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.     

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).     

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.     

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.     

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.     

Metabolism of ecdysteroids by a chitin-synthesizing insect cell line

A chitin-synthesizing cockroach cell line (UMBGE-4) previously shown to secrete ecdysteroids was analyzed for its ability to metabolize potential precursors of ecdysone (e.g., 2-deoxyecdysone, 2,22-dideoxyecdysone, 2,22,25-trideoxyecdysone, and cholesterol). All, except cholesterol, were actively metabolized by UMBGE-4 cells. However, all but 2-deoxyecdysone were converted to polar and hydrolyzable metabolites, and not to ecdysone. Labeling with cholesterol was unsuccessful. Labeling experiments with molting hormones, i.e., ecdysone and 20-hydroxyecdysone, confirmed that this cell line can metabolize ecdysteroids and allowed identification of some of the products. Molting hormones were converted into acetate conjugates and polar conjugates which were often double-conjugates, i.e., polar conjugates of acetate conjugates. Labeling experiments with ecdysone demonstrated that this cell line possesses a low ecdysone 20-hydroxylase activity. The capacity of UMBGE-2 cells, which do not synthesize chitin or ecdysteroids, was also examined. Neither ecdysone nor 20-hydroxyecdysone was significantly metabolized by UMBGE-2 cells. 2-Deoxyecdysone and 2,22-dideoxyecdysone were very slowly metabolized respectively to more polar compounds.     

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.     

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.     

Comparative studies on ecdysone metabolism between mature larvae and pharate pupae in the fleshfly,Sarcophaga peregrina

Metabolites of radioactive ecdysone or 20-hydroxyecdysone in larvae and pharate pupae of Sarcophaga peregrina were separated and identified by using thin-layer chromatography, high-performance liquid chromatography, and chemical methods. At the larval stage ecdysone was metabolized to biologically less active ecdysteroids predominantly through 20-hydroxyecydsone, at the pharate pupal stage, to other ecdysteroids which were tentatively identified as 26-hydroxyecdysone, 3-epi-26-hydroxyecdysone, and 3-epi-20,26-dihydroxyecdysone. Ecdysteroid acids were found in the polar metabolites during pharate pupal-pupal transformation, but scarcely detected in the larval metabolites. These acids were presumed to be ecdysonoic acid, 20-hydroxyecdysonoic acid, and their epimers. The conjugates of ecdysteroid that released the free ecdysteroids by enzymatic hydrolysis were produced more in larvae than in pupae, whereas the very polar ecdysteroids that were not affected by the enzyme were found more in pupae. Therefore, there are different metabolic pathways of ecdysone between these two successive developmental stages, and the alteration of the metabolic pathway may serve as one of the important factors in a regulatory mechanism of molting hormone activity which is responsible for normal development of this insect.     

Ecdysone Metabolism in Diapause Eggs and Non-Diapause Eggs of the Silkworm, Bombyx mori

In order to compare ecdysone metabolism between diapause eggs and non-diapause eggs of the silkworm, Bombyx mori, (3)H-ecdysone and its derivatives ((3)H-3-epiecdysone and (3)H-ecdysone 22-phosphate) were injected into the eggs at various stages during early embryogenesis, and the resultant labelled metabolites were analyzed by high-performance liquid chromatography. From the quantitative and qualitative changes in the labelled metabolites between diapause eggs and non-diapause eggs, it was demonstrated that epimerization of ecdysone occurred during early embryogenesis irrespective of the embryonic stage in both diapause eggs and non-diapause eggs, and that phosphorylation of ecdysone was a major metabolic step in diapause eggs, whereas dephosphorylation of ecdysone 22-phosphate and its subsequent hydroxylation at the C-20 and C-26 positions were characteristic in non-diapause eggs.     

Molecular cloning of NADPH-cytochrome P450 oxidoreductase from silkworm eggs. Its involvement in 20-hydroxyecdysone biosynthesis during embryonic development.

Using RT-PCR, a cDNA fragment of NADPH-cytochrome P450 oxidoreductase from silkworm, Bombyx mori, was cloned from three-day-old nondiapause eggs. RACE was used to isolate the ends of the DNA. The full-length cDNA obtained was composed of 3471 bp with an open reading frame encoding a protein of 687 amino-acid residues with a relative molecular mass of 77 700. The protein, fused with glutathione S-transferase, was expressed in Escherichia coli and purified to homogeneity. The fused protein not only had NADPH-dependent cytochrome c-reducing activity, but also acted as an electron carrier from NADPH to bovine adrenal 21-hydroxylase P450 in the steroid hydroxylation reaction, confirming that the protein is the silkworm NADPH-cytochrome P450 oxidoreductase. Ecdysone 20-hydroxylase activity in the nondiapause egg microsomes increased until the fourth day after oviposition, and then decreased, little being detected on the ninth day. An antibody raised against the P450 reductase inhibited the ecdysone hydroxylation. Immunoblot analyses of the microsomes indicated that the P450 reductase protein appeared distinctly in the three-day-old nondiapause eggs and, in contrast to the developmental pattern of ecdysone hydroxylase activity, continued to increase as the embryos developed. These results suggest that ecdysone hydroxylation in the early stage of embryogenesis is dependent on the presence of both P450 reductase and ecdysone 20-hydroxylase P450, but its gradual reduction in the later stage may be due to the decrease in the level of ecdysone 20-hydroxylase P450.     

