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.     

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.     

Transfer of molecules from ejaculate to females in Drosophila melanogaster and Drosophila pseudoobscura

Methionine in the form of free amino acids, small peptides and several proteins is transferred from ejaculate to females in Drosophila melanogaster and D. pseudoobscura. The male contribution is found mostly in the ovary and the sizes of the polypeptides transferred have been established. Some components of the ejaculate are rapidly transferred to the somatic tissues outside the ovary and reproductive system where they co-migrate with the yolk polypeptides. The incorporation of free methionine into polypeptides in non-reproductive tissues is higher in females that have been deprived of a source of protein prior to mating. The molecules transferred from ejaculate may have roles in regulating reproductive behaviour and may also be used as a nutrient source. We suggest that free amino acids in the ejaculate are rapidly utilised in protein synthesis in the somatic tissues outside the ovary and could provide a boost to yolk protein and hence egg production in females in nature, where nutrients may be in limited supply.     

Artificial reproduction in a hymenopteran insect, Athalia rosae, using eggs matured with heterospecific yolk proteins and fertilized with cryopreserved sperm

Previtellogenic ovaries of Athalia rosae (Hymenoptera, Symphyta, Tenthredinidae) were transplanted into the adult female abdominal hemocoel of Athalia infumata (Symphyta, Tenthredinidae), Arge nigrinodosa (Symphyta, Argidae), and Pimpla nipponica (Apocrita, Ichneumonidae). The donor oocytes accumulated heterospecific yolk proteins and matured in the A. infumata host. On average, six mature oocytes were obtained per transplanted ovary. In contrast, the donor oocytes accumulated a limited amount of yolk but did not mature in the Ar. nigrinodosa host and did not even accumulate yolk in the P. nipponica host. The eggs that matured in the A. infumata host were injected with cryopreserved A. rosae sperm that had been taken from adult male seminal vesicles and stored at -80 degrees C. Fertilization, as confirmed by the use of visible marker mutations, was achieved and a fraction of the injected eggs developed into fertile female adults.     

家蝇卵巢摄取卵黄蛋白的机理

在家蝇Musca domestica viaina 的卵黄发生过程中,卵母细胞摄取卵黄原蛋白与滤泡开放是相关的。观察不同发育时期的家蝇滤泡结果表明,在摄取活动最旺盛的时期也就是卵黄发生的顶盛时期,其滤泡开放程度最大,而在卵黄发生前期和后期基本上没有摄取活动,此时的滤泡上皮细胞间不开放。卵巢体外培养的激素处理表明,JH可以促进滤泡开放。家蝇卵巢微粒体制备物的Na⁺-K⁺ATP酶活力在卵巢发育过程中存在着动态变化。羽化后24小时时有一定的酶活性,随着卵黄发生的进行,酶活力逐渐增加,到羽化48小时时酶活力最高,然后又开始下降,到羽化72小时时已经很小。羽化32小时的家蝇点滴或注躬 JH之后,测得的卵巢微粒体制备物的Na⁺-K⁺ATP酶活力比正常羽化36小时的高,羽化44小时的家蝇点滴和注射JH之后,测得酶活力比正常羽化48小时的低。羽化36小时和48小时的家蝇卵巢微粒体制备物与JH共同作用后,其Na⁺-K⁺ATP酶的活力分别增加2.95倍和3.50倍,羽化48小时的家蝇卵巢在含有JH的培养液中培养启,其匀浆液的酶活性为对照组的1.26倍。 由此我们可以推测在家蝇的卵黄发生过程中,JH通过促进滤泡开放和增加卵巢微粒体制备物Na⁺-K⁺ATP酶的活力,从而调控卵母细胞对卵黄蛋白的摄取。     

The Use of Yolk Protein Variations in Drosophila Species to Analyse the Control of Vitellogenesis

The yolk proteins of many insects, including Drosophila , are synthesised in the fat body of adult females and are transported through the haemolymph to be accumulated in the oocytes. We have used differences in the size and number of yolk polypeptides in different species of Drosophila to investigate the role of the ovary and of juvenile hormone in vitellogenesis.
The yolk proteins of eight species of Drosophila were compared with those of Drosophila melanogaster . Only Drosophila simulans had three yolk polypeptides of similar molecular weight to the three polypeptides in D. melanogaster and gave a high degree of cross reactivity with antibody raised against the yolk proteins of D. melanogaster . All other species had one to three bands on a sodium dodecyl sulphate gel representing the yolk polypeptides; they are between 44,000 and 49,500 daltons in molecular weight, showing weak cross reactivity with anti- D. melanogaster yolk antibody. Interspecies ovary transplants established that males of D. arizonensis and D.pseudoobscura which supported vitellogenesis of D. melanogaster ovaries, did so by permitting the implanted ovaries to synthesise their own yolk proteins. The synthetic juvenile hormone, ZR515, was unable to induce ovaries, which failed to develop in other species of males, to undergo vitellogenesis. In females, however, ZR515 was able to induce uptake of the yolk proteins of some of the species into the D. melanogaster donor ovaries, which had failed to develop in the absence of hormone. These interspecies differences in the yolk proteins have therefore been used to investigate the control of vitellogenesis and the role of juvenile hormone in this process in Drosophila .     

