The formation of the pupal cuticle by Drosophila imaginal discs in vitro

Mass-isolated imaginal discs of Drosophila melanogaster form a chitin-containing pupal procuticle In vitro. Optimal procuticle deposition occurs when the discs are incubated for 4–6 hr with 0.5–1.0 μg/ml of 20-hydroxyecdysone and then with less than 0.05 μg/ml of 20-hydroxyecdysone. The formation of the chitin-containing procuticle is demonstrated using three independent assays: with fluorescene-conjugated cuticle proteins that bind to chitin; by electron microscopy; by incorporation of [³H]glucosamine into a chitin fraction. Synthesis and deposition of pupal cuticle proteins are also demonstrated. Incorporation of [³H]glucosamine into chitin is sensitive to inhibitors of protein, RNA and chitin synthesis, but has little sensitivity to inhibitors of DNA synthesis, and dolichol-dependent glycosylation.     

Metabolism of ecdysteroid by testes of the tobacco budworm,Heliothis virescens

Testes from late last stage larvae of the tobacco budworm, Heliothis virescens, were incubated with [³H]ecdysone and [³H]cholesterol. [³H]Ecdysone was converted to six other major ecdysteroids, identified by cochromatography in reverse-phase high-pressure liquid chromatography (RPHPLC); four of them were verified by normal-phase HPLC. A highly polar fraction, moderately polar ecdysteroids (20,26-dihydroxyecdysone, 3-epi-20-hydroxyecdysone, and 20-hydroxyecdysone) and low-polarity ecdysteroids, including 2-deoxyecdysone, were detected after incubation with [³H]ecdysone. Compounds that reacted positively to antibodies to progesterone and testosterone were detected in the low-polarity fractions. Testes were incubated in fractions corresponding to each of the major ecdysteroid peaks derived from [³H]ecdysone metabolism. Although most of the radioactive ecdysteroid fractions were further metabolized to high- and low-polarity endpoints, 88% of the [³H]20-hydroxyecdysone peak apparently remained unmetabolized. 20-Hydroxyecdysone may be the primary ecdysteroid product of testes of H. virescens. [³H]Cholesterol was not metabolized to any appreciable extent.     

Metabolism of maternal ecdysteroid-22-phosphates in developing embryos of the desert locust,Schistocerca gregaria

The ecdysteroid composition of Schistocerca gregaria eggs at different stages of development was determined by analysis of ecdysteroids labelled maternally from [4-¹⁴C]cholesterol. At all stages studied, highly polar ecdysteroid derivatives predominated, but changes in their composition occurred between day 10 of development and hatching (day 17). During this period, polar conjugates of ecdysone-3-acetate and 3-epi-2-deoxyecdysone appeared together with ecdysteroid acids. At day 17, the polar conjugate of [¹⁴C]ecdysone-3-acetate represented 36% of the total conjugated steroids. Separate in vivo studies on the metabolism of [¹⁴C]ecdysteroid conjugates isolated from newly-laid eggs and consisting primarily of the 22-phosphates of ecdysone, 2-deoxyecdysone and 20-hydroxyecdysone showed that ecdysteroid phosphates could be hydrolysed to give primarily free ecdysone during embryogenesis. Developing eggs can metabolize [³H]ecdysone to ecdysonoic acid, 3-acetylecdysone-2-phosphate and to a lesser extent ecdysone-22-phosphate and 20-hydroxyecdysonoic acid. A polar conjugate of 20-hydroxyecdysone-3-acetate, possibly the 2-phosphate derivative, was detected as a minor metabolite of ecdysone. A scheme of the proposed pathways involved in the metabolism of ecdysteroid-22-phosphates in the developing eggs of S. gregaria is presented.     

