Autonomous yolk protein synthesis in ovaries ofDrosophila cultured in vivo

Summary Immature ovaries ofDrosophila mercatorum were injected into young larvae and into adult males ofD. mercatorum, D. melanogaster, D. hydei, D. virilis, andZaprionius vittiger. These homo- and heteroplastic transplantations allow normal vitellogenesis to occur in the donor ovary. By SDS gel electrophoresis, we identified the major species-specific yolk proteins of mature eggs (stage 14) which were exclusively of donor-specific origin. Other experiments withD. hydei andZ. vittiger showed that, when females were used as hosts, the host-specific yolk proteins became incorporated into the donor eggs. When two immature ovaries, one ofD. mercatorum and one ofD. hydei, were co-cultured in males, again only the donor-specific yolk proteins were found in the mature eggs implying that these yolk proteins were not released into the host hemolymph.A parthenogenetic strain ofD. mercatorum was used to demonstrate the ability of transplanted immature ovaries to produce viable eggs which can give rise to fertile adults.The role of the species-specific yolk proteins is discussed with respect to the dual origin of these proteins during normal vitellogenesis, i.e., an autonomous synthesis within the ovary itself in addition to the well-known production by the fat body. Further experiments with pupae as hosts indicate that even in the absence of juvenile hormone and in the presence of high doses of ecdysone, vitellogenesis can proceed within the donor ovary.Based on these experiments, a new hyopthesis on the hormonal control of vitellogenesis inDrosophila is presented. We propose that yolk proteins derived from the fat body are controlled by juvenile hormone, whereas the independent and autonomous vitellogenesis within the ovary itself is controlled by endogenously synthesized ecdysone.     

Insulin signaling is necessary for vitellogenesis in Drosophila melanogaster independent of the roles of juvenile hormone and ecdysteroids: female sterility of the chico1 insulin signaling mutation is autonomous to the ovary

It has been suggested that insulin signaling mutations of Drosophila melanogaster are sterile and long-lived because of juvenile hormone (JH) and ecdysteroid deficiency. However, female sterility of an insulin/IGF-like signaling mutant (chico(1)) of D. melanogaster is not mediated by downstream systemic signaling in terms of major alterations in JH or ecdysteroid levels. chico(1) is a null mutation in the insulin substrate protein (CHICO) gene of D. melanogaster. Homozygous chico(1) females are sterile and their oocytes do not mature beyond the last previtellogenic stage. Homozygous chico(1) females exhibit approximately wild-type rates of JH biosynthesis, ovarian release of ecdysteroids and haemolymph ecdysteroid levels, suggesting that these two major hormone systems play no role in producing the sterility. Previtellogenic wild-type ovaries transplanted into homozygous chico(1) females underwent vitellogenesis, showing that systemic factors present in mutant females are sufficient to support normal vitellogenesis. chico(1) ovaries transplanted into wild-type females did not undergo vitellogenesis indicating that CHICO is necessary in the ovary for vitellogenic maturation. The ovary transplant experiments corroborate the endocrine results and demonstrate that insulin/insulin-like signaling (IIS) is necessary for vitellogenesis even when sufficient levels of JH, ecdysteroids or other factors are present.     

Monitoring the effects of juvenile hormones and 20-hydroxyecdysone on yolk polypeptide production of Drosophila melanogaster with enzyme immunossay

ABSTRACT. A double antibody sandwich enzyme-linked immunosorbent assay (ELISA) was developed for detecting and quantifying small amounts of yolk polypeptides (YP) in studies on the hormonal control of vitellogenesis in Drosophila melanogaster Meigen. Monoclonal antibodies were incorporated as primary antibodies in the ELISA procedure to ensure selectivity in YP detection. The fact that YP concentration increases immediately after adult eclosion presents some difficulties in designing hormonal regulation experiments. Female adults decapitated immediately after eclosion remain alive for several days and virtually no YP is detected in the haemolymph 24 h after decapitation. The surgical procedure does not interfere with the competence of the fat bodies to respond to exogenous source of hormones. The effect of juvenile hormone (JH) on vitellogenesis can be studied by topical application of test material to these decapitated adults. A juvenile hormone analogue. Methoprene applied at 0.2 μg/fly or greater, restores YP production. The relative potencies of JH I₂ II₃ III and ZR 515 are compared at the same dose of 0.25 μg/fly. Their ranking in terms of re-initiating vitellogenesis is ZR-515 < JH IIFat bodies which are left attached to the body wall, are successfully maintained in culture. With this in vitro system, synthetic hormone can be administered precisely to the organ culture. After a short incubation period, aliquots of medium are removed for the quantification of YP. Incubation of fat bodies with a physiological dose of the 20-hydroxyecdysone (20-HE) stimulates the production and release of YP into the medium. This represents the first direct experimental evidence for 20-HE stimulation of Drosophila fat bodies for YP production in the absence of other endogenous factors that might either promote or interfere with vitellogenesis     

