Biosynthesis of ecdysteroids by prothoracic glands in Pieris brassicae (Lepidoptera insect). Conversion in vitro of radiolabelled precursor of 3-dehydroecdysone]

Ecdysteroids secreted by prothoracic glands of Pieris brassicae were measured by enzyme immunoassay, after HPLC separation. Both ecdysone and 3-dehydroecdysone, as a major product, are produced. Two radiolabelled putative precursors were converted by Pieris glands in vitro: [3H] ketodiol was converted into ecdysone at a low rate; [3H]3-oxoketodiol was efficiently converted, mainly into 3-dehydroecdysone. These data make 3-oxoketodiol a good candidate for an intermediate in ecdysteroid biosynthetic pathway.     

An in vitro study on regulation of prothoracic gland activity in the early last-larval instar of the silkworm Bombyx mori

The endocrine mechanisms that regulate prothoracic gland (PG) activity in early stages of final larval instar of the silkworm Bombyx mori were investigated using a newly developed long-term cultivation system of the gland. The PGs dissected from day-0 fifth instar larvae did not secrete detectable amounts of ecdysone for the first 24 h in culture but started secretion within the next 2 days. The amount of secreted ecdysone increased day by day. When day-0 PGs were co-cultivated with corpora allata, however, they remained inactive for at least 8 days. PGs dissected from 1-day younger larvae (day-3 fourth instar larvae) secreted ecdysone for the first 24 h but stopped secretion for the next 24 h, followed by recovery of ecdysone secretory activity. By contrast, PGs from day-1 fourth instar larvae remained active throughout a cultivation period without any sign of inactivation. However, when the same glands were exposed to a high titer of 20-hydroxyecdysone for the second 24h in culture, they gradually lost their activity. These results indicate that PGs of fourth instar larvae are inactivated by ecdysteroid through a negative feedback mechanism and that thus inactivated PGs spontaneously recover ecdysone secretory activity in the early fifth instar unless inhibited by juvenile hormone.     

Hormonal mechanisms underlying termination of larval diapause by juvenile hormone in the bamboo borer, Omphisa fuscidentalis

Topical application of methoprene, a juvenile hormone analogue (JHA), induces pupation by activating the prothoracic glands (PGs) in diapausing larvae of the bamboo borer, Omphisa fuscidentalis. To determine the minimum stimulation period for PG activation, we transplanted PGs of JHA-treated larvae (donors) into non-treated larvae (recipients) on successive days after JHA treatment and observed the recipients for pupation. JHA stimulation for 1 day was sufficient to induce pupation. In recipient larvae, the hemolymph ecdysteroid titer increased transiently on day 18 after transplantation and significantly on days 24-28, prior to pupation. Secretory activity of recipient PGs increased transiently on day 16 and days 22-28. Because the recipient PG activity was too low to account for an increased ecdysteroid titer, the JHA-stimulated donor PGs must produce the major part of hemolymph ecdysteroids. In addition, the ecdysteroid produced by the donor PGs might have stimulated the recipient PGs. We examined the possible involvement of two ecdysone receptor (EcR) isoforms, OfEcR-A and OfEcR-B1, in PG activation by JHA, and found that although both isoforms were up-regulated, accompanied by an increased ecdysteroid titer in the hemolymph, the isoform mRNA levels were not altered at all before the increase in PG secretory activity. Thus, EcR expression might not be involved in feedback activation of PGs.     

Involvement of 3-dehydroecdysone in the 3-epimerization of ecdysone.