Ecdysone metabolism and distribution during the pupal-adult development of Manduca sexta

The metabolism and distribution of endogenous ecdysone and injected [³H]ecdysone were studied during the pupal-adult development of Manduca sexta. Well-characterized antisera were used to detect and quantify endogenous metabolites by radioimmunoassay (RIA) following their separation by ion-suppressed reverse phase, and normal phase, high performance liquid chromatography. Identical chromatographic procedures were employed to determine the metabolic fate of the [³H]ecdysone in the haemolymph pool. These studies revealed the sequential appearance in the haemolymph and gut of progressively oxidized metabolites of ecdysone—hydroxylation at C-20 was followed by hydroxylation at C-26. The data are suggestive of both the induction of the steroid hydroxylases (oxidases) by substrate or other effector substances and the possible coordination of developmental events by ecdysteroids other than 20-hydroxyecdysone.In the haemolymph, two highly-polar conjugates of ecdysone were observed together with conjugates of the other free ecdysteroids, especially those hydroxylated at C-26. In contrast, relatively little 20-hydroxycdysone conjugate was detected in the insect. As adult development proceeded, both endogenous and radiolabelled ecdysteroids were increasingly localized in the gut, so that just prior to eclosion most ecdysteroids were present in the meconium of the high gut (rectal pouch). The peak titres and the kinetics of appearance of ecdysone, 20-hydroxyecdysone, and 20,26-dihydroxyecdysone were similar for both haemolymph and gut (and for males and females), but considerably higher levels of C-26 oxidized (acid) metabolites of ecdysone and 20-hydroxyecdysone were localized in the gut. Although levels of highly-polar ecdysteroid conjugates found in the haemolymph and gut were similar, considerable amounts of three less polar ecdysone conjugates, of 3-α-epimers of ecdysone and 20-hydroxyecdysone, and of a substance tentatively identified as 2-deoxyecdysone were found only in the gut. Whether ionized, conjugated, or free, the gut ecdysteroids did not appear to equilibrate with the haemolymph compartment.Differences were observed in the metabolism kinetics of exogenously administered radiolabelled ecdysone when compared to the endogenous ecdysteroids; and some RIA positive gut metabolites did not become significantly radiolabelled. This suggests that injection of ecdysone may not simulate the endogenous secretion of ecdysone or its subsequent metabolism and distribution completely accurately.     

Ecdysone metabolism in the host-parasitoid-system Trichoplusia ni/Chelonus sp

In unparasitized 4th and 5th-instar larvae of Trichoplusia ni and in 4th-instar larvae parasitized by Chelonus sp. 20-hydroxyecdysone, 20,26-dihydroxyec-dysone, and 20-hydroxyecdysonoic acid were the predominant metabolites formed 2 h after injection of [³H]ecdysone. Other unidentified metabolites were seen, but none seemed to be specific for either parasitized or unparasitized larvae. The major difference between parasitized and unparasitized larvae was seen with respect to the quantity of apolar (unidentified) and polar metabolites (20-hydroxyecdysonoic acid and unidentified ones), which were produced to a greater extent in parasitized larvae. Ecdysone was rapidly converted into 20-hydroxyecdysone and the other polar metabolites in all stages investigated, and the parasitoid seemed not to affect the conversion of ecdysone into 20-hydroxyecdysone. When analyzing the fate of [³H]ecdysone in host and parasite separately, at a stage when the parasite drinks hemolymph of its host, we observed that 10–20% of the radioactivity was recovered from the parasitoid. Analysis of the parasitoid's ecdysteroids revealed that ecdysone and 20-hydroxyecdysone represented only a small proportion of the recovered labeled ecdysteroids, the majority being apolar and polar metabolites. Our data suggest that the parasitoid takes up ecdysteroids from its host, converts them, and to some extent releases apolar metabolites into the host.     

Feedback inhibition of ecdysone production by 20-hydroxyecdysone in Pieris brassicae pupae

The effects of exogenous moulting hormones, ecdysone and 20-hydroxyecdysone on ecdysteroid production were studied in vivo in Pieris brassicae pupae. Both hormones inhibit ecdysteroid production; however, 20-hydroxyecdysone is much more efficient than ecdysone, and it is likely that the ecdysone effect is due to its partial conversion into 20-hydroxyecdysone. These results suggest that 20-hydroxyecdysone acts on ecdysteroid production as a negative-feedback regulator. Furthermore, since 20-hydroxyecdysone elicits inhibition in headless pupae, it is suggested that 20-hydroxyecdysone acts directly upon the prothoracic glands.     