The Regulation of yolk polypeptide synthesis in Drosophila ovaries and fat body by 20-hydroxyecdysone and a juvenile hormone analog

In adult female Drosophila melanogaster an increase in the synthesis and secretion of three yolk polypeptides (YPs) occurs during the first 24 hr after eclosion. During organ culture, these same polypeptides are synthesized and secreted into the medium by both fat body and ovaries. Two hormones, 20-hydroxyecdysone (20-HE) and a juvenile hormone analog (ZR-515) stimulate synthesis and secretion of YPs into the hemolymph of isolated female abdomens. The present experiments were undertaken to compare synthesis of YPs in normal females with YP synthesis in preparations deprived of anterior endocrine glands, and to find which hormone stimulates synthesis in the different organs. Separation of hemolymph proteins by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) showed that at eclosion incorporation of [³⁵S]methionine into YP1 and YP2 was low and was barely detectable in YP3. Over the next 24 hr the rate of label incorporation increased for all the YPs. Isolation of female abdomens at eclosion prevented this increase in label incorporation but did not entirely abolish YP synthesis. Application of either ZR-515 or 20-HE to isolated abdomens stimulated up to ninefold label incorporation into three polypeptides which comigrated with YPs from normal vitellogenic females. The response of isolated abdomens to ZR-515 or 20-HE was first detectable between 90 and 135 min after hormone application. The stimulated bands were confirmed to be YPs by a comparison of peptide digests of each of the three labeled polypeptides with those of the yolk polypeptides from intact vitellogenic females. The hypothesis that the two hormones might act on different organs was tested by treating isolated female abdomens with various concentrations of either ZR-515 or 20-HE and then culturing the stimulated organ in vitro with [³⁵S]methionine. The fat body responded to both hormones by synthesizing and secreting into the culture medium polypeptides which comigrated with the YPs found in hemolymph, whereas the ovary produced similar polypeptides only after ZR-515. These secreted polypeptides were confirmed to be YPs by repeating the experiment using organs from heterozygotes for both YP2 and YP3 electrophoretic variants. Such organs synthesized five polypeptides which comigrated with the corresponding yolk polypeptides. These findings are discussed in relation to a hypothesis for the action of the two hormones.     

Yolk protein endocytosis by oocytes in Drosophila melanogaster: immunofluorescent localization of clathrin, adaptin and the yolk protein receptor

The process of yolk protein (YP) uptake by developing oocytes in Drosophila melanogaster has been investigated by immunofluorescent localization of the endocytosis proteins, clathrin, alpha-adaptin and the putative yolk protein receptor (YP receptor). Data suggests that YPs from the follicle cells are trafficked into the oocyte during early stages of vitellogenesis, and that hemolymph YPs are sequestered by nurse cells adjacent to the developing oocyte during late stages of vitellogenesis. Yolk proteins were immunolocalized to both follicle cells and nurse cells during these processes. Diapausing female Drosophila melanogaster undergo a pre-vitellogenic arrest of ovarian development associated with the absence of ovarian alpha-adaptin, clathrin and putative YP receptor. Diapause termination by transfer of whole animals from 11 degrees C to 25 degrees C, or by 20-hydroxyecdysone injection, results in the appearance of immunopositive material in the nurse cells for all three proteins between 12 h and 16 h post upshift and within four days of injection. Immunopositive material was not noted in the follicle cells during diapause termination. In vitro warming of diapausing ovaries, or incubation in the presence of 1 &mgr;M 20-hydroxyecdysone failed to initiate early vitellogenic development suggesting that diapause termination requires factor(s) external to the ovary. Western blotting analysis of extracts of 24 h post-eclosion wild type and ap(56f) females identified putative yolk protein receptor with a molecular weight of 208 kDa and clathrin with a molecular weight of 178 kDa.     

