Makisterone C: A 29-carbon ecdysteroid from developing embryos of the cotton stainer bug,Dysdercus fasciatus

An ecdysteroid RIA was used to determine the ecdysteroid titer in developing embryos of Dysdercus fasciatus and revealed that peak titer occurred approximately 120 h post-oviposition. Analysis of neutral sterols at this time indicated sitosterol to be the predominant neutral sterol with lesser amounts of campesterol. Embryonic sterols were highly reflective of the sterols found in the cotton seed diet upon which previous generations of the bugs had fed. Analysis of the embryonic extract for ecdysteroids indicated the presence of both makisterone A and the 29-carbon ecdysteroid makisterone C. Isolation of these compounds was accomplished by reversed-phase and silica HPLC in conjunction with RIA, and the identification of both compounds was confirmed by mass spectrometry. No ecdysone or 20-hydroxyecdysone was detected in the embryonic sample.     

Occurrence of 28- and 27-Carbon ecdysteroids and sterols in developing worker pupae of the leaf-cutting ant acromyrmex octospinosus (reich) (hymenoptera,formicidae: Attini)

The major ecdysteroids in large worker pupae of the leaf-cutting ant Acromyrmex octospinosus were characterized at the peak ecdysteroid concentration by using high-performance liquid chromatography, enzyme immunoassay, and mass spectrometry. In decreasing amounts, they were determined to be makisterone A, an unidentified C₂₈ ecdysteroid bearing a molecular weight of 494, 20-hydroxyecdysone (ratio of 1 to 6 as compared to makisterone A), and putative but negligible ecdysone. The presence of both C₂₈ and C₂₇ ecdysteroids is discussed in relation to the content of 4-desmethylsterols determined by gas chromatography and mass spectrometry to be ergosta-5,7,24 (28)-trien-3β-ol, ergosterol, ergosta-5,7-dien-3β-ol and ergosta-7,24(28)-dien-3β-ol for the main sterols, and with a small amount of cholesterol.     

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.     

Larval moulting hormone of trichophoran Hemiptera-Heteroptera: Makisterone A,not 20-hydroxyecdysone

The haemolymph ecdysteroids were examined in fifth-stage larvae of Nezara viridula, Podisus maculiventris and Dysdercus cingulatus (Hemiptera-Heteroptera) using high-pressure liquid chromatography to separate the ecdysteroids and a radioimmunoassay to detect the fractionated ecdysteroids. The length of the fifth stage ranged from 5 to 8 days, and a peak in ecdysteroid titre (1700–2650 ng/ml) occurred 2–3 days prior to ecdysis to the adult. An ecdysteroid matching the retention time of makisterone A (24-methyl-20-hydroxyecdysone) was clearly present in haemolymph taken at the time of peak titre in all 3 of these true bugs, whereas little, if any, ecdysone or 20-hydroxyecdysone was detected. These data, along with previously reported data for the milkweed bug Oncopeltus fasciatus, are persuasive evidence that makisterone A is the larval moulting hormone of a group of closely related Heteroptera called the Trichophora (Lygaeoida, Pentatomoidea, Pyrrhocoroidea and Coreoidea).     

Neutral sterols of representatives of two groups of hemiptera and their correlation to ecdysteroid content

The sterols of four species of Pentatomomorpha—Oncopeltus fasciatus (Dallas), Nezara viridula (L.), Dysdercus cingulatus (F.), and Podisus maculiventris (Say)—and threé species of Cimicomorpha—Rhodnius prolixus Stal, Arilus cristatus (L), and Cimex lectularius (L.)—were isolated and examined in order to compare neutral sterol utilization and content with the known ecdysteroids of these species. In the phytophagous Pentatomomorpha, O. fasciatus, N. viridula, and D. cingulatus, the low content of cholesterol and the high content of C₂₈ and C₂₉ phytosterols (< 1% and > 99% of the tissue sterols, respectively) indicated that these species are unable to dealkylate the C-24 position of sterols. These insects appear to have adapted to the challenge of both insufficient dietary cholesterol and inability to dealkylate phytosterols by evolving the ability to produce a C₂₈ ecdysteroid (makisterone A). The secondarily predacious P. maculiventris has adequate cholesterol available for C₂₇ ecdysteroid production, but appears to have retained the ecdysteroid biosynthetic pathways of its phytophagous ancestors because it produces a C₂₈ ecdysteroid. Cholesterol was the major sterol of each of the three species of Cimicomorpha, and these insects are only able to produce C₂₇ ecdysteroids.     