The Fate of [3H]Ecdysone in Three Species of Annelids

Summary

The metabolism of [³H]ecdysone was examined in 3 species of annelids: the bloodworm, Tubifex vulgaris (a freshwater oligochaete), the earthworm, Lumbricus terrestris (a terrestrial oligochaete) and the ragworm, Nereis divtrsicolor (a marine polychaete). One of these species, N. diversicolor, metabolised injected [³H]ecdysone into compounds which co-chromatographed on both reversed-phase and adsorption HPLC with authentic 20-hydroxyecdysone, 26-hydroxyecdysone and 20,26-dihydroxyecdysone, thus demonstrating the occurrence of 20-hydroxylation and 26-hydroxylation capability in the Annelida. Furthermore, [³H]ecdysonoic acid was also formed and excreted by N. diversicolor, suggesting that 26-oic acid formation is involved in ecdysteroid inactivation in this species. Other, as yet unidentified, radioactive metabolites were also excreted by N. diversicolor. Several metabolites of [³H]ecdysone were also detected in the other 2 species examined, T. vulgaris and L. terrestris.     

Distribution and metabolism of exogenous ecdysteroids in the egyptian cotton leafworm Spodoptera littoralis (lepidoptera: noctuidae)

After ingestion of various amounts of either [³H]ecdysone or [³H]20-hydroxyecdysone (0.8 ng to 10 μg) by sixth instar larvae of the Egyptian cotton leafworm Spodoptera littoralis, apolar metabolites are rapidly detected in the gut and frass. Hydrolysis of the apolar products with Helix hydrolases releases solely [³H]ecdysone or [³H]20-hydroxyecdysone, respectively. This, coupled with the formation of chemical derivatives (acetonide and acetate) which cochromatograph with authentic reference compounds on hptlc and hplc demonstrates that these apolar metabolites consist of ecdysone or 20-hydroxyecdysone esterified at C-22 with common long-chain fatty acids. The major fatty acids have been identified by RP-hplc and their contribution to the mixture determined. In contrast, [³H]ecdysone injected into the haemolymph of S. littoralis is metabolized to yield 20-hydroxyecdysone, ecdysonoic acid, and 20-hydroxyecdysonoic acid. Thus, two different pathways exist for the metabolism of ecdysteroids in this species. In addition to an essentially polar pathway operating on injected and endogenous ecdysteroids, exogenous ecdysteroids entering the gut of S. littoralis are detoxified, yielding apolar ecdysteroid 22-fatty acyl esters which are rapidly excreted. The significance of these results in relation to the effects of ingested ecdysteroids on S. littoralis is discussed. Arch. Insect Biochem. Physiol. 34:329–346, 1997. © 1997 Wiley-Liss, Inc.     

Ecdysone 20-monooxygenase activity in land crabs

1. Ecdysone 20-monooxygenase activity has been found in hepatopancreas, gonads, epidermis and muscle of the crab Gecarcinus lateralis. Activity was assayed by measuring the in vitro conversion of [³H]-ecdysone to [³H]-20-hydroxyecdysone. Maximal activity is obtained at 30°C and pH 8.0 in sodium phosphate buffer.2. Activity from hepatopancreas is localized in a fraction which sediments at 10,000 g, probably mitochondria.3. NADPH stimulates activity and metyrapone or oxygen deprivation inhibits it, as has been observed for cytochrome P-450-dependent monooxygenases.4. Changes in ecdysone 20-monooxygenase activity at different stages of the molt cycle are not directly correlated to changes in ecdysteroid levels in the hemolymph.     

Ecdysone metabolism in adult crickets,Gryllus bimaculatus

The fate of injected [³H]ecdysone has been investigated in female and male adults of the Mediterranean field cricket, Gryllus binaculatus (de Geer). The metabolism is similar in both sexes and at various stages of adult life. Several classes of apolar metabolites (A1–A5) represent the major compounds. The amount of polar conjugates is low in all tissues, as are the concentrations of 20-hydroxyecdysone. Ovaries are the only organs capable of storing considerable amounts of ecdysteroids. The amount of radiolabelled ecdysteroid activity (mostly [³H]ecdysone) excreted during the first 24 hr after injection is high.The chemical identity of the apolar metabolites is not yet known. A2, which is the major apolar compound, has recently been identified as a complex of ecdysone conjugates with abundant long-chain fatty acids (Hoffman et al., 1985 Life Sci.37, 185–192). Incubations with tissue homogenates in vitro have shown that several organs are capable of converting ecdysone into apolar compounds. Apolar ecdysteroid acyl esters represent a newly identified class of ecdysone conjugates from insects. Their role in regulation of free ecdysteroid titres during the reproductive period in female crickets is discussed.     