Sexual phenotype and vitellogenin synthesis in Drosophila melanogaster

An ovary transplanted from a Drosophila melanogaster female into a male will mature and form morphologically normal yolk-filled oocytes. Since it has been supposed that the yolk polypeptides come only from the female fat body, it was hypothesized that the implanted ovary induces the fat body of the male host to synthesize and secrete yolk polypeptides (YPs). To test this hypothesis, fat body preparations from females, untreated males, and males containing transplanted ovaries were cultured in vitro with ³⁵S-methionine and the medium was examined for the presence of newly labeled YPs. Female fat body secreted newly labeled YPs, but no freshly synthesized YPs were secreted by fat bodies from untreated males or from males containing transplanted ovaries. In vitro cultured ovaries, however, both from females and from male hosts did secrete newly synthesized YPs. Therefore, the YPs in an ovary that matured in a male come mainly from endogenous synthesis by the implanted ovary. To find whether males were responsive to the hormones that stimulate YP production in isolated female abdomens, we treated males with the juvenile hormone analogue ZR-515 and with 20-hydroxyecdysone. The latter, but not the former, was able to cause synthesis and secretion of three bands migrating precisely as YPs in SDS gels. Partial peptide digests of the 20-hydroxyecdysone-stimulated polypeptides in males showed them to be identical with those stimulated by 20-hydroxyecdysone or ZR-515 in isolated female abdomens and with the three YPs found in normal female hemolymph. Finally, YP synthesis was assayed in mutants that affect the phenotypic sex of a fly. It was found that flies bearing two X chromosomes and the mutations dsx, dsx^D, ix or three sets of autosomes continued to make YPs, but tra-3-pseudomales did not. These results suggest that the process of sex determination involves steps leading to synthesis of an ecdysteroid in females, which then activates synthesis of the YPs by the fat body. A hypothesis is suggested to explain the fact that two different hormones can stimulate YP synthesis and two different organs can synthesize YPs.     

Ultrastructural changes induced by juvenile hormone analogue in oöcyte membranes of apterous4Drosophila melanogaster

Egg chambers from apterous⁴ (ap⁴), a female sterile mutant of Drosophila melanogaster, show none of the microvilli or pinocytotic vesicles which are a prominent feature of the membrane of the wild-type vitellogenic oöcyte. The studies reported here show that a juvenile hormone analogue (ZR515) stimulates formation of microvilli and pinocytotic vesicles in oöcytes of ap⁴ flies. Within 12 hr after topical application of ZR515 to homozygous ap⁴ females the oöcyte membranes exhibit extensive microvilli and pinocytotic activity. The follicle-cell surface adjoining the oöcyte also shows some changes. In vitro studies in which ap⁴ ovaries were incubated in Schneider's Drosophila tissue-culture medium in the presence of ZR515 with or without female haemolymph, or in the absence of ZR515, showed that the analogue acts alone directly on the ovary to cause formation of microvilli and pinocytotic vesicles on the oöcyte membrane.     

JUVENILE HORMONE BINDING PROTEIN IN THE OVARIES OF HOUSEFLY MUSCA DOMESTICA VACINA

Abstract  By using charcocal binding assay, the juvenile hormone binding protein (JHBP) was determined in the ovaries of houseflies. This ovarian JHBP possesses high affinity with juvenile hormone III (JH III) and has a K_d of 2.1 III 10^--⁸ M. The binding of ³H-juvenile hormone III (³H-JH III) to this protein was inhibited by unlablled JH III, but not by juvenile hormone analog ZR 512 or ZR 515. The level of this ovarian JHBP reached the highest in houseflies 48 h after emergence, and was 6. 5-fold and 15. 5-fold higher than that in housefIies 60 h and 72 h after emergence, respectively. No binding activity was detected in the ovaries of houseflies 24 h or 36 h after emergence. The absence of JHBP in the ovaries of houseflies 36 h after emergence could be reversed by applying JH III to newly emerged houseflies. The data suggest that the fluctuation of the JHBP concentration might associate with the action of juvenile hormone (JH) on housefly vitellogenesis.     

Nonvitellogenic female sterile mutants and the regulation of vitellogenesis in Drosophila melanogaster.