The neutral sterols of Megalotomus quinquespinosus (say) (hemiptera: Alydidae) and identification of makisterone a as the major free ecdysteroid

Last-stage nymphs of the broad-headed bug, Megalotomus quinquespinosus contain the C₂₈ ecdysteroid makisterone A as their major ecdysteroid. No ecdysone or 20-hydroxyecdysone was detected in whole body extracts analyzed by high performance liquid chromatography and radioimmune assay. Analyses of the neutral sterols of this phytophagous hemipteran revealed that the sterol composition of the nymphs was highly reflective of their dietary sterols. The most abundant nymphal sterols were sitosterol (46.6%), Δ⁷-stigmastenol (13.8%) and spinasterol (13.4%). Cholesterol accounted for only 0.2% of the total sterols and indicates that this species is incapable of converting 24-alkyl sterols to cholesterol.     

Relationship of the neutral sterols and ecdysteroids of the parasitic mite,Varroa jacobsoni to those of the honey bee,Apis mellifera

The neutral sterols of the parasitic mite Varroa jacobsoni were compared with Apis mellifera carnica drone pupae. Analysis by GLC-mass spectrometry indicated mite sterols were reflective of the sterol composition of the drones; 24-methylenecholesterol was the major sterol in both species, with lesser amounts of sitosterol and isofucosterol. Cholesterol accounted for less than 1% of the total sterols. Ecdysteroid analyses indicated drones contained primarily makisterone A. In addition to makisterone A, mites contained ecdysone and 20-hydroxyecdysone, which accounted for over 66% of the ecdysteroid detected. These results indicate that while V. jacobsoni are apparently unable to convert dietary sterols to cholesterol, they are able to produce significant amount of C(27) ecdysteroids in a low cholesterol environment.     

Haemolymph ecdysteroids in the solitary and gregarious larvae of Schistocerca gregaria

In the penultimate and last instar larvae of Schistocerca gregaria, 20-hydroxyecdysone (20E) makes up 74–84% of detected ecdysteroids in the females, and 63–74% in the males. Remaining ecdysteroids include ecdysone, a compound with HPLC and TLC retention times of makisterone A, and highly polar metabolites. Except for the last instar females, the contents of ecdysone and the unknown compound are higher in the solitary phase, while that of polar metabolites is higher in the gregarious phase. The phases also differ in that the molt-inducing ecdysteroid peaks last longer in the gregarious than in the solitary larvae. Peak concentrations reach 3.0–4.0 μg 20E equiv./ml in penultimate female instar, 2.5–3.0 μg/ml in penultimate male instar, and 1.5–2.0 μg/ml in the last larval instar of both sexes. © 1996 Wiley-Liss, Inc.     

Neutral sterols and ecdysteroids of the solitary cactus bee Diadasia rinconis cockerell (hymenoptera: Anthophoridae)

Using high performance liquid chromatography in conjunction with radioimmunoassay and mass spectrometry, the major ecdysteroid of the solitary cactus bee, Diadasia rinconis, was determined to be 20-hydroxyecdysone, with lesser amounts of makisterone A. Another 28-carbon ecdysteroid thought to be the 24-epimer of makisterone A was also detected. The neutral sterols of Diadasia consisted primarily of 24-methylenecholesterol (92.2%) with lesser amounts of other C₂₈ and C₂₉ sterols. Cholesterol accounted for less than 0.1% of the total tissue sterols. The occurrence of 20-hydroxyecdysone in a phytophagous hymenopteran is discussed in relation to the low level of cholesterol encountered. © 1993 Wiley-Liss, Inc.

1 This article is a US Government work and, as such, is in the public domain in the United States of America.

     

Hemolymph concentrations of host ecdysteroids are strongly suppressed in precocious prepupae of Trichoplusia ni parasitized and pseudoparasitized by Chelonus near curvimaculatus.