The epimerization of ecdysone to 3-epiecdysone has been investigated in a dialysed cytosolic enzyme preparation from midgut of sixth instar Spodoptera littoralis larvae, with particular emphasis on establishing the intermediacy of 3-dehydroecdysone. Incubation of ecdysone with the dialysed cytosolic preparation furnished 3-dehydroecdysone as the only detectable product, the reaction being oxygen-dependent. The enzyme preparation catalysed reduction of 3-dehydroecdysone to 3-epiecdysone and ecdysone in the presence of NADH or NADPH. Whereas formation of 3-epiecdysone greatly predominated over that of ecdysone in the presence of NADPH, the converse applied when the cofactor was NADH. 3-Epiecdysone incubated with the enzyme preparation in the presence of various cofactors was not metabolized, indicating the irreversibility of the reduction of 3-dehydroecdysone to 3-epiecdysone and, hence, of the 3-epimerization process. The foregoing results, together with comparison of the metabolism of 3-dehydro[3H]ecdysone and [3H]ecdysone by the enzyme preparation in the presence of unlabelled ecdysone and NADPH, support the intermediacy of 3-dehydroecdysone in the 3-epimerization of ecdysone.     

The effect of glucose on the activity of phosphofructokinase in the mucosa of rat small intestine.

Maturing eggs of the desert locust, Schistocerca gregaria, contain a variety of ecdysteroid (insect moulting hormone) conjugates and metabolites, four of which have been previously isolated from polar extracts and identified as ecdysonoic acid, 20-hydroxyecdysonoic acid, 3-acetylecdysone 2-phosphate and ecdysone 2-phosphate. In the present study we have isolated eight additional ecdysteroids from similar late-stage eggs by high-performance liquid chromatography. The 22-phosphate esters of ecdysone, 2-deoxyecdysone, 20-hydroxyecdysone and 2-deoxy-20-hydroxyecdysone, all of which were first identified as ecdysteroid components of newly-laid eggs of S. gregaria, were identified by co-chromatography with authentic compounds and by physicochemical techniques. The remaining compounds were identified as 3-acetyl-20-hydroxyecdysone 2-phosphate, 3-epi-2-deoxyecdysone 3-phosphate, 3-acetylecdysone 22-phosphate and 2-acetylecdysone 22-phosphate by fast atom bombardment mass spectrometry, p.m.r. spectroscopy and analysis of the steroid moieties after enzymic hydrolysis. The latter two compounds, after isolation, are susceptible to nonenzymic acetyl migration and deacetylation to give mixtures of ecdysone 22-phosphate and its 2- and 3-acetate derivatives. The possible role and significance of these ecdysteroid conjugates with respect to the control of hormone titres in insect eggs is discussed.     

Mechanism of hydroxylation at C-22 during the biosynthesis of ecdysteroids in the locust Schistocerca gregaria.

1. The fates of the 22-pro-R and 22-pro-S hydrogen atoms of cholesterol during the biosynthesis of ecdysteroids in the ovaries of Schistocerca gregaria were investigated. 2. Two stereospecifically labelled cholesterol species, obtained by incubating 3R,2R- and 3R,2S-[2-14C, 2-3H]mevalonic acid with rat liver preparations, were administered, in turn, to maturing adult female locusts and the radiolabelled ecdysteroid conjugates isolated from the eggs. Enzymic hydrolysis of the conjugates yielded free ecdysteroids, from which ecdysone was purified. 3. Derivative formation and oxidation at C-22 of both ecdysone samples indicated that the 22-pro-R and 22-pro-S hydrogen atoms of cholesterol were stereospecifically eliminated and retained respectively during ecdysteroid formation. This indicates that C-22 hydroxylation in ecdysone biosynthesis is direct and occurs with retention of configuration.     

Venom from the ectoparasitoid wasp Eulophus pennicornis disrupts host ecdysteroid production by regulating host prothoracic gland activity