The genetic and endocrine regulation of vitellogenesis was investigated by studying 18 female sterile mutations that disrupt the development of normal vitellogenic follicles. Applications of exogenous juvenile hormone analog and reciprocal ovarian transplants between flies of different genotypes were employed to accomplish our first two objectives: to find (1) whether the mutation blocked development of the ovary directly, and (2) whether the mutation altered the hormonal milieu. In 15 of the mutants the developmental defect was localized to the ovary, but in the other 3 the ovary was competent to respond to a permissive environment. The internal milieu of these three mutants (ap⁴, fs(3)A1, fs(2)A18) was unable to provoke normal development in wild-type ovaries, suggesting that these mutations cause endocrine defects. Our third objective was to find whether an endocrine organ was itself defective in any of these mutants. The corpus allatum from two of the mutants was unable to provoke vitellogenesis in isolated wild-type abdomens, but corpora allata from wild-type females or from other mutants were able to promote maturation of ovarian follicles in isolated abdomens. Our fourth objective was to find whether any of the mutants were able to produce yolk proteins. Immunoelectrophoresis of fly hemolymph demonstrated that in all mutants tested vitellogenins were found in the blood. These experiments permit four main conclusions. First, they identify the first Drosophila mutants in which an endocrine gland is shown to be intrinsically defective during adulthood. Second, they show that the production of morphologically normal late previtellogenic follicles is not required for the induction of vitellogenin synthesis and secretion. Third, they show that juvenile hormone can cause ovarian follicles to sequester yolk in mutant flies. And finally, they show that mutants with defective corpora allata still synthesize and secrete vitellogenin. Taken together, these conclusions suggest that in Drosophila melanogaster the uptake of vitellogenin into follicles depends upon the availability of juvenile hormone, but that the synthesis and secretion of vitellogenin are independent of both normal ovaries and totally normal corpora allata.     

Morphology of mouse egg cylinder development in vitro: a light and electron microscopic study.

The endocrine control of yolk deposition in Drosophila melanogaster was studied by ligation and transplantation techniques. Endocrine events associated with the initiation of vitellogenesis were found to be synchronized with eclosion rather than the completion fo adult development. Decapitation experiments showed that a cephalic event occurring at about the time of eclosion is necessary for each animal to initiate vitellogenesis. The morphogenetic effect of the head could be replaced by a juvenile hormone analog (JHA). In addition to the cephalic event, a thoracic factor is required for each follicle to initiate vitellogenesis, since preparation of isolated abdomens before 16 hours after eclosion prevented vitellogenesis. In abdomens isolated after this time, no early vitellogenic stages were formed. The suppression of vitellogenesis in isolated abdomens was reversed by implanting corpora allata or by treating these preparations with JHA, but not by implanting corpora cardiaca. Ovaries that were artificially induced to mature by treating isolated abdomens with JHA still displayed the normal complement of ovarian proteins after electrophoresis in polyacrylamide gels. These results show that a circadian clock triggers vitellogenesis via a cephalic signal at eclosion, which in turn triggers events in the thorax or abdomen. The cephalic signal can be superseded by juvenile hormone, whose presence is necessary for each follicle to become vitellogenic.     

The roles of juvenile hormone and 20-hydroxy-ecdysone during vitellogenesis in isolated abdomens of Drosophila melanogaster

Both juvenile hormone and 20-hydroxy-ecdysone seem to be involved in the regulation of vitellogenesis in Drosophila melanogaster. It is the purpose of this paper to begin to define the functions of these two hormones. Although vitellogenin synthesis does not occur at a high rate in 1-day-old female abdomens isolated from the head and thorax before 0.75 hr after eclosion, both ZR515 (a juvenile hormone analogue) and 20-hydroxy-ecdysone can cause in these preparations vitellogenin synthesis and secretion into the haemolymph. The synthesis and secretion into the haemolymph of all three vitellogenins which are detectable by electrophoresis in sodium dodecyl sulphate-containing gels of polyacrylamide is promoted by both hormones. That result excludes the hypothesis that these two hormones regulate the synthesis of different vitellogenins. A dose-response curve showed that an injection of 0.2 μl of a 10^?6 M 20-hydroxy-ecdysone solution was sufficient to promote vitellogenin synthesis and secretion in isolated abdomens. Ovaries from isolated female abdomens treated with juvenile hormone analogue showed nearly normal amounts of all three vitellogenins and morphologically normal advanced vitellogenic follicles, whereas ovaries from isolated abdomens treated with 20-hydroxy-ecdysone contained little vitellogenin and no vitellogenic follicles. We conclude that under the conditions used, juvenile hormone permits vitellogenin uptake into the oöcyte much more readily than does 20-hydroxy-ecdysone.     

