Feedback inhibition of ecdysone production by 20-hydroxyecdysone during pupal—adult metamorphosis of Mamestra configurata wlk

Large peaks of ecdysone (E, 2,875 ng/g live wt) and 20-hydroxyecdysone (20-HE, 2,150 ng/g live wt) occur on days 8 and 12, respectively, of postdiapause pupal-adult metamorphosis at 20°C in the bertha armyworm, Mamestra configurata, and then decline to low levels (< 100 ng/g live wt) prior to eclosion of the moth (50% eclosion at day 31.8). These peaks of E and 20-HE can be suppressed by treating the developing pupae with a physiological dose (2,500 ng/g live wt) of 20-HE. Suppression of E and 20-HE by 20-HE treatment was dose dependent, rapid (within 24 h of treatment) and permanent. The peaks of E and 20-HE were suppressed by 20-HE treatment on days 1, 3, 5, and 7 but the 20-HE peak was not suppressed by treatment on days 9 or 11. It is proposed that the mechanism by which 20-HE suppresses the production of E and thereby its own production forms a negative feedback loop that operates during the first 0.4 units of pupal-adult development in M. configurata. The function of the transitory peaks of E and 20-HE that form this feedback loop is currently unknown. Since most adults from pupae that had their ecdysteroid levels experimentally suppressed by 20-HE treatment were morphologically normal, it seems that the peaks of E and 20-HE have little or no function in controlling morphological development in pupae of M. configurata.     

The initiation of adult development in Sarcophaga argyrostoma by β-ecdysone

Sarcophaga argyrostoma pupae otherwise destined to diapause can be made to initiate prompt, complete adult development by injection of 0.2 to 0.3 μg β-ecdysone/g body weight, if the injection is given soon after head eversion at the time ecdysone levels would normally increase in developing animals. At these doses some animals show only the earliest signs of adult development and then enter diapause. After two weeks in diapause, a 40-fold higher dose (10 μg/g) is required to initiate development promptly. β-ecdysone can also accelerate the termination of diapause after a time delay which is dose-dependent. Doses of 6 to 10 μg/g lead to hyperhormonal abnormalities affecting antennae, genitalia, and bristle orientation.     

Stages of diapause development in the pupa of Mamestra configurata based on the β-ecdysone sensitivity index

Four distinct stages of diapause development in pupae of Mamestra configurata held at 20°C can be recognized by means of the ‘β-ecdysone sensitivity index’. The latter refers to the ED50 of injected β-ecdysone required to break diapause in half of the treated pupae. Stage 1 begins with the newly-formed pupa, lasts about 3.5 days and is characterized by a rapidly falling ED50. Stage 2 lasts about four weeks during which the ED50 increases by almost 20-fold, from 0.27 μg/g at the beginning to 4.9 μg/g at the end. Stage 3 begins when the pupae are about 4 weeks old and lasts for about six weeks. Stage 3 is the stable diapausing state and is characterized by a virtually unchanging ED50. The onset of stage 4 occurs when the pupae are about 10 weeks old and is recognized by the beginning of a decline in the ED50. Stage 4 precedes the completion of diapause development and may signal the transition of the endocrine system to its active state.Pupal diapause deepens with time in M. configurata. The deepening process evidently occurs during stage 2 of diapause development. Pupae that were transferred to 5°C at the beginning of stage 2 failed to make the transition to stage 3 and were trapped in a very shallow diapause.     

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

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

Water and carbohydrate levels at different developmental stages and dynamics in hibernating pupae of Pieris melete (Lepidoptera: Pieridae)

