Isolation and identification of 26-hydroxyecdysone 2-phosphate: An ecdysteroid conjugate of eggs and ovaries of the tobacco hornworm,Manduca sexta

Maturing eggs (48 to 64 h old) of the tobacco hornworm, Manduca sexta, contain at least three ecdysteroid conjugates, two of which have been previously identified as 26-hydroxyecdysone 26-phosphate (the major conjugate) and 26-hydroxyecdysone 22-glucoside. In this study we have isolated and identified the third conjugate as 26-hydroxyecdysone 2-phosphate by XAD-2 chromatography, C₁₈ SEP-PAK separation, ion suppression reversed-phase high-performance liquid chromatography, nuclear magnetic resonance, and fast atom bombardment mass spectrometry. This compound is the second most abundant conjugate of ovaries from 4-day-old adult females. The possible role for this ecdysteroid conjugate is discussed.     

Metabolism of 26-[14C]hydroxyecdysone 26-phosphate in the tobacco hornworm,Manduca sexta L., to a new ecdysteroid conjugate: 26-[14C]hydroxyecdysone 22-glucoside

Following injection into female Manduca sexta pupae, [¹⁴C]cholesterol is converted to a radiolabeled C₂₁ nonecdysteroid conjugate as well as ecdysteroid conjugates, which in ovaries and newly-laid eggs consist mainly of labeled 26-hydroxyecdysone 26-phosphate. During embryogenesis, as the level of 26-hydroxyecdysone 26-phosphate decreases there is a concurrent increase in the amount of a new, labeled ecdysteroid conjugate. This conjugate, which is the major ecdysteroid conjugate (9.4 μg/g) in 0- to 1-hour-old larvae was identified as 26-hydroxyecdysone 22-glucoside by nuclear magnetic resonance and chemical ionization mass spectrometry. This is the first ecdysteroid glucoside to be identified from an insect. The disappearance of 26-hydroxyecdysone 26-phosphate in 0- to 1-hour-old larvae indicates that the 26-hydroxyecdysone 22-glucoside is derived from 26-hydroxyecdysone 26-phosphate. 3-Epi-26-hydroxyecdysone was the major free ecdysteroid isolated from these larvae and 3-epi-20,26-dihydroxyecdysone was the next most abundant ecdysteroid isolated. Interestingly, the 0- to 1-hour-old larvae contained the highest levels of 3α-ecdysteroids per gram of insect tissue (8.7 μg/g) to be isolated from an insect, yet there was a complete absence of the corresponding free 3β-epimers. The ecdysteroid conjugate profiles of ovaries and 0- to 1-hour-old larvae are discussed. Methodology is presented that permits the efficient separation of free and conjugated ecdysteroids and nonecdysteroid conjugates (C₂₁-steroid conjugates).     

Profile of free and conjugated ecdysteroids and ecdysteroid acids during embryonic development of Manduca sexta (L.) following maternal incorporation of [14C]cholesterol