Replication of Drosophila chromosomes. IX. Stimulation of initiation of polytene replication cycles in vitro by juvenile hormone

A greater proportion of polytene nuclei show [3H]thymidine incorporation when third instar larval salivary glands of Drosophila nasuta are pulse-labelled after in vitro culture (3-24 h) in the presence of a juvenile hormone mimic, ZR 515. In glands chronically labelled with [3H]thymidine in the presence of ZR 515, more nuclei are seen to have entered new polytene replication cycles. Similarly, when salivary glands from larvae fed on 5-fluorodeoxyuridine to block polytene replication cycles at intersynthetic periods were cultured in vitro, new polytene replication cycles were initiated more quickly in the presence of ZR 515. These results suggest a stimulatory effect of juvenile hormone on new polytene replication cycles.     

Identification and comparisons of the yolk polypeptides and the genes which code for them in D. melanogaster sibling species

Summary The yolk proteins stored in Drosophila, oocytes for utilisation during embryogenesis are an ideal system for studying the regulation of gene expression during development. The 3 major polypeptides found in yolk in D. melanogaster are synthesised in the fat body and ovarian follicle cells and selectively accumulated by the oocyte during vitellogenesis. In order to understand more about their regulation and the mechanism of uptake, studies on other species are necessary.Three yolk polypeptides have previously been identified in the D. melanogaster sibling species (D. melanogaster, D. simulans, D. mauritiana, D. erecta, D. teissieri, D. orena and D. yakuba). In D. melanogaster three genes located on the X chromosome are known to code for these yolk polypeptides. in this study genomic Southern transfers and in situ hybridisation experiments were carried out on the sibling species. Using the three cloned yolk protein genes from D. melanogaster, homologous sequences could be detected in the sibling species. It is suggested that three yolk protein genes occur in each of these species, all being located on the X chromosome, and that two of the genes are very closely linked in these same species. Yolk protein gene-homologous DNA sequences have also been identified in two more distantly related species D. funebris and D. virilis.     

Inhibition of DD2R gene expression in the corpus allatum activates alkaline phosphatase in female Drosophila melanogaster

Tissue-specific inhibition of the expression of the D2-like dopamine receptor gene (DD2R) in the corpus allatum (CA), which is a gland that synthesizes the juvenile hormone (JH), was tested for effect on alkaline phosphatase (AP) activity and the intensity of the AP response to heat stress (stress reactivity) in female Drosophila melanogaster. AP activity and AP stress reactivity in transgenic females with lower DD2R expression in the CA were higher than in control flies. A pharmacological elevation in JH increased AP activity in females of the control strains. DD2R was assumed to mediate the inhibitory effect of dopamine of JH synthesis in the CA of D. melanogaster.     

Downregulation of the dopamine D2-like receptor in corpus allatum affects juvenile hormone synthesis in Drosophila melanogaster females

In Drosophila, juvenile hormone (JH) is synthesized de novo in the specialized endocrine gland, corpusallatum (CA). Dopamine (DA) controls JH levels by either stimulating or inhibiting its synthesis and degradation depending on the developmental stage. The present study focuses on the role of D2-like receptors in the regulation of JH synthesis by dopamine. We show that D2-like receptors (DD2R) are expressed in CA cells of Drosophila melanogaster females. In addition, the level of JH production was analyzed in D. melanogaster females with decreased DD2R expression in CA (vs. corresponding control flies) by assessing multiple indices of JH synthesis (JH-hydrolyzing activity and stress reactivity of the system of JH metabolism, activity and stress reactivity of the alkaline phosphatase, activity and stress reactivity of the tyrosine decarboxylase). The differential value obtained for each index suggests increased JH production in female flies that downregulate DD2R. Based on these findings, we postulate that the DA inhibiting effect on the JH synthesis in D. melanogaster is mediated at least in part via D2-like receptors.     