For insight into the physiological indicators of diapause in Pieris melete, water and carbohydrate (glycogen and trehalose) levels were measured under both natural and laboratory conditions. The highest water content (3.71–3.79 mg/mg dry weight) was found in larvae and developing pupae, which was substantially higher than in diapausing pupae (2.59 mg/mg dry weight). Water content was almost stable during diapause, except for individuals approaching diapause termination (3.43–3.58 mg/mg dry weight). The total carbohydrate level was significantly higher in pre‐pupae (47.41 μg/mg) compared to larvae (22.80 μg/mg) and developing pupae (21.48 μg/mg). The highest level of trehalose was detected in winter diapausing pupae, and no trehalose was found in larvae or developing pupae. Levels of glycogen were highest in pre‐pupae and lowest in diapausing pupae. Levels of total carbohydrate decreased as diapause proceeded, and no significant changes were found in trehalose levels for diapausing pupae under natural conditions or treated for 60–90 days at 5°C. Pupae treated at 20°C for 60–90 days had significantly lower levels of trehalose than those treated for 30 days. Glycogen content was relatively stable at 5°C, but increased after treatment under natural conditions and 20°C for more than 60 days. These results suggest that the dynamics of water and carbohydrate levels are potential physiological diapause indicators, which show metabolic differences between trehalose and glycogen during diapause development.     

A possible role of 20-hydroxyecdysone in embryonic development of the silkworm Bombyx mori

It has been well established that eggs of insects, including those of the silkworm Bombyx mori, contain various ecdysteroids and the amounts of these ecdysteroids fluctuate during embryonic development. In order to know the function of egg ecdysteroids in embryonic development of B. mori, we examined the biological activities of various egg ecdysteroids by in vitro ligand-binding assay and bioassay using B. mori eggs. First, using the ecdysteroid receptor of B. mori (BmEcR-B1/BmUSP heterodimer) prepared by yeast and Escherichia coli expression systems, the interaction between the ecdysteroid receptor and various egg ecdysteroids of B. mori was analyzed. The relative binding affinities of egg ecdysteroids to the BmEcR-B1/BmUSP heterodimer decreased in the order of 20-hydroxyecdysone > 2-deoxy-20-hydroxyecdysone > 22-deoxy-20-hydroxyecdysone > ecdysone > 2-deoxyecdysone > ecdysone 22-phosphate. Next, several egg ecdysteroids of B. mori were injected into the prospective diapause eggs, which show a very low level of free ecdysteroids at the onset of embryonic diapause (gastrula stage). Approximately 7% of them (P < 0.002, chi(2)-test) developed beyond the gastrula stage without entering diapause by the injection of 20-hydroxyecdysone (25 ng/egg). In contrast, the injection of other ecdysteroids was not effective in inducing embryonic development. These results suggest that 20-hydroxyecdysone, via the ecdysteroid receptor, is responsible for the developmental difference between diapause and non-diapause in B. mori embryos. Furthermore, it was suggested that continuous supply of 20-hydroxyecdysone may be required to induce embryonic development.     

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.     

棉铃虫蛹期血淋巴的蜕皮甾类

目前为止仅在少数几种昆虫中研究过蛹期的蜕皮激素。关于蜕皮甾类的性质分析,结果也颇不一致。本文采用放射免疫分析、薄层层析、高压液相色谱及质谱对棉铃虫Heliothis armigera蛹血淋巴内的蜕皮激素进行了研究。结果如下:1.物理-化学方法证明蛹血淋巴内存在二种蜕皮甾类:蜕皮酮和20-羟基蜕皮酮。2.蛹期蜕皮甾类滴度呈一宽峰,高峰出现在化蛹后的第5天(3435ng/ml)。3.在高峰时,蜕皮酮与20-羟基蜕皮酮的比例为1:3.57,说明20-羟基蜕皮酮是主要的蜕皮甾类。4.比较雌雄两性蛹的蜕皮甾类滴度,未见明显差异。研究表明在棉铃虫中影响成虫发育的主要激素是20-羟基蜕皮酮而不是蜕皮酮。     

Hormonal control of seasonal morphs by the timing of ecdysteroid release in Araschnia levana L. (Nymphalidae: Lepidoptera)