The metabolism of ingested and injected [3H]ecdysone by final instar larvae of Heliothis armigera

ABSTRACT. When larvae of Heliothis armigera (Hüber) are fed on a diet containing [³H]ecdysone they produce large quantities of ecdysone 22-palmitate, probably in the gut. The radiolabel is excreted in the faeces chiefly as ecdysone 22-palmitate, but appreciable quantities of unchanged ecdysone are also found together with traces of ecdysone 2-and 3-acetates. No polar metabolites are found with ingested ecdysone, and the ecdysone probably did not penetrate the gut wall, since on injection into the body, ecdysone was appreciably converted into polar metabolites.     

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.     

Ecdysteroids in the developing eggs of the desert locust, Schistocerca gregaria

Ecdysteroid levels in the developing eggs of Schistocerca gregaria were determined, at daily intervals, using gas chromatography and electron capture detection of ecdysteroid derivatives. Ecdysone and 20-hydroxyecdysone were present both as the free ecdysteroid and as polar conjugates. Total ecdysteroids reached a maximum of 40 ng/egg with ecdysone contributing the greater part.     

Ecdysteroids during early embryonic development in silkworm Bombyx mori: metabolism and functions

It has been well established that eggs of insects, including those of the silkworm Bombyx mori, contain various molecular species of ecdysteroids in free and conjugated forms. In B. mori eggs, 20-hydroxyecdysone (20E) is a physiologically active molecule. In nondiapause eggs, 20E is produced by the conversion of maternal conjugated ecdysteroids (ecdysteroid-phosphates) and by de novo biosynthesis. In contrast, in diapause eggs, neither of these metabolic processes occurs. In de novo biosynthesis of 20E in B. mori eggs, hydroxylation at the C-20 position of ecdysone, which is catalyzed by ecdysone 20-hydroxylase, is a rate-limiting step. Furthermore, we found that a novel enzyme, called ecdysteroid-phosphate phosphatase (EPPase), specifically catalyzes the conversion of ecdysteroid-phosphates to free ecdysteroids. The developmental changes in the expression pattern of EPPase mRNA correspond closely to changes in the enzyme activity and in the amounts of free ecdysteroids in eggs. EPPase is localized in the cytosol of yolk cells, and the bulk of maternal ecdysteroid-phosphates is bound to vitellin and stored in yolk granules. The vitellin-bound ecdysteroid-phosphates are scarcely hydrolyzed by EPPase. Therefore, to examine how ecdysteroid-phosphates are hydrolyzed by EPPase during embryonic development further investigations were focused on yolk granules. Recent data indicate that acidification in yolk granules, induced by vacuolar H(+)-ATPase, triggers the dissociation of ecdysteroid-phosphates from the vitellin-ecdysteroid-phosphates complex and the dissociated ecdysteroid-phosphates are released from yolk granules to the cytosol. To explain the process of the increase in the level of 20E during embryonic development in B. mori eggs, a possible model is proposed.     

Identification of ecdysone 22-long-chain fatty acyl esters in newly laid eggs of the cattle tick Boophilus microplus.

The five major apolar ecdysone esters present in newly laid eggs of the cattle tick Boophilus microplus have been purified by h.p.l.c. The quantities of the apolar esters present in the eggs were increased by administration of ecdysone to the mature females. G.c.-m.s. analysis, as their methyl esters, of the fatty acids released from the apolar ecdysone derivatives by alkali, coupled with positive-ion fast-atom-bombardment m.s. of the intact ecdysone esters, showed that the compounds consisted of a series of fatty acyl esters of ecdysone. The position of esterification of the ecdysone was established by p.m.r. spectroscopy. The combined data show that the novel apolar derivatives of ecdysone consist of the 22-palmitate, -palmitoleate, -stearate, -oleate, and -linoleate esters respectively. Confirmation was obtained by comparison with synthetic ecdysone 22-palmitate. The significance of the ecdysone fatty acyl esters as a possible source of free hormone during embryogenesis is discussed.     

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.     