Ecdysteroids in Carausius eggs during embryonic development

Peaks of ecdysteroids were observed during the different phases of embryonic development of intact Carausius eggs or eggs precociously deprived of their exochorion and cultivated under paraffin oil. Several groups of ecdysteroids were separated and analyzed by thin-layer chromatography (TLC) and high performance liquid chromatography (HPLC) combined with radioimmunoassay. Ecdysteroids were similar in the two categories of eggs, including high-polarity products (essentially conjugates hydrolyzable by Helix pomatia digestive juice, or alkaline phosphatase), possible ecdysonoic acids (unhydrolyzable polar substances), free hormones, and nonpolar ecdysteroids. Four ecdysteroids were identified by co-elution during HPLC with reference compounds of 20,26-dihydroxyecdysone, 20-hydroxyecdysone, ecdysone, and 2-deoxy-20-hydroxyecdysone. Concentrations of these substances (free and conjugated forms) were studied during the different stages of embryonic development: 20-hydroxyecdysone and 2-deoxy-20-hydroxyecdysone were the major free ecdysteroids. They showed parallel variations with large peaks at stages VI₈ and VII₆ whereas ecdysone titers were consistently low. Injected labelled ecdysone was converted efficiently into 20-hydroxyecdysone, and both compounds underwent 26-hydroxylation and/or conjugation to polar or apolar metabolites.     

Ecdysone 20-hydroxylation in imaginal wing discs of Pieris brassicae (lepidoptera): Correlations with ecdysone and 20-hydroxyecdysone titers in pupae

Ecdysone 20-hydroxylase activity has been detected in pupal wing discs of Pieris brassicae. This activity is due to an enzyme system located in microsomal fractions. Its apparent Km is 58 nM for ecdysone. The enzyme is inhibited by the reaction product 20-hydroxyecdysone with an apparent Ki of 2.6 μM. Its activity varied during pupal-adult development with a maximum on day 4, when ecdysone levels are the highest in the animal. Although low, the peak activity is sufficient to assure 25% of the conversion of endogenous ecdysone into 20-hydroxyecdysone in pupae. Ecdysone and 20-hydroxyecdysone levels were measured in hemolymph and whole animals; ecdysone appears to be mainly located in hemolymph, whereas 20-hydroxyecdysone seems to be equally distributed between hemolymph and tissues. All these findings are discussed in relation to the roles of ecdysone and 20-hydroxyecdysone during pupal-adult development.     

Biosynthesis of makisterone A and 20-hydroxyecdysone from labeled sterols by the honey bee,Apis mellifera

In an effort to determine the sterol precursor(s) of the 28-carbon ecdysteroid, makisterone A, honey bee pupae (13 days post-oviposition) were injected with radiolabeled sterols and subsequently examined for labeled ecdysteroids. High performance liquid chromatography of the pupal extracts revealed that [³H]campesterol was converted to a compound that behaved chromatographically identical to authentic makisterone A, and [¹⁴C]cholesterol was incorporated into a compound chromatographically like 20-hydroxyecdysone. No incorporation of either 24-[³H]methylenecholesterol or [¹⁴C]sitosterol into an ecdysteroid was observed. The neutral sterols of uninjected honey bee pupae contained 49.8% 24-methylenecholesterol on a relative percent basis and, with three other C²⁸ and C²⁹ sterols, accounted for over 99% of the total sterols present.     

Conversion of ecdysone and 20-hydroxyecdysone into 3-dehydroecdysteroids is a major pathway in third instar Drosophila melanogaster larvae

Ecdysone and 20-hydroxyecdysone metabolism was investigated in third instar Drosophila larvae both in vivo by injecting radiolabelled ecdysteroids and in vitro by incubating various tissues with labelled ecdysteroids.Ecdysone metabolism proceeds through different pathways: (1) C-20 hydroxylation; (2) C-26 hydroxylation and C-26 oxidation leading to the formation of 26-hydroxyecdysteroids (26-hydroxyecdysone and 20,26-dihydroxyecdysone) and acidic compounds (ecdysonoic acid and 20-hydroxyecdysonoic acid); C-3 oxidation and C-3 epimerization then conjugation leading to the formation of 3-dehydrocompounds (3-dehydroecdysone and 3-dehydro-20-hydroxyecdysone), 3-epimers (3-epiecdysone and 3-epi-20-hydroxyecdysone) and conjugates (only one conjugate was tentatively characterized as 3-epi-20-hydroxyecdysone-3-phosphate). 3-Dehydrocompounds are the major metabolites formed in third instar Drosophila larvae and C-3 oxidation occurs in various tissues. Experiments using tritiated cholesterol provided evidence that 3-dehydroecdysone and 3-dehydro-20-hydroxyecdysone are true endogenous ecdysteroids in Drosophila larvae.     