Araschnia levana L. occurs in two seasonal morphs. Larvae reared under short-day conditions become diapause pupae and emerge as red spring-morph butterflies. Long-day larvae become non-diapause pupae, which emerge as black and white summer morphs. Pupae reared under these different conditions were joined in parabiosis. Both underwent adult development without diapause and the long-day animals developed into the summer morph as normal. The morph of short-day animals depended on the time of parabiosis. When they were joined to fresh long-day pupae 1 day after their own pupation, summer morphs resulted. When parabiosis began 4 days after pupation or later, spring morphs resulted. Extirpation of the brain-corpora cardiaca-allata complex from long-day pupae affected neither non-diapause development nor the summer morph. Adult development could be prevented by removal of head and prothorax. When adult development was initiated in the remaining bodies by 20-hydroxyecdysone 14 days after pupation, the spring morph resulted.—Injection of 20-dydroxyecdysone into 3-day-old short-day pupae initiated adult development and led to the summer morph. Injections into 10-day-old short-day pupae led to the spring morph. The same was true in diapause pupae deprived of their brain-corpora cardiaca-allata complex. These results indicate that seasonal diphenism in A. levana is controlled only by the timing of ecdysteroid release, which initiates adult development. There is no direct influence of the brain on wing coloration.     

Identification of 20-hydroxyecdysone and ecdysone from the pupa of the gypsy moth,Lymantria dispar

Normal and reverse-phase high-performance liquid chromatography in conjunction with radioimmunoassay and mass spectrometry were used to identify the free and conjugated ecdysteroids (after enzymatic hydrolysis) from day-4 pupae of the gypsy moth, Lymantria dispar L. Seven ecdysteroids were searched for, but only 20-hydroxyecdysone (964 ng/g fresh weight) and ecdysone (367 ng/g fresh weight) were detected. Analysis of conjugated ecdysteriods after liberation by hydrolysis also indicated the presence of 20-hydroxyecdysone (21.6 ng/g fresh weight) and ecdysone (2.4 ng/g fresh weight). Neither 26-hydroxyecdysone nor the 3α-epimers of 20-hydroxyecdysone or ecdysone were detected.     

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.     

Ecdysteroids and diapause in pupae of Heliothis punctiger

Most pupae of H. punctiger enter diapause when reared at 19°C, 12L:12D. When pharate pupae were treated for only 12 hr at 28°C about 50% developed at 19°C. The proportion of non-diapausing pupae increased as the temperature at which the pharate pupal stage was spent increased.The quantity of injected 20-hydroxyecdysone necessary to promote development in diapausing pupae varied from about 1 μg g^?1 soon after pupation to about 4 μg g^?1 after 50 days. It fell somewhat after 150 days.Removing brains from non-diapausing pupae showed that the brain secreted its hormone at the time of pupation (or just before). However, if the pupae were kept at 19°C development did not occur unless the brain remained in situ for at least 20 hr at 28°C. Implanting brains from non-diapausing pupae into diapausing ones had no measurable effect.These results may be explained by postulating that the prothoracic gland is ‘activated’ by exposure to high temperature, but that it reverts to inactivity over a period at 19°C. The ‘active’ gland must then be stimulated by brain hormone for a long period to trigger secretion of its hormone, which results in development. Diapause is thus the result of the failure of the prothoracic gland to secrete.     

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

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

The 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).     

Temperature-dependent development and survival of the lesser mealworm, Alphitobius diaperinus

Abstract. Development, growth and survival of the lesser mealworm, Alphitobius diaperinus (Panzer), were determined at six constant temperatures. No egg hatch or larval development occurred at 17^oC. At temperatures of 20, 25, 30, 35 and 38^oC the median development times (days), respectively, were for eggs (13.4, 6.0, 4.4, 2.6 and 2.6), larvae (133.0, 46.0, 26.2, 22.4 and 23.9), pupae (17.0, 8.0, 5.5, 4.0 and 4.1), and from oviposition to adult emergence (164.4, 60.2, 37.9, 29.0 and 30.8). The Sharpe & DeMichele (1977) model was used to describe the temperature-dependent development. The mean egg survival (hatching) ranged from 61% to 86%, with lowest hatch at 20^oC. Survival of the larvae and pupae ranged from 32% to 73% and from 85% to 95%, respectively, with lowest survival at 20^oC. Pupae had significantly lower weights at 35^oC and adults at 38^oC than at the other temperatures. Female pupae (20 mg) and female adults (16 mg) were significantly heavier than male pupae (17 mg) and male adults (13 mg). Adults (0.5–9 months old) laid 4–7 eggs per female per day at 25^oC.     