The levels of both free and conjugated ecdysteroids, maternally labeled from [¹⁴C]cholesterol, of six different age groups of Manduca sexta eggs were quantitatively determined. Eggs 0–1-h old contain about 2.5 and 35 μ/g of the 2- and 26-phosphates of 26-hydroxyecdysone, respectively, and 1 μg/g of 26-hydroxyecdysone. During embryogenesis of 26-hydroxyedcdysone 26-phosphate is hydrolyzed to 26-hydroxyecdysone, which reaches a peak titer in 1–18-h-old eggs; the level of 26-hydroxyecdysone 2-phosphate remains rather constant. Additionally, other metabolic modifications such as hydroxylation, conjugation, epimerization, and oxidation are occurring; and as the level of the 26-hydroxyecdysone 26-phosphate decreases there is a progression of other ecdysteroids. C-20 hydroxylation first appears in 24–40-h-old eggs and reaches peak activity in 48–64-h-old eggs, where 20-hydroxyecdysone and 20, 26-dihydroxyecdysone are both present at peak titer but the latter is the major free ecdysteroid. Ecdysone is observed at measurable levels only in the three age groups of eggs between 1 and 64 h-old. C-3 epimerase activity also appears at 24–40 h and continually increases throughout embryogenesis to the point that 3-epi-26-hydroxyecdysone and 3-epi-20, 26-dihydroxyecdysone are the major free ecdysteroids in 96-h-old eggs. A new ecdysteroid conjugate, 26-hydroxyecdysone 22-glucoside, first appears at 24–40h and becomes the major conjugate in 72–80-h-old eggs; it represents an apparent end-product as its peak titer is reached and maintained throughout the final embryonic stages. 20-Hydroxyecdysonoic acid occurs in 48–64-h-old eggs, and along with 3-epi-20-hydroxyecdysonoic and ecdysonoic acids in 72–88-h-old eggs. 20-Hydroxyecdysonoic acid peaks during the latter time interval, and as its titer subsequently falls, there is a concurrent increase in the level of 3-epi-20-hydroxyecdysonoic which was identified as the second major component of the ecdysteroid conjugate fraction of 0–1-h-old larvae. Our results indicate that there is little or no biosynthesis of ecdysteroids during embryogenesis; that the materal ecdysteroid conjugate 26-hydroxyecdysone 26-phosphate serves as source for 26-hydroxyecdysone and the numerous metabolites; that 26-hydroxyecdysone and 20,26-dihydroxyecdysone may be the active hormones during embryonic development; and that glucosylation, epimerization, and formation of acids cosntitute inactivation processes. A scheme of the proposed pathways involved in the metabolism of 26–hydroxyecdysone 26-phosphate in the developing eggs of m. sexta is presented.     

Ecdysteroids in developing ovaries and eggs of the tobacco hornworm

Ecdysteroids of ovaries and newly-laid eggs (0- to 1-hour-old) of the tobacco hornworm are present mainly as conjugates (greater than 95%). Newly-laid eggs contain ecdysteroid conjugates equivalent to 21 micrograms of 26-hydroxyecdysone and 0.73 micrograms of ecdysone per gram of eggs. These levels are similar in ovaries of 93-hour-old adult females. In 1- to 18-hour-old eggs more than 63% of the ecdysteroids exist in the free form and the proportion is similar in 48- to 64-hour-old eggs. The ratio of 26-hydroxyecdysone to ecdysone in the conjugated form remains constant during oocyte maturation and embryogenesis. Though 26-hydroxyecdysone is without molting hormone activity in the house fly assay, the exceptionally high concentration of 26-hydroxyecdysone conjugate(s) in ovaries and newly-laid eggs, together with the fact that it is being released during embryogenesis, indicate some physiological role for 26-hydroxyecdysone.     

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.     

The ecdysteroids from young embryonated eggs of the tobacco hornworm

26-Hydroxyecdysone, which is the major free recoverable ecdysteroid of older age groups of embryonated eggs of the tobacco hornworm was also the major component in 4- to 18-hour-old embryonated eggs. The other 3β-ecdysteroids, ecdysone, 20-hydroxyecdysone, and 20,26-dihydroxy-ecdysone, were also present and accounted for an the molting hormone activity; 26-hydroxyecdysone was devoid of molting hormone activity in the house fly assay. 20-Hydroxyecdysone was a minor component, which confirms the earlier observations that the main metabolic route for ecdysteroids during embryonic development is that leading to 26-hydroxy-ecdysone, whereas formation of 20-hydroxyecdysone is a minor pathway. A new 3α-ecdysteroid, 3-epi-26-hydroxyecdysone, also devoid of molting hormone activity, was the second major ecdysteroid isolated from the eggs. 3-Epi-20,26-dihydroxyecdysone was detected in very minute amounts. In additon to the six 3β-and 3α-ecdysteroids there were at least an equivalent number of unknown ecdysteroids an of which lacked molting hormone activity. Their physical properties including chromatographic behavior are discussed.     