Abstract. Attack by the ectoparasitoid Eulophus pennicornis Nees (Hymenoptera: Eulophidae) prevents larvae of Lacanobia oleracea L. (Lepidoptera: Noctuidae) from moulting. Prothoracic glands (PGs) excised from parasitized or artificially envenomated hosts show a reduced basal level of ecdysteroid release at a time when non-parasitized caterpillars produce an ecdysteroid surge (48 h post moult to 5th stadium = penultimate stadium in non-venomated hosts). By contrast, PGs from similarly parasitized or envenomated caterpillars release comparatively high levels of ecdysteroid at 120 h post-moult. Temporary inactivation of PGs cannot be attributed solely to a parasitoid-induced reduction in cell viability, and incubation in E. pennicornis venom in vitro does not exert any direct effect on either PG cell viability or ecdysteroid release. However, inactivated PGs are not stimulated by forskolin, which may indicate that the absence of the required pre-moult ecdysteroid surge in developmentally arrested L. oleracea is due to insensitivity to a prothoracicotropic hormone. Even though parasitized caterpillars never moult, reversed-phase HPLC separations and radioimmunoassay confirm that they produce active moulting hormone (20-hydroxyecdysone) at 120 h post-moult. These results suggest that E. pennicornis arrests host development through the indirect effects on their hosts' PGs. This effect is not achieved through the destruction of gland cells, but more likely reflects the interruption of an innate cycle in PG activity, such that they lose their ability to respond to a normal cue to produce an essential hormone peak at a crucial point in development.     

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.     

Catalytical oxidation of ecdysteroids to 3-dehydro products and their biological activities

Oxidation of ecdysone and ecdysterone with platinum as catalyst gives rise to several polar and 4–5 apolar substances, among them 3-dehydroecdysone and 3-dehydroecdysterone. Highest yields in the 3-dehydro products were reached after 4 to 8 hr of oxidation. 3-dehydroecdysone and 3-dehydroecdysterone are less active in inducing ecdysone specific puffs in Drosophila hydei salivary gland giant chromosomes but still contain a remarkable biological activity when compared with the original ecdysteroids. The activity of these two compounds is about one tenth that of ecdysone in the Calliphora assay.     

Ecdysteroid release by the prothoracic gland of Gryllus bimaculatus (Ensifera: Gryllidae) during larval-adult development

The in vitro secretion of ecdysteroids from the prothoracic glands of larvae of Gryllus bimaculatus was analysed by HPLC-RIA. The primary product was identified as 3-dehydroecdysone (65-93%), with lesser amounts of ecdysone (7-35%). Production and release of ecdysteroids from the prothoracic glands are calcium-dependent. The rate of ecdysteroid release was low during the beginning and the end of the last two larval stages and high in between. Prothoracic glands from young adult females produced only minor amounts of ecdysteroids and ceased hormone production around day 4 after the moult.     

Ecdysteroid titre and metabolism to novel apolar derivatives in adult female Boophilus microplus (Ixodidae)

The free ecdysteroid titre determined by radioimmunoassay in adult female Boophilus microplus showed a peak just prior to full engorgement and detachment of the ticks and decreased subsequently to a very low value. In contrast, the titre of polar ecdysteroid conjugates was very low. Ecdysone was the major ecdysteroid at peak titre and was accompanied by much lower levels of 20-hydroxyecdysone. In newly detached ticks, injected [³H]ecdysone was metabolized primarily (80%) into much less polar compounds, which could be resolved into at least three groups by reversed-phase h.p.l.c. These [³H] “apolar” metabolites were transferred to the newly laid eggs, where they accounted for the vast preponderance of ecdysteroids, the level of free hormone being low. Hydrolysis of the three groups of compounds with an esterase preparation from porcine liver yielding [³H]ecdysone, together with the release of [³H] ecdysteroid and fatty acids upon alkaline saponification of the compounds, suggests that they are of a fatty acyl ester nature. The chemical transformation of these “esters” into the corresponding acetonide derivatives indicates that the 2- and 3-hydroxyls of ecdysone remain unsubstituted in these compounds. Several tick tissues, including Malpighian tubules, ovaries, gut, and fat body, metabolized [³H]ecdysone in vitro forming the “apolar esters” as major products. The maternal ecdysteroid “esters” may function as storage forms of hormone (presumably hormonally inactive), which could be hydrolysed enzymically during embryogenesis releasing free ecdysteroids. Such enzymic hydrolysis of [³H]ecdysone “esters” by homogenates from developing eggs of B. microplus has been demonstrated.     

Isolation and identification of 3-acetylecdysone 2-phosphate, a metabolite of ecdysone, from developing eggs of Schistocerca gregaria.