Meeting announcements

The levels of individual free and conjugated ecdysteroids and ecdysteroid acids, labeled from [¹⁴C]cholesterol, in five different age groups of male Manduca sexta during pupal-adult development were determined by HPLC. Eight free ecdysteroids, eight ecdysteroid phosphates, and two ecdysteroid acids were identified. Newly ecdysed pupae contained predominantly 3-epiecdysteroids in each of the free, conjugated, and acidic ecdysteroid fractions. The titer of each ecdysteroid fraction rose sharply by day 4, and this was particularly noteworthy with respect to free ecdysone and 3-epi-20-hydroxyecdysonoic acid. This stage demonstrated high degrees of ecdysone biosynthesis, oxidative catabolism, and phosphorylation. As development proceeded to day 16, total ecdysteroid titer remained constant; a decreasing free ecdysteroid titer was accompanieid by increasing titers of both conjugates and acids resulting from the metabolic processes of hydroxylation, oxidation, epimerization, and phosphorylation. The predominant metabolites throughout development were 3-epi-20-hydroxyecdysonoic acid and the phosphate conjugates of 3-epi-20-hydroxyecdysone and 3-epi-20,26-dihydroxyecdysone. The ultimate inactivation of the ecdysteroids of M. sexta during pupal-adult development is possibly mediated by two pairs of metabolically-linked processes, one leading to a 3-epiecdysteroid acid, and the other to 3-epiecdysteroid phosphates.     

Artifactual stimulation of vitellogenesis in Aedes aegypti by 20-hydroxyecdysone

Single or repeated, non-physiological, high doses (0.5–5.0 μg/female) of 20-hydroxyecdysone or ecdysone injected into sugar-fed female Aedes aegypti stimulated follicular growth and deposition of yolk, but suppressed accumulation of protein yolk to approximately one-third, and lipid yolk to one-half that in an equal number of follicles with equivalent yolk length taken from blood-fed controls. Physiological doses (500 pg/female) of ecdysone or 20-hydroxyecdysone or the implantation of ecdysone-secreting ovaries (verified by bioassay), into sugar-fed females failed to induce any yolk deposition. In these experiments, yolk precursors were not the limiting factor, because in decapitated females, digesting a blood meal, the injection of a physiological dose of 20-hydroxyecdysone or the implantation of ecdysone-secreting ovaries still did not stimulate vitellogenesis. Finally, continuous infusion of 500 pg or even 50 ng 20-hydroxyecdysone/hr for 22 hr was as ineffective as single or multiple injections of equivalent doses of hormone. Consequently, rapid excretion or catabolism of 20-hydroxyecdysone by the sugar-fed female does not explain the need for high doses to induce vitellogenesis, or the failure of oöcytes to mature with normal protein and lipid content. Apparently, ovarian ecdysone is not the factor by which normal vitellogenesis is initiated and maintained in this mosquito.     

Efficient isolation of ecdysteroids from the silkworm,Bombyx mori by droplet counter-current chromatography

The insect moulting hormones, 20-hydroxyecdysone, and its precursor, ecdysone were first isolated from the pupae of silkworm Bombyx mori using a classical solid support chromatographic technique. We have developed a simple procedure for isolation of 20-hydroxyecdysone and ecdysone from B. mori by droplet counter-current chromatography (DCCC). DCCC method was very efficient for isolation of such a small amount as insect hormones.     

Ecdysteroid levels throughout the life cycle of the desert locust, Schistocerca gregaria

Moulting hormone levels for all stages of the life cycle of the desert locust, Schistocerca gregaria, have been determined using gas chromatography with electron capture detection of the trimethylsilylated hormones. During larval development, the major hormone detected is 20-hydroxyecdysone with smaller quantities of ecdysone present. In mature adult females the major ecdysteroid observed is a polar conjugate of ecdysone, with smaller quantities of conjugated 20-hydroxyecdysone also present. During embryonic development the pattern changes from a high proportion of conjugated ecdysone in the early stages to give more free hormone and a higher proportion of 20-hydroxyecdysone in later stages. The highest titre of 20-hydroxyecdysone found in this insect is during the 5th larval instar. Maximal levels of ecdysteroid per insect are found in mature females just before oviposition, while the highest level of ecdysteroid per g of tissue is found in the eggs.     