抗水稻黄单胞菌的苏云金芽胞杆菌菌株筛选及其 活性物质

【目的】从400株苏云金芽胞杆菌菌株中筛选出拮抗水稻黄单胞菌活性最好的菌株YBT-2532,并对其抑菌活性物质进行分离。【方法】对苏云金芽胞杆菌YBT-2532产生的活性物质理化特性进行测定。【结果】该活性物质对温度、蛋白酶、pH均不敏感,70 °C处理1 h仍保留有75%的活性;活性物质在pH 2.0?12.0较稳定;该活性物质溶于甲醇、微溶于乙醇、不溶于丙酮、二氯甲烷和氯仿。利用凝胶过滤、离子交换层析、固相萃取、高效液相色谱技术,对抑菌组分进行分离,并通过HPLC-IT-MS方法确定其分子量。纯化的活性组分是一种分子量为797.8 Da的强极性水溶性小分子。【结论】该活性物质性质与已知的来源于苏云金芽胞杆菌的抗菌活性物质不同,可能为新型抗菌物质。     

Qualitative and quantitative analyses of juvenile hormone and ecdysteroids from the egg to the pupal molt in Trichoplusia ni

A method was developed to determine in the same extract juvenile hormone and various types of ecdysteroids in precisely staged eggs and larvae of Trichoplusia ni. Ecdysteroids were tentatively identified on the basis of their retention time in ion suppression reversed-phase HPLC and their cross-reactivity with two relatively non-specific, complimentary antibodies, whereas juvenile hormone was identified using reversed-phase HPLC combined with Galleria bioassay. Freshly laid eggs contained low levels of immunoreactive ecdysteroids. Mid-polar ecdysteroids increased in the phase of segmentation (14-18 h) and 1st larval cuticle formation (36-44 h), when 20-hydroxyecdysone and 20,26-dihydroxyecdysone were found to be predominant. Only traces of ecdysone and 26-hydroxyecdysone were seen. Toward hatching ecdysteroids decreased and represented mainly compounds more polar than 20,26-dihydroxyecdysone. In larval development ecdysteroids were low at the beginning of the feeding phases, increased toward cessation of feeding, and reached highest levels 12-15 h before ecdysis. In feeding stages ecdysone and 20-hydroxyecdysone were predominant, whereas in molting stages they were seen together with 20,26-dihydroxyecdysone and 20-hydroxyecdysonoic acid. The juvenile hormone titer was very low in freshly laid eggs and was high (approximately 25 ng/g) in embryos at the stage of 1st larval cuticle formation and eye pigmentation. In eggs we tentatively identified juvenile hormones I and II, whereas in larval stages juvenile hormone II appeared to be the predominant or exclusive juvenile hormone. Its titer fluctuated rapidly and was high in early 1st-instar larvae and again before the molts into the 3rd, 4th, and 5th instar. Highest titers were reached concomitant with the peak in 20-hydroxyecdysone 12-15 h before ecdysis.     

Formation of apolar ecdysteroid conjugates by ovaries of the house cricket Acheta domesticus in vitro.

The newly laid eggs of the house cricket Acheta domesticus contain apolar ecdysteroid conjugates, which we have hypothesized to be ecdysone long-chain fatty acyl esters [Whiting & Dinan (1988) J. Insect Physiol., in the press]. The ovaries of mature adult female A. domesticus in vitro convert [3H]ecdysone into apolar conjugates identical with those found in newly laid eggs. Comparison of the radioactive metabolites produced on incubation of [3H]ecdysone with various organs of adult female A. domesticus in vitro indicate that the fat-body is the major producer of polar ecdysteroid metabolites at this stage of development, whereas the ovaries are the major site of production of apolar metabolites. Apolar metabolites are also produced to a lesser extent by the crop, gut sections and the fat-body. Hydrolysis of radioactive metabolites produced by the ovaries with Helix enzymes releases only [3H]ecdysone, and thus ecdysone is not metabolized before conjugation by the ovaries. Formation of chemical derivatives (acetonide and acetates) of these 3H-labelled apolar conjugates strongly indicates that the position of conjugation is through the hydroxy group at C-22 of ecdysone. Extensive chromatographic analysis of the 3H-labelled apolar metabolites produced by the ovaries by t.l.c. and h.p.l.c. and comparison with authenticated reference compounds have conclusively demonstrated that the conjugates consist of ecdysone esterified at C-22 to a mixture of common long-chain fatty acids. The major fatty acyl esters have been identified and their percentage contribution to the mixture determined: laurate (0.5%), myristate (2.8%), palmitate (25.8%), stearate (8.4%), arachidate (1.0%), oleate (15.7%), linoleate (38.8%) and linolenate (2.1%). In addition there are three minor unidentified peaks, one of which has been tentatively identified as ecdysone 22-palmitoleate (2.6%). Comparison of this percentage composition with the previously published fatty acid composition of A. domesticus haemolymph [Wang & Patton (1969) J. Insect Physiol. 15, 851-860] reveals remarkable similarities, indicating that the acyl transferase(s) forming the conjugates have a broad specificity with regard to the fatty acyl substrate.