Diapause Induction and Termination in Hyphantria cunea (Drury) (Lepidoptera: Arctiinae)

The fall webworm, Hyphantria cunea (Drury), enters facultative diapause as a pupa in response to short-day conditions during autumn. Photoperiodic response curves showed that the critical day length for diapause induction was 14 h 30 min, 14 h 25 min and 13 h 30 min at 22, 25 and 28°C, respectively. The photoperiodic responses under non-24 h light–dark cycles demonstrated that night length played an essential role in the determination of diapause. Experiments using a short day length interrupted by a 1-h light pulse exhibited two troughs of diapause inhibition and the effect of diapause inhibition was greater in the early scotophase than in the late scotophase. The diapause-inducing short day lengths of 8, 10 and 12 h evoked greater intensities of diapause than did 13 and 14 h. Diapause can be terminated without exposure to chilling, but chilling at 5°C for 90 and 120 d significantly accelerated diapause development, reduced mortality, and synchronized adult emergence. Additionally, the potential for H. cunea from the temperate region (Qingdao) to emerge and overwinter under field conditions in subtropical regions (Nanchang) of China was evaluated. Pupae that were transferred to Nanchang in early July showed a 60% survival rate and extremely dispersed pupal period (from 12 to 82 days), suggesting that some pupae may undergo summer diapause. Diapausing temperate region pupae that were moved out-of-doors in Nanchang during October showed approximately 20% overwintering survival; moreover, those pupae that overwintered successfully emerged the next spring during a period when their host plants would be available. The results indicate that this moth has the potential to expand its range into subtropical regions of China.     

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.     

Fungal ecdysteroid-22-oxidase, a new tool for manipulating ecdysteroid signaling and insect development

Steroid hormones ecdysteroids regulate varieties of developmental processes in insects. Although the ecdysteroid titer can be increased experimentally with ease, its artificial reduction, although desirable, is very difficult to achieve. Here we characterized the ecdysteroid-inactivating enzyme ecdysteroid-22-oxidase (E22O) from the entomopathogenic fungus Nomuraea rileyi and used it to develop methods for reducing ecdysteroid titer and thereby controlling insect development. K(m) and K(cat) values of the purified E22O for oxidizing ecdysone were 4.4 μM and 8.4/s, respectively, indicating that E22O can inactivate ecdysone more efficiently than other ecdysteroid inactivating enzymes characterized so far. The cloned E22O cDNA encoded a FAD-dependent oxidoreductase. Injection of recombinant E22O into the silkworm Bombyx mori interfered with larval molting and metamorphosis. In the hemolymph of E22O-injected pupae, the titer of hormonally active 20-hydroxyecdysone decreased and concomitantly large amounts of inactive 22-dehydroecdysteroids accumulated. E22O injection also prevented molting of various other insects. In the larvae of the crambid moth Haritalodes basipunctalis, E22O injection induced a diapause-like developmental arrest, which, as in normal diapause, was broken by chilling. Transient expression of the E22O gene by in vivo lipofection effectively decreased the 20-hydroxyecdysone titer and blocked molting in B. mori. Transgenic expression of E22O in Drosophila melanogaster caused embryonic morphological defects, phenotypes of which were very similar to those of the ecdysteroid synthesis deficient mutants. Thus, as the first available simple but versatile tool for reducing the internal ecdysteroid titer, E22O could find use in controlling a broad range of ecdysteroid-associated developmental and physiological phenomena.     

外源保幼激素对中华通草蛉滞育解除及滞育后发育的影响

[目的]本研究旨在明确外源保幼激素(juvenile hormone,JH)在中华通草蛉Chrysoperla sinica滞育快速解除过程中的使用剂量及最佳使用时期.[方法]测定点滴不同剂量(0,5,15,25和35 μg/成虫)外源JH后中华通草蛉滞育成虫的产卵前期、产卵历期、雌虫寿命及单雌产卵量,以及15 μg/...     

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.