A major ecdysteroid conjugate, which accumulates in the eggs of the desert locust, Schistocerca gregaria, during the later stages of embryogenesis, has been isolated by reversed-phase and anion-exchange high-performance liquid chromatography. Hydrolysis of the conjugate with a crude arylsulphatase preparation from Helix pomatia liberates mainly ecdysone 3-acetate. The compound was identified as 3-acetylecdysone 2-phosphate by phosphate analysis of an acid-hydrolysed sample, fast atom bombardment, electron impact and chemical ionization mass spectrometry and 1H and 13Cn.m.r. spectroscopy. The instability of 3-acetylecdysone 2-phosphate on storage results in the formation of ecdysone 2-phosphate, which was identified by physicochemical techniques. 3-Acetylecdysone 2-phosphate and ecdysone 2-phosphate are less susceptible than ecdysone 22-phosphate to hydrolysis in vitro by an enzyme preparation from S. gregaria embryos. The possible role of 3-acetylecdysone 2-phosphate as an inactive end product of ecdysteroid metabolism is discussed.     

Differences between recombinant PTTH and crude brain extracts in cAMP-mediated ecdysteroid secretion from the prothoracic glands of the silkworm,Bombyx mori

The ability of recombinant prothoracicotropic hormone (rPTTH) or crude brain extract (cBRAIN) of Bombyx mori to stimulate ecdysteroid secretion from prothoracic glands (PGs) was investigated throughout the fifth instar and the first day of the pupal stage. Crude brain extracts could stimulate much higher ecdysteroid secretion than rPTTH during a 2h incubation. Recombinant PTTH did not increase the level of glandular cyclic AMP, except on days 4 and 5 of the fifth instar. Glandular cAMP levels were increased by cBRAIN from day 0 until day 5 of the fifth instar with the highest increase on day 3. On this day, rPTTH could not stimulate any increase of ecdysteroid secretion from the PGs during a 30min incubation. On the contrary, PGs incubated with cBRAIN for 30min showed increased secretory activity. Furthermore, on day 3 and in the absence of extracellular Ca(2+), rPTTH did not increase the glandular cAMP levels but cBRAIN did. Recombinant PTTH-stimulated ecdysteroid secretion from day 3 PGs was dependent on extracellular Ca(2+) in a dose-dependent manner. However, cBRAIN could stimulate ecdysteroid secretion even in the absence of extracellular Ca(2+). Taken together, the results of these experiments suggest the presence of a previously unknown cerebral prothoracicotropic factor that can stimulate glandular cAMP levels and ecdysteroid secretion from the PGs of Bombyx mori.     

CYP306A1, a cytochrome P450 enzyme, is essential for ecdysteroid biosynthesis in the prothoracic glands of Bombyx and Drosophila

Ecdysteroids mediate a wide variety of developmental and physiological events in insects. In the postembryonic development of insects, ecdysone is synthesized in the prothoracic gland (PG). Although many studies have revealed the biochemical and physiological properties of the enzymes for ecdysteroid biosynthesis, most of the molecular identities of these enzymes have not been elucidated. Here we describe an uncharacterized cytochrome P450 gene, designated Cyp306a1, that is essential for ecdysteroid biosynthesis in the PGs of the silkworm Bombyx mori and fruit fly Drosophila melanogaster. Using the microarray technique for analyzing gene expression profiles in PG cells during Bombyx development, we identified two PG-specific P450 genes whose temporal expression patterns are correlated with changes in ecdysteroid titer during development. Amino acid sequence analysis showed that one of the Bombyx P450 genes belongs to the CYP306A1 subfamily. The temporal and spatial expression pattern of the Drosophila Cyp306a1 homolog is essentially the same as that of Bombyx Cyp306a1. We also found that Drosophila Cyp306a1 is disrupted in the phantom (phm) mutant, known also as the Halloween mutant. The morphological defects and decreased expression of ecdysone-inducible genes in phm suggest that this mutant cannot produce a high titer of ecdysone. Finally we demonstrate that S2 cells transfected with Cyp306a1 convert ketodiol to ketotriol via carbon 25 hydroxylation. These results strongly suggest that CYP306A1 functions as a carbon 25 hydroxylase and has an essential role in ecdysteroid biosynthesis during insect development.     