The identification and titres of conjugated and free ecdysteroids in developing ovaries and newly-laid eggs of Schistocerca gregaria

Ecdysteroid levels throughout ovarian development and in newly-laid eggs of S. gregaria have been determined. A simple method for the separation of free and conjugated ecdysteroids is described. Both free and polar conjugated ecdysteroids are present at the end of oögenesis and in newly-laid eggs, but the polar conjugated ecdysteroids always predominate; 95% of the total ecdysteroid in newly-laid eggs is in the conjugated form. Ecdysone, 2-deoxyecdysone and 20-hydroxyecdysone have been fully characterized from both the ‘free’ and ‘conjugated’ fractions. The presence of traces of 26-hydroxyecdysone in the ‘conjugate’ fraction was indicated by HPLC analyses. The levels of ecdysteroid released from the conjugates of newly-laid eggs were 35 μg/egg pod (44 μg/g wet weight) for ecdysone, 16 μg/egg pod (19.4 μg/g) for 2-deoxyecdysone and 5 μg/egg pod (6.1 μg/g) for 20-hydroxyecdysone. The level of free ecdysone found in newly-laid eggs was 2 μg/egg pod (2.6 μg/g).     

Characterization of ecdysteroid 26-hydroxylase: an enzyme involved in molting hormone inactivation

Insect molting hormone (ecdysteroid) inactivation occurs by several routes, including 26-hydroxylation and further oxidation to the 26-oic acids. Thus, the ecdysteroid 26-hydroxylase is a critical enzyme involved in precise regulation of ecdysteroid titers during insect development. Administration of the ecdysteroid agonist, RH-5849 (1,2-dibenzoyl, 1-tert-butyl hydrazone), or 20-hydroxyecdysone to the tobacco hornworm, Manduca sexta, results in induction of ecdysteroid 26-hydroxylase activity in midgut mitochondria and microsomes. The biochemical and kinetic properties of the ecdysteroid 26-hydroxylase were investigated. The mitochondrial enzyme was found to have optimal activity at a pH of 7. 5 in a Hepes or sodium phosphate buffer at 30-37 degrees C. The apparent K(m) of the microsomal 26-hydroxylase for 20-hydroxyecdysone substrate was lower than that of the mitochondrial enzyme for either 20-hydroxyecdysone or ecdysone substrate. The V(max) of the 26-hydroxylase in both subcellular fractions was slightly higher using 20-hydroxyecdysone as substrate compared to ecdysone. Demonstration that activity of the mitochondrial 26-hydroxylase was inhibited by incubation in a CO (or N(2)) atmosphere, taken together with the requirement for reducing cofactor and the efficacy of the P450 inhibitors, ketoconazole and fenarimol, provided strong evidence that the hydroxylase is cytochrome P450-dependent. Indirect evidence suggested that the mitochondrial and microsomal ecdysteroid 26-hydroxylase(s) could exist in a less active dephosphorylated state or more active phosphorylated state. Using Escherichia coli alkaline phosphatase to remove covalently bound phosphate groups, the activity of the 26-hydroxylase was decreased and, conversely, activity was enhanced using a cAMP-dependent protein kinase with appropriate cofactors. In addition, the protein kinase was shown to reactivate the 26-hydroxylase activity in alkaline phosphatase-treated fractions.     

The molting hormones from the embryonated egg of the tobacco hornworm, Manduca sexta (L.)

26-Hydroxyecdysone is the predominant molting hormone in 24- to 44-hour-old embryonated tobacco hornworm eggs, accounting for approximately 80% of the ecdysones present at this stage of development. This molting hormone was previously shown to be the major ecdysone present in 48- to 64-hour-old embryonated eggs of this insect. During both of these periods of embryonic development in the hornworm 20-hydroxyecdysone is a minor component, in contrast to its presence as the major ecdysone in the hornworm during certain stages of post-embryonic development.     