Regulation of ecdysteroid production in lepidopteran prepupae was studied using a parasitic wasp (C. near curvimaculatus) which specifically suppresses host prepupal ecdysteroid production after the induction of precocious host metamorphosis. At the developmental stage at which the hemolymph of the unparasitized metamorphosing host has its maximum titer of prepupal ecdysteroids, the hemolymph of 4th instar "truly parasitized" hosts (hosts with a surviving endoparasite) had a strongly reduced ecdysteroid titer. However, during the photophase about 12 h later, just prior to emergence of the parasite larva, an ecdysteroid peak was observed in the host hemolymph. Fourth instar pseudoparasitized prepupal hosts (in which the endoparasite was not present or died early in development) exhibited a sustained suppression in the hemolymph ecdysteroid titer. Small 5th instar pseudoparasitized hosts, which normally would molt to a 6th instar prior to metamorphosis, but which precociously attained the prepupal stage, also had a strongly reduced ecdysteroid titer. The late increase observed in truly parasitized hosts could be completely prevented by surgical removal of the parasite 24 h earlier, resulting in a titer similar to that in pseudoparasitized hosts. HPLC analysis of ecdysteroids in normal, truly parasitized, and 4th or 5th instar pseudoparasitized prepupae showed that both ecdysone and 20-OH ecdysone* were suppressed in truly and pseudoparasitized prepupae, with ecdysteroid levels being lowest in pseudoparasitized hosts. These data, and those of Brown and Reed-Larsen (Biol Contr 1, 136 [1992]), showing endoparasite secretion of ecdysteroids just prior to its emergence from the host, strongly indicate that: (1) the prepupal peak in truly parasitized hosts originates from the endoparasite, and (2) the low level of ecdysteroids in pseudoparasitized hosts results from the host's intrinsic inability to express a normal level of prepupal ecdysteroid titer. While precocious 4th or 5th instar prepupae of similar size had similarly suppressed ecdysteroid titers, smaller 4th instar prepupae had a lower ecdysteroid titer than larger, precocious 5th instar prepupae. Rare 5th instar pseudoparasitized prepupae that were of nearly normal size showed a prepupal ecdysteroid titer distinctly greater than those of the usual smaller, precocious 5th instar prepupae. The data suggest that the competence of the host to express a normal hemolymph titer of prepupal ecdysteroids is more closely correlated with the size of the prepupae than with the instar attained.     

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.     

Cell Cultures of Ecdysteroid-Containing Ajuga reptansand Serratula coronata Plants

Cell suspension cultures of Ajuga reptans L. and Serratula coronata L. were derived from long-cultured calluses. Their growth patterns and morphophysiological characteristics indicated that these cells adapted well to grow in suspensions. During the growth cycle of cell suspension, the main ecdysteroid, among others present in plants, was 20-hydroxyecdyson (20E) for both cell lines. The content of 20E in cell suspension of A. reptans was 4–8 times higher than in the intact plant. After long culturing, the ecdysteroid profile in cell suspensions of S. coronata (20E, inokosterone, makisterone A, ecdyson, and a nonidentified metabolite) became similar to that of the intact plant. The ecdysteroids accumulated with a periodicity during subculturing cycle.     

An ultrastructural analysis of the ecdysoneless ((l(3)ecd 1ts) ring gland during the third larval instar of Drosophila melanogaster

Summary In the late third larval instar of Drosophila melanogaster, the prothoracic gland, an endocrine portion of the ring gland, synthesizes ecdysteroids at an accelerated rate. The resultant ecdysteroid titer peak initiates the events associated with metamorphosis. The normal prothoracic gland displays several ultrastructural features at this developmental stage that reflect increased steroidogenic activity, including extensive infoldings of the plasma membrane (membrane invaginations) and an increase in both the concentration of smooth endoplasmic reticulum (SER) (or transitional ER) and elongated mitochondria. By contrast, the prothoracic glands of larvae homozygous for a conditional larval lethal mutation, l(3)ecd ^1ts, not only fail to produce ecdysteroids at normal levels at the restrictive temperature (29° C), but also acquire abnormal morphological features that reflect the disruptive effects of the mutation. These abnormalities include an accumulation of lipid droplets presumed to contain sterol precursors of ecdysteroids, a disappearance of SER and a drastic reduction of membrane invaginations in the peripheral area of the cell. These morphological defects are observed in prothoracic glands dissected from larvae transferred from 18° C to 29° C approximately 24 h before observation and also within 4 h of an in vitro transfer to 29° C following dissection from wandering third instar larvae reared at 18° C. No ultrastructural abnormalities were noted in the corpus allatum portion of mutant ring glands. These observations further indicate the direct involvement of the ecd gene product in ecdysteroid synthesis and suggest a role for the gene in the proper transport of precursors to the site where they can be utilized in ecdysteroid biosynthesis.     