Ovarian yolk-protein synthesis in Drosophila melanogaster

The ovaries and fat bodies of Drosophila melanogaster adult females both synthesize yolk polypeptides. In a series of experiments it has been shown that the ovaries become competent to mature in an adult male host, where only ovarian synthesis occurs, very early in metamorphosis and synthesis of yolk polypeptides begins in a time-dependent sequence related to the age of the ovary when transplanted. Maturation of ovaries occurs prior to eclosion when they are transplanted to an earlier developmental stage showing that neither the event of eclosion not the adult environment is essential in triggering yolk-polypeptide synthesis by the ovary. When metamorphosing ovaries are transplanted to a female host they take up host yolk polypeptides from the haemolymph, but this does not lead to the implanted ovary developing substantially better than in a male host where only synthesis by the ovary can occur. The regulation of ovarian yolk-polypeptide synthesis therefore appears to be autonomous to the ovary itself. There may be a trigger early in metamorphosis which induces competence in the ovary so that it subsequently initiates yolk-polypeptide gene expression at eclosion.     

Artifactual stimulation of vitellogenesis in Aedes aegypti by 20-hydroxyecdysone

Single or repeated, non-physiological, high doses (0.5–5.0 μg/female) of 20-hydroxyecdysone or ecdysone injected into sugar-fed female Aedes aegypti stimulated follicular growth and deposition of yolk, but suppressed accumulation of protein yolk to approximately one-third, and lipid yolk to one-half that in an equal number of follicles with equivalent yolk length taken from blood-fed controls. Physiological doses (500 pg/female) of ecdysone or 20-hydroxyecdysone or the implantation of ecdysone-secreting ovaries (verified by bioassay), into sugar-fed females failed to induce any yolk deposition. In these experiments, yolk precursors were not the limiting factor, because in decapitated females, digesting a blood meal, the injection of a physiological dose of 20-hydroxyecdysone or the implantation of ecdysone-secreting ovaries still did not stimulate vitellogenesis. Finally, continuous infusion of 500 pg or even 50 ng 20-hydroxyecdysone/hr for 22 hr was as ineffective as single or multiple injections of equivalent doses of hormone. Consequently, rapid excretion or catabolism of 20-hydroxyecdysone by the sugar-fed female does not explain the need for high doses to induce vitellogenesis, or the failure of oöcytes to mature with normal protein and lipid content. Apparently, ovarian ecdysone is not the factor by which normal vitellogenesis is initiated and maintained in this mosquito.     

Juvenile hormone induces ovarian development in diapausing cave-dwelling Drosophila species

Drosophila grisea and macroptera were collected in caves overwintering as adults. The females remained in a state of reproductive diapause which extended until May for macroptera and until July for grisea, whereas the males of both species had mature sperm at all times. Termination of the reproductive diapause under laboratory conditions was accomplished in grisea by exposing them to 14 hr of illumination daily and in macroptera by increasing the temperature to 20°C. Topical application of juvenile hormone (JH) on diapausing grisea caused a prompt termination of diapause and maturation of oöcytes within 10 days. Yolk proteins were found in the haemolymph of diapausing flies but not in their ovaries. In the JH-treated flies, yolk proteins were found in both the haemolymph and the ovaries, suggesting that in this species JH regulates the uptake of yolk proteins.     

Ecdysteroids regulate yolk protein uptake by Drosophila melanogaster oocytes

Juvenile hormones (JHs) are thought to drive the regulation of yolk protein uptake by ovaries in Drosophila melanogaster. However, the level of JH production in a mutant stock (ap(56f)) is depressed yet the flies are normally vitellogenic. The production of ecdysteroids by these ap(56f) ovaries in vitro is elevated above that of wild-type ovaries. The incubation of wild-type ovaries in the presence of 0.1mM JHB(3) increased ecdysteroid biosynthesis only during the first 18h following eclosion. Female Drosophila melanogaster undergo a pre-vitellogenic reproductive diapause when exposed to low temperature (11 degrees C) and a short-day photoperiod (L12:D12). The rate of ecdysteroid synthesis by the ovaries, but not JH production, increased within 12h of a temperature upshift to 25 degrees C from a basal level of 20+/-1pg/10 pair of ovaries/5h to a sustained level of 150+/-20pg/10 pair/5h. Vitellogenic oocytes were noted in all females within 12h of this temperature upshift. Diapause was also terminated by the injection of 1&mgr;g of 20-hydroxyecdysone into the abdomens of diapausing females as determined by an increase in ovary size, and the appearance of vitellogenic oocytes as compared to controls. These results are consistent with a revised model for the regulation of yolk protein uptake by ovaries in which ecdysteroids, and not JHs, play the prominent role.