Metabolism of [3H]-ecdysone in Schistocerca gregaria; formation of ecdysteroid acids together with free and phosphorylated ecdysteroid acetates

The metabolism of [³H]-ecdysone has been investigated at times of low and high endogenous ecdysteroid tit re, in early and late fifth-instar Schistocerca gregaria larvae, respectively. Ecdysone-3-acetate, 20-hydroxyecdysone, and 20,26-dihydroxyecdysone were identified as metabolites in both the free form and as polar conjugates. Comparison of the intact polar conjugates of the ecdysteroid acetates on two HPLC systems with the corresponding authentic compounds indicated that they were 3-acetylecdysone-2-phosphate and 3-acetyl-20-hydroxyecdysone-2-phosphate. Other major polar metabolites were identified as ecdysonoic acid and 20-hydroxyecdysonoic acid. Ecdysone metabolism in fifth-instar S. gregaria is apparently an age-dependent process. Early in the instar, excretion of both free and conjugated ecdysteroids, as well as ecdysteroid 26-acids, occurs. At this stage the level of ecdysteroid acetates in the conjugated (phosphate) form is high, in contrast to the free ecdysteroids, where ecdysone predominates. When the endogenous hormone titre is high, the formation of ecdysteroid acetates is less, the major excreted matabolites at that stage being conjugated 20-hydroxyecdysone together with ecdysteroid-26-acids, but little free ecdysteroids. Acetylation of ecdysone occurs primarily in the gastric caecae. Ecdysone-3-acetate (mainly as polar conjugate) is also a major product of ingested ecdysone in early fifth-instar Locusta migratoria.     

Metabolism of [14C]cholesterol in Manduca sexta pupae: Isolation and identification of sterol sulfates,free ecdysteroids,and ecdysteroid acids

[¹⁴C]Cholesterol was injected into fifth-instar larvae of Manduca sexta, and the metabolites were isolated and identified from 8-day-old male and female pupae. A major portion of the metabolized cholesterol was esterified either with a sulfate group or with fatty acids. The predominant ecdysteroid metabolites were 20-hydroxyecdysone, 20,26-dihydroxyecdysone, 20-hydroxyecdysonoic acid, and 3-epi-20-hydroxyecdysonoic acid. Smaller amounts of ecdysteroids were identified as conjugates of 26-hydroxyecdysone, 3-epi-20-hydroxyecdysone, 20,26-dihydroxyecdysone, and its 3α-epimer. The metabolic profiles were similar for both male and female pupae. The two ecdysteroid acids were identified by nuclear magnetic resonance spectroscopy and chemical ionization mass spectrometry and by mass spectral analyses of their methyl esters. Detection of 3-epi-20-hydroxyecdysonoic acid as a major metabolite is significant, as its occurrence has been scarcely reported. 3-Epiecdysteroid acid formation is discussed as a possible ecdysteroid-inactivating pathway that may be operating specifically in lepidopterous insects or in particular developmental stages such as eggs or pupae.     

Ecdysteroid profiles for hemolymph and testes from larvae,pupae, and pharate adults of the European corn borer,Ostrinia nubilalis hubner

Total ecdysteroid levels as well as concentrations of several individual ecdysteroids were determined for hemolymph and testes of fifth instars, pupae, and pharate adults of the European corn borer, Ostrinia nubilalis (Hubner). For total levels, the patterns of fluctuation in hemolymph and testes were similar, but the concentrations in testes were lower than those in hemolymph. In both hemolymph and testes there were two ecdysteroid peaks: the first just prior to the formation of the pharate pupa, the second just prior to the formation of the pharate adult. An examination of ecdysteroid profiles revealed some important differences. Ecdysone was either absent or present at extremely low levels in larval testes, whereas in hemolymph there was a premolt ecdysone peak. In pupal testes, ecdysone was present, but levels of 26-hydroxyecdysone were much lower than those in hemolymph. Thus, in regard to ecdysteroids, testes have the ability to control their own internal milieu.     