Ecdysteroid synthesis by testes of 5th instars and pupae of the European corn borer,Ostrinia nubilalis (Hubner)

Summary

Testes from young fifth instar Ostrinia nubilalis produced very small amounts of ecdysteroids while those from larvae that had purged their gut produced considerably more immunodetectable ecdysteroid in vitro. Larval testes that had fused produced 2.2 times more ecdysteroid than those that remained separate. It was the sheath of the testes rather than the contents that was physiologically active. Synthesis was questionable in testes from day-1 pupae and was not observed in testes from pharate pupae, from day-2 pupae or from pharate adults. Thus, synthesis only occurred at specific times in the life cycle. Ecdysteroid profiles for testes from wandering larvae whose testes had fused showed a net increase in all normally observed ecdysteroids, with the greatest increase being in 20-hydroxyecdysone. For testes from day-1 pupae, the nature of the ecdysteroid profile changed after 24 h of incubation, with some ecdysteroids showing increases and other decreases. There appear to be considerable differences among species regarding the times of testis synthesis and the amounts and nature of the ecdysteroids synthesized.     

Sterol utilization and ecdysteroid content in the house fly,Musca domestica (L.)

Larvae of the house fly, Musca domestica were reared aseptically on diets which contained either cholesterol, campesterol or sitosterol as the dietary sterol at a concentration of 0.1% dry wt. Analysis of puraria (24 h post-pupariation) reared on campesterol or sitosterol diets revealed they contained from 2.7 to 4.6% cholesterol, indicating an ability to accumulate this sterol even where it is present in only minute quantities. Purparia on all diets produced the 27-carbon molting hormones, ecdysone and 20-hydroxyecdysone. When the concentration of campesterol was increased to 0.2% dry wt, puparia also contained the 28-carbon ecdysteroid, makisterone A, although it accounted for only 20.7% of the total ecdysteroid produced.     

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).     

Makisterone A: The major ecdysteroid from the pupa of the honey bee,Apis mellifera

Makisterone $\text{A}$, a 28-carbon moulting hormone, has been identified as the major free pupal ecdysteroid in the honey bee, Apis mellifera. The pupal ecdysteroid was isolated and identified by normal and reversed-phase high performance liquid chromatography in conjunction with a radioimmune assay. The compound was further characterized physico-chemically by both mass spectrometry and nuclear magnetic resonance spectroscopy. No C₂₇ ecdysteroids (i.e. 20-hydroxyecdysone or ecdysone) were detected at this stage of development. This is the first isolation and identification of a 28-carbon ecdysteroid in an insect species from the order Hymenoptera. Utilization of dietary sterols by honey bees is also discussed.     

Humoral stimulation of the larval and adult prothoracic glands in Schistocerca gregaria

Fluctuations in ecdysteroid production by explanted prothoracic glands (PG) during the penultimate and last larval instars parallel changes in ecdysteroid titer in the hemolymph. The in vitro output of ecdysteroids increases up to 30-fold when PG are co-cultured with the brain. Maximal amounts of ecdysteroids are produced when both PG and brain are taken from larvae at the time of the molt-inducing ecdysteroid peaks (days 2–3 in the penultimate and days 5–6 in the last instar), and also from day 3 last instar larvae that exhibit a small rise of hemolymph ecdysteroids. Detailed investigations on penultimate instar larvae revealed that their PG become sensitive to the stimulation on day 1 (about 24 h after ecdysis), but the stimulatory brain potential is restricted to days 2 and 3. Both the stimulatory capacity of the brain and the sensitivity of PG are lost on days 4 and 5, i.e., after the ecdysteroid surge on day 3. PG explanted from young adults do not secrete appreciable amounts of ecdysteroids but can be stimulated to ecdysteroid production with active larval brains. Arch. Insect Biochem. Physiol. 36:85–93, 1997. © 1997 Wiley-Liss, Inc.     

In vitro stimulation of cell death in the moulting glands of Oncopeltus fasciatus by 20-hydroxyecdysone

The moulting glands of the milkweed bug, Oncopeltus fasciatus, normally degenerate just before the time of ecdysis to an adult (day 7 of the fifth instar). Morphologically normal cell death can be prematurely stimulated in vitro by 20-hydroxyecdysone. Breakdown is triggered by a 24-hr period of exposure to 20-hydroxyecdysone, but an additional incubation period is required before clear signs of degeneration are manifested. Glands removed after the onset of endogenous ecdysteroid secretion degenerate in vitro in the absence of added hormones. Thus, in the moulting glands of Oncopeltus, ecdysteroids appear to act as an important trigger for metamorphic cell death.