high esterase activity capable of hydrolyzing $\text{Hyalophora cecropia}$ C₁₈ juvenile hormone (JH). In an attempt to characterize the substrate specificity of the enzyme (s) involved, dilute haemolymph was incubated $\text{in vitro}$ with a series of JH-analogs. Ethyl esters with or without the 10,11-epoxide group were hydrolyzed readily but isopropyl esters and the (2Z)-isomer of JH were not affected. Indirect evidence was obtained for the hydrolysis of aziridine analogs of JH. Correlations of these results to biological activities are discussed.     

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.     

The identification and biosynthesis of two juvenile hormones from the tobacco budworm moth (Heliothis virescens)

Brain-corpora cardiaca-corpora allata complexes from the tobacco budworm $\text{Heliothis virescens}$ produce both radiolabelled methyl (2E, 6E, 10Z)-10,11-epoxy-3, 11-dimethyl-7-ethyl-2, 6-tridecadienoate (JH I) and methyl (2E, 6E, 10Z)-10, 11-epoxy-3, 7, 11-trimethyl-2, 6-tridecadienoate (JH II) when cultured in medium containing L-[$\text{methyl}$−¹⁴C] methionine or sodium [1−¹⁴C] propionate. Degradative studies of the hormones derived from propionate show the specific incorporation of the latter into the homo-isoprenoid portions of these compounds.     

Synthesis and antitumor activity of 1-beta-D-arabinofuranosylcytosine conjugates of cortisol and cortisone.

Superior antitumor activity of 1-β-D-arabinofuranosylcytosine (ara-C) conjugates of prednisolone and prednisone against L1210 leukemic mice, based on ara-C content, has encouraged us to synthesize 5′-(cortisone-21-phosphoryl)-1-β-D-arabinofuranosylcytosine (I) and 5′-(cortisone-21-phosphoryl)-1-β-d-arabinofuranosylcytosine (II) by condensation of N⁴,2′,3′-triacetyl-1-β-d-arabinofuranosylcytosine 5′-monophosphate with cortisol and cortisone in the presence of N,N′-dicyclohexylcarbodiimide at room temperature followed by removing the acetyl groups in 2 N methanolic ammonia in 20% yield. The conjugates I and II inhibited the $\text{in}\text{vitro}$ growth of L1210 by 50% (ED₅₀) at 0.25 μM and 0.07 μM, respectively, while ara-C showed ED₅₀ 0.1 μM. However, the conjugates I and II exhibited 287% and 238% of $\text{T}\text{C}$ at 50 mg/kg/day × 5 doses against L1210 leukemic mice, respectively, while ara-C at 25 mg and 50 mg/kg/day × 5 gave the respective 127% and 110% of $\text{T}\text{C}$.     

Juvenile hormone (JH) esterase activity but not JH epoxide hydrolase activity is downregulated in larval Adoxophyes honmai following nucleopolyhedroviruses infection

Juvenile hormones (JHs) and ecdysteroids are critical insect developmental hormones. JH esterase (JHE) and JH epoxide hydrolase (JHEH) are JH-selective enzymes that metabolize JH and thus regulate the titer of JH. Baculoviruses are known to alter host endocrine regulation. The nucleopolyhedroviruses, AdhoNPV and AdorNPV, are known to have slow and fast killing activity against Adoxophyes honmai (Lepidoptera: Tortricidae), respectively. Here we found that when penultimate (4th) instar A. honmai are inoculated with AdhoNPV or AdorNPV, the mean survival time is 9.7 and 8.2 days, respectively. The larvae molted once but did not pupate. The AdhoNPV- or AdorNPV-infected larvae did not show a dramatic increase in JHE activity as was found in mock-infected larvae, instead they showed a marked decrease in JHE activity. In contrast, both viral infections had no effect on JHEH activity. In order to further characterize the JHE activity, the JHE-coding sequence of A. honmai (ahjhe) was cloned and confirmed to encode a biologically active JHE. Quantitative real-time PCR analysis of ahjhe expression in 4th and 5th instar A. honmai revealed that AdhoNPV and AdorNPV are able to reduce ahjhe expression levels.     

Correlations between juvenile hormone esterase activity,ecdysone titre and cellular reprogramming in Galleria mellonella

Juvenile hormone esterase (JHE) activity, ecdysone titre, and developmental competence of the epidermis were determined in last instar larvae and pupae of Galleria mellonella. Haemolymph JHE activity reaches a peak before increases are observed in ecdysone titre both during larval-pupal and pupal-adult metamorphosis. JHE activity is low during the penultimate larval instar although general esterase activity is relatively high. In last instar larvae two ecdysone peaks are noted after the increase in JHE activity. Furthermore, epidermal cell reprogramming occurs just after the increase in haemolymph JHE activity and possibly before the first increase in ecdysone titre. This was tested by injection of high doses of β-ecdysone into last instar larvae of different ages resulting in rapid cuticle deposition. Reprogramming occurred if the resulting cuticle was of the pupal type. These correlative observations may increase our understanding of the relative importance of an ecdysone surge in the absence of JH in reprogramming of the insect epidermis.     