Conversion of 3-dehydroecdysone by a ketoreductase in post-diapause, pre-hatch eggs of the gypsy moth Lymantria dispar

The prothoracic glands (PGs) of Lymantria dispar (day-5 female, last-stage larvae) produce both ecdysone and an ecdysteroid which has the same retention time on reverse-phase liquid chromatography (RPLC) as a known standard of 3-dehydroecdysone. The latter ecdysteroid can be converted by a heat-labile factor in extracts of post-diapause, pre-hatch L. dispar eggs to an ecdysteroid which has the same retention time on RPLC as ecdysone. Purified 3-dehydroecdysone, similarly treated with egg extract, also gives the same retention time on RPLC as ecdysone. Taken together, these data suggest that, like Manduca sexta, a major product of the PGs in L. dispar is 3-dehydroecdysone. Furthermore, these data suggest that L. dispar eggs, which contain mature embryos, possess ecdysteroid ketoreductase activity capable of converting 3-dehydroecdysone to ecdysone. This is the first report of ecdysteroid ketoreductase activity in embryonated eggs.     

Ecdysteroid levels and integument changes in post-embryonic stages of Anastrepha suspensa

Ecdysteroid levels in larvae and pupae of Anastrepha suspensa (Diptera: Tephritidae) were measured by radioimmunoassay. These levels were correlated with histological changes throughout the development of the post-embryonic stages. Ecdysteroid levels increase rapidly throughout the last-larval instar and on the last day of this stage are 283 pg equivalents of 20-hydroxyecdysone per insect (14.5 ng/g) when wandering behaviour is initiated. At the end of this period the puparium is formed and within 24 h, the ecdysteroid rises to its highest peak (625 pg equivalents of 20-hydroxyecdysone/insect). Larval-pupal apolysis is initiated within 24 h later and the pupal cuticle is then secreted. Two days later, the ecdysteroids reach their lowest levels (75 pg equivalents of 20-hydroxyecdysone/insect or 0.6 ng/g) and most of the larval fat body and other tissues have been histolysed. In 5- to 10-day old pupae ecdysteroid levels again increase and remain relatively high throughout. During this period the larval epidermis is replaced by imaginal epidermis, imaginal discs begin to proliferate and the adult cuticle is secreted. Ecdysteroid levels finally fall 2 days prior to adult emergence. HPLC determinations indicate that 20-hydroxyecdysone is the predominant free ecdysteroid, and along with ecdysone, is readily detectable in all postembryonic stages of this species. An unusually high and unexplained peak of 20-hydroxyecdysone occurs in the pharate adult. This peak probably consists of ecdysone metabolites with retentions similar to that of 20-hydroxyecdysone and to which the antiserum is sensitive.     

Identification of the 22-phosphate esters of ecdysone, 2-deoxyecdysone, 20-hydroxyecdysone and 2-deoxy-20-hydroxyecdysone from newly laid eggs of the desert locust, Schistocerca gregaria.

The four major ecdysteroid (insect moulting hormone) conjugates present in the newly laid eggs of the desert locust, Schistocera gregaria, have been purified by reversed-phase and anion-exchange high-performance liquid chromatography. The steroid moieties were identified as ecdysone, 2-deoxyecdysone, 20-hydroxyecdysone and 2-deoxy-20-hydroxyecdysone. Phosphate analysis of acid-hydrolysed samples showed a steroid:phosphate ratio of approx. 1:1 for all four compounds. The intact conjugates were identified as ecdysone 22-phosphate, 2-deoxyecdysone 22-phosphate, 20-hydroxyecdysone 22-phosphate and 2-deoxy-20-hydroxyecdysone 22-phosphate by fast atom bombardment mass spectrometry and 1H, 13C and 31P n.m.r. The significance of ecdysteroid phosphates as a source of free hormone during embryogenesis is discussed.     