Mechanism of hydroxylation at C-2 during the biosynthesis of ecdysone in ovaries of the locust, Schistocerca gregaria.

The stereochemistry of hydroxylation at C-2 during the biosynthesis of ecdysone in the ovaries of Schistocerca gregaria was investigated by incorporation of [1 alpha,2 alpha-3H(n)]cholesterol in admixture with [4-14C]cholesterol into oöcyte 2-deoxyecdysone and ecdysone conjugates in maturing adult female S. gregaria. Extraction of the eggs followed by enzymic hydrolysis of the ecdysteroid conjugate fraction yielded free ecdysteroids, from which 2-deoxyecdysone and ecdysone were purified. The 3H/14C ratios in the 2-deoxyecdysone and ecdysone were similar, suggesting that the 2 alpha hydrogen of cholesterol was retained during hydroxylation at C-2. This was corroborated by oxidation at C-2 of the 3,22-diacetate derivative of the ecdysone, yielding the corresponding 2-oxo compound with removal of essentially all the 3H originally present at the 2 alpha position of cholesterol. The results indicate that the 2 beta hydrogen of cholesterol has been eliminated during the hydroxylation at C-2. Thus, during ecdysone biosynthesis, hydroxylation at C-2 is direct and occurs with retention of configuration.     

Ecdysone 20-hydroxylation and 3-epimerization in larvae of the gypsy moth,Lymantria dispar L.: tissue distribution and developmental changes

The potential for ecdysone metabolism was determined for various larval tissues of the gypsy moth, Lymantria dispar. Homogenates of fat body, midguts, and Malpighian tubules, taken on different days during the second half of the fifth instar, were incubated with [(3)H]ecdysone, and the products were analyzed by reversed-phase and normal-phase HPLC. All tissues showed conversion to 20-hydroxyecdysone, and midguts also produced 3-epiecdysone. Ecdysone 20-monooxygenase (E20MO) activity in the fat body increased from a low level on day 5 to a peak on day 11, coinciding with the peak in the hemolymph ecdysteroid titer on the penultimate day of the instar. Midguts and Malpighian tubules showed E20MO activity only during the last 3 or 4days of the instar, with the highest activity also occurring on the penultimate day. For the midguts, the appearance of the E20MO coincided with the transition from larval to pupal tissue. No activity was detected in larval midguts. 3-Epiecdysone formation, however, was mainly found in larval midguts, with only marginal activity detectable in pupal midguts.     

Downregulation of the cAMP signal transduction cascade in the prothoracic glands is responsible for the fenoxycarb-mediated induction of permanent 5th instar larvae in Bombyx mori

Fenoxycarb application at 48 h (day 2) of the 5th instar of Bombyx mori induced permanent larvae with prothoracic glands (PGs) exhibiting weak ecdysteroidogenic activity. Although glands from control and fenoxycarb-treated larvae exhibited similar responses to dibutyl cAMP and forskolin on day 2, forskolin could not stimulate ecdysteroid secretion from PGs of fenoxycarb-treated larvae on day 3. Glands from control larvae incubated with cholera toxin (CTX) on day 3 had increased cAMP content and enhanced ecdysteroid secretion. Cholera toxin did not stimulate ecdysteroid secretion and marginally increased cAMP content in day 3 PGs of fenoxycarb-treated larvae. After application of fenoxycarb on day 2, crude brain extracts (cBRAIN) could not increase the glandular cAMP content throughout the rest of the 5th instar of the treated larvae. Fenoxycarb did not affect the basal or cBRAIN-stimulated cAMP accumulation in control PGs on day 2 and day 3 in vitro. Application of fenoxycarb on day 2 did not affect the recombinant PTTH (rPTTH)-stimulated ecdysteroid secretion on day 3, but reduced the cBRAIN-stimulated ecdysteroid secretion on day 3 to levels similar to that of rPTTH. The combined results suggest that the cAMP signalling cascade in the PGs of B. mori becomes nonfunctional after fenoxycarb application on day 2 of the 5th instar.