Ecdysone metabolism in Pieris brassicae during the feeding last larval instar

Ecdysone metabolism in Pieris brassicae during the feeding last larval stage was investigated by using ³H-labeled ecdysteroid injections followed by high-performance liquid chromatographic (HPLC

1 Abbreviations: 3DE = 3-dehydroecdysone; 3D20E = 3-dehydro-20-hydroxyecdysone; 2026E = 20,26-dihydroxyecdysone; E = ecdysone; Eoic = ecdysonoic acid; 2026E′ = 3-epi-20,26-dihydroxyecdysone; E′ = 3-epiecdysone; E′oic = 3-epiecdysonoic acid; E′8P = 3-epiecdysone 3-phosphate; 20E′ = 3-epi-20-hydroxyecdysone; 20E′3P = 3-epi-20-hydroxyecdysone 3-phosphate; FT = Fourier transform; HPLC = high-performance liquid chromatography; 20E = 20-hydroxyecdysone; 20Eoic = 20-hydroxyecdysonoic acid; NMR = nuclear magnetic resonance; NP-HPLC = normal phase HPLC; RP-HPLC = reverse phase HPLC; TFA = trifluoroacetic acid; Tris = tris(hydroxymethyl)-aminomethane.

) analysis of metabolites. Metabolites were generally identified by comigration with available references in different HPLC systems. Analysis of compounds for which no reference was available required a large-scale preparation and purification for their identification by ¹H nuclear magnetic resonance spectrometry. The metabolic reactions affect the ecdysone molecule at C-3, C-20, and C-26, leading to molecules which are modified at one, two, or three of these positions. At C-20, hydroxylation leads to 20-hydroxyecdysteroids. At C-26, hydroxylation leads to 26-hydroxyecdysteroids which can be further converted into 26-oic derivatives (ecdysonoic acids) by oxidation. At C-3, there are several possibilities: there may be oxidation into 3-dehydroecdysteroids, or epimerization possibly followed by phosphate conjugation. Thus, injected 20-hydroxyecdysone was converted principally into 20-hydroxyecdysonoic acid, 3-dehydro-20-hydroxyecdysone, and 3-epi-20-hydroxyecdysone 3-phosphate. Labelled ecdysone mainly gave the same metabolites doubled by a homologous series lacking the 20-hydroxyl group.     

Characterization of acetyl-CoA: Ecdysone 3-acetyltransferase in Schistocerca gregaria larvae

Characterization of the acetyltransferase (acetyl-CoA: ecdysone 3-acetyltransferase) which catalyzes the conversion of ecdysone into ecdysone 3-acetate was carried out in gastric caecae of day 7 last instar larvae of Schistocerca gregaria. This enzyme is one of the enzymic systems involved in the inactivation of ecdysteroids. The acetyltransferase exhibited a microsomal subcellular localization, an apparent K_m for ecdysone of 71 μM, a maximal specific activity of 7.2 nmol/min/mg of protein and was inhibited competitively in the presence of 20-hydroxyecdysone with K_i = 68.8 μM. The enzyme required acetyl-CoA as co-substrate for its activity, the apparent K_m for acetyl-CoA being 47.2 μM. Acetic acid could not replace acetyl-CoA as the co-substrate, indicating that the enzyme is an acetyl-CoA: ecdysone acetyltransferase and not a hydrolase. Similarly, esterification of ecdysone was not observed when long-chain fatty acyl-CoA derivatives were substituted as co-substrates. The reaction was linear for 20 min and with protein concentration up to 0.8 mg/ml.The formation of 20-hydroxyecdysone 3-acetate has been demonstrated in the same microsomal fraction and required also acetyl-CoA as co-substrate. The apparent K_m of the acetyltransferase for 20-hydroxyecdysone was 53.5 μM, revealing that the enzyme had a somewhat stronger affinity for 20-hydroxyecdysone than for ecdysone.