Cellular events in the prothoracic glands and ecdysteroid titres during the last-larval instar of Spodoptera littoralis

Changes in prothoracic gland morphology were correlated to developmental events and ecdysteroid titres (20-hydroxyecdysone equivalents) during the last-larval instar in Spodoptera littoralis. After ecdysis to the last-larval instar the haemolymph ecdysteroid titre remained at about 45 ng/ml, when the prothoracic glands appeared quiescent. The first signs of distinct gland activity, indicated by increased cell size and radial channel formation, were observed at about 12 h prior to the cessation of feeding (36 h after the last-larval moult), accompanied by a gradual increase in ecdysteroid titre to 110 ng/ml haemolymph, at the onset of metamorphosis. During this phase ecdysteroid titres remained at a constant level (140–210 ng/ml haemolymph) and prothoracic gland cellular activity was absent for a short period. The construction of pupation cells occurred when haemolymph ecdysteroids titres increased to 700 ng/ml. A rapid increase in ecdysteroids began on the fourth night (1600 ng/ml haemolymph) reaching a maximal level (4000 ng/ml haemolymph) at the beginning of the fourth day. In freshly moulted pupae a relatively high ecdysteroid titre (1100 ng/ml haemolymph) was still observed, although during a decrease to almost negligible levels. The increase in ecdysteroid level during the third and the fourth nights of the last-larval instar was correlated with the period when almost all the prothoracic gland cells showed signs of high activity. Neck-ligation experiments indicated the necessity of head factors for normal metamorphosis up to the second to third day of the instar. The possibility that the prothoracic glands are under prothoracicotropic hormone regulation at these times is discussed.     

Developmental plasticity of neuropeptide expression in motoneurons of the moth,Manduca sexta: Steroid hormone regulation

Developmental changes in the expression of a FMRFamide-like (Phe-Met-Arg-Phe-NH₂) peptide or peptides in motoneurons of the tobacco hornworm, Manduca sexta, were demonstrated using immunohistochemical techniques. The onset of FMRFamide-like immunoreactivity (FLI) was gradual during larval growth but by the final larval stage, immunoreactivity was present in the majority of motoneurons. FLI then declined during metamorphosis and was absent in all identified adult motoneurons. We used a novel in vivo culture system to demonstrate that the steroid hormone, 20-hydroxyecdysone, regulates the loss of FLI in motoneurons during metamorphosis. The small commitment peak of ecdysteroid appears to shut off the program of neuropeptide accumulation that is characteristic of the larval state of the motoneurons. The prepupal peak of steroid then causes the rapid loss of stored FLI. This steroid-induced change in the neuropeptide content of motoneurons may reflect major changes in neuromuscular functions between the larval and adult stages. © 1996 John Wiley & Sons, Inc.     

Absence of phytosterol dealkylation and identification of the major ecdysteroid as makisterone A in Dysdercus fasciatus (Heteroptera,Pyrrhocoridae)

The absence of phytosterol dealkylation in the cotton stainer bug, Dysdercus fasciatus, has been established and the major ecdysteroid in the fifth-stage larvae identified. The demonstration that the free and esterified sterols in D fasciatus consisted of 95–96% sitosterol and 4–5% campesterol, a similar composition to the cottonseed diet, together with the lack of conversion of [¹⁴C]sitosterol into cholesterol, establishes that phytosterol dealkylation does not occur in this insect species. The ecdysteroid titer determined by radioimmunoassay in the fifth instar of D fasciatus shows a distinct peak at day 6, the instar lasting for 7 days. Makisterone A was purified by HPLC from insects at a time of high ecdysteroid titer and identified as a major component by both fast atom bombardment and electron impact mass spectrometry. Gas-liquid chromatography/mass spectrometry (selected ion monitoring) confirmed the occurrence of makisterone A and revealed the presence of two unidentified compounds. One of these occurs in a similar amount to makisterone A and may be 26-hydroxymakisterone A, whereas only a minute amount of the other compound, which may be 20-deoxymakisterone A, was present; further identification of the latter compounds is necessary. C₂₇ ecdysteroids (eg, ecdysone and 20-hydroxyecdysone) and C₂₉ ecdysteroids (eg, podecdysone A) were undetectable. The specificity of the enzymes of ecdysteroid biosynthesis is discussed.