The effect of juvenile hormone and its antagonists on JH esterase activity in Tenebrio molitor

The hemolymph juvenile hormone esterase (JHE) and general carboxyl esterase activities in Tenebrio molitor show independent development-associated changes during larval-pupal and pupal-adult metamorphoses. JHE activity was high in pharate pupae and early pupae. Unlike in lepidopteran pupae that have been studied thus far, JH had no effect on JHE activity in pupae and pharate adults of Tenebrio. A JH antagonist, ethyl 4,2,tert butyl carboxy n benzoate (ETB), and 20-hydroxyecdysone had no effect on JHE activity. These observations suggest that although JHE activity in Tenebrio is precisely regulated during larval-pupal metamorphosis, JH and molting hormone do not appear to be involved in its regulation and that the proximate cues that influence JHE activity in Tenebrio pupae are different from that of lepidopterans.

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Résumé Les activités JHE (estérase juvénile hormone) de l'hémolymphe et carboxyl estérase générale de T. molitor changent indépendamment du développement pendant les métamorphoses larve-nymphe et nymphe-adulte. L'activité JHE est élevée chez les prénymphe et les jeunes nymphes. Contrairement aux chrysalides de papillons, JH n'a pas d'effet sur l'activité JHE chez les nymphes et les préadultes de Tenebrio. Un antagoniste de JH, l'éthyl 4,2,tert butyl carboxy n benzoate (ETB), 20-hydroxyecdysone et le précocène 2-agent anti-allate chez plusieurs insectes-, n'ont aucun effet sur l'activité JHE. Ces observations suggèrent que, bien que l'activité JHE chez T. molitor soit ajustée avec précision pendant la métamorphose larvo-nymphale, JH et hormone de mue ne paraissent pas être impliquées dans sa régulation et que les signaux immédiats, qui influent sur l'activité JHE de la nymphe de T. molitor, diffèrent de ceux des Lépidoptères.

     

Control of juvenile hormone esterase activity in Galleria mellonella larvae

The juvenile hormone esterase (JHE) activity in Galleria mellonella larvae was measured after exposure to different experimental conditions that affect larval-pupal transformation. The data show that stimulation of production of JHE is closely coupled with the developmental signals that intiate larval-pupal metamorphosis. Injury, which delays pupation, delays the appearance of JHE activity if the larvae are injured within 48 hr after the last larval moult. Chilling of day-0 larvae induces a supernumerary larval moult and inhibits the appearance of JHE. However, JHE activity increases in chilled larvae when their commitment for an extra larval moult is reversed by starvation. Starvation is effective in reversing the commitment for an extra larval moult if commenced within 48 hr after chilling, thereby suggesting a critical period for that commitment. These data suggest that the stimulus for JHE synthesis and/or release occurs approximately within 48 hr after the last larval ecdysis. A series of studies involving implantation of brain, suboesophageal ganglion and fat body into chilled, as well as chilled and ligated larvae suggest that a factor from the brain is involved in stimulation or production of JHE in Galleria larvae.JH, which suppresses JHE activity in day-3, -5 and early day-6 Galleria larvae, stimulates the production of JHE in late day-6 larvae, suggesting that reprogramming in larval fat body may occur on day 6 of the last larval stadium.     

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.     

Steric factors involved in the action of glycosidases and galactose oxidase

α-(1→2)-$\text{L}\text{=}$-Fucosidase, β-$\text{D}\text{=}$-galactosidase and galactose oxidase are sterically hindered by certain types of branching in the oligosaccharide chains. 1) β-$\text{D}\text{=}$-Galactosidase will not cleave galactose when the penultimate sugar carries a sialic acid residue as in I. 2) Galactose Oxidase will not oxidize the galactose residue in trisaccharide I but will in II. Moreover, neither galactose nor $\text{N}$-acetylgalactosamine, glycosidically bound as in III, is susceptible to oxidation with galactose oxidase until the α-(1→2) linkage between them is cleaved by $\text{α-}\text{N}\text{-acetylgalactosaminidase}$. 3) α-(1→2)-$\text{L}\text{=}$-Fucosidase action is inhibited by $\text{α-(1→3)-}\text{N}\text{-acetylgalactosaminyl}$ or galactosyl residue, as in III and IV. Removal of the terminal sugars makes the fucosyl residue susceptible to fucosidase action.