Influence of the mesonephros on the development of fetal mouse ovaries following transplantation into adult male and female mice

We previously reported that fetal mouse ovaries frequently develop testicular structure following transplantation into adult male mice. The mechanism involved in gonadal sex reversal of ovarian grafts is not known. In the present study, we examined the influence of the adjacent mesonephros on development of the ovarian grafts. The results show that (1) when fetal ovaries were transplanted with the attached mesonephros, the frequency of ovotestis development was higher in male hosts than in female hosts, (2) the fetal ovaries that had been separated from mesonephros developed testicular structures more frequently than those with the mesonephros, and the incidence of ovotestis development was comparable in male and female hosts, (3) removal of the cranial or caudal half of the mesonephros resulted in a similar frequency of ovotestis development, and (4) when fetal ovaries were separated and reattached to the mesonephros, they developed testicular structures at a frequency similar to that of ovaries left attached to the mesonephros, and the sex of mesonephroi reattached to ovarian grafts did not influence the incidence of ovotestis development. These findings suggest that fetal ovaries can develop testicular structures after transplantation regardless of the sex of host, and that the adjacent mesonephros protects ovarian grafts from masculinizing stimuli more efficiently in female host than male hosts.     

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.     

家蝇卵巢摄取卵黄蛋白的机理

在家蝇Ｍｕｓｃａ　ｄｏｍｅｓｔｉｃａ　ｖｉａｉｎａ的印黄发生过程中,卵母细胞摄取卵黄原蛋白与滤沟开放是相关的。观察不同发育时期的家蝇滤泡结果表明,在摄取活动最旺盛的时期也就是卵黄发生的顶盛时期,其滤泡开放程度最大,而在卵黄发生前期和后期基本上没有摄取活动,此时的滤泡上皮细胞间不开放。卵巢体外培养的激素处理表明,ＪＨ可以促进滤泡开放。家蝇卵巢微粒体制备物的Ｎａ＋－Ｋ＋ＡＴＰ酶活力在卵巢发育过程中存在着动态变化。羽化后２４小时时有一定的酶活性,随着卵黄发生的进行,酶活力逐渐增加,到现化４８小时时酶活力最高,然后又开始下降,到弱化７２小时时已经很小。羽化３２小时的家蝇点滴或注射ＪＨ之后,测得的卵巢微粒体制备物的Ｎａ＋－Ｋ＋ＡＴＰ酶活力比正常羽化３６小时的高,羽化率４４小时的家蝇点滴和注射ＪＨ之后,测得酶活力比正常羽化４８小时的低．羽化３６小时和４８小时的家蝇卵巢微粒体制备物与ＪＨ共同作用后,其Ｎａ＋－Ｋ＋ＡＴＰ酶的活力分别增加２．９５倍和３．５０倍,羽化４８小时的家蝇卵巢在含有ＪＨ的培养液中培养后,其匀浆液的酶活性为对照组的１．２６倍。由此我们可以推测在家蝇的卵黄发生过程中,ＪＨ通过促进滤泡开放和增加卵巢微粒体制     

Genetic and Hormonal Regulation of Vitellogenesis in Drosophila

In Drosophila the female-specific yolk protein, or vitellogenin,is synthesized in the fat body. In D. melanogaster, vitellogenin,is first detected in the female hemolymph at the time of adulteclosion and in the ovaries 20 hours later, suggesting differentregulatory mechanisms for the processes of synthesis and uptake.Transplantations of pupal or immature adult ovaries into D.melanogaster adult males induce vitellogenin synthesis, implicatingan ovarian agent in the control of synthesis. Larval ovariesfail to stimulate synthesis. Female-sterile mutants with rudimentaryor previtellogenic ovaries synthesize and accumulate large quantitiesof vitellogenin in the hemolymph, but not in the ovaries. Transplantationof these rudimentary ovaries into males induces vitellogeninsynthesis, suggesting that the ovarian inducing agent does notoriginate from the germ cells. Treatment of the homozygous female-sterilemutants with juvenile hormone stimulates the uptake of vitellogeninby the ovary in some strains. This shows that juvenile hormoneplays a role in vitellogenin uptake. The potential importanceof Drosophila vitellogenesis for studies of gene regulationis discussed.     

Ovarian and fat-body vitellogenin synthesis in Drosophila melanogaster

The ovary and the fat body of Drosophila melanogaster both synthesise vitellogenins in vivo. The ovary contributes nearly as much vitellogenin to the yolk of an oocyte as does the fat body. Densitometry of fluorographs and gels has been used to compare the amount of the smallest vitellogenin polypeptide, yolk protein 3, synthesised by each tissue. Cell-free translations indicate that the ovary, in contrast to the fat body, contains a much reduced level of the mRNA for yolk protein 3 compared with the mRNAs for the other vitellogenin polypeptides. However, if tissues are cultured in vitro, the underproduction of this protein by the ovary is not significant. Because young embryos have levels of this polypeptide which are expected if the ovary has a low level of its corresponding mRNA, we argue that the ovary genuinely underproduces this protein in vivo and that the relative levels synthesised by the ovary in vitro are an artefact. Egg chambers of previtellogenic stages can synthesise vitellogenins, but the maximum level of vitellogenin synthesis occurs in egg chambers of the early vitellogenic stages. We conclude that the expression of the vitellogenin genes is subject to different controls at each site of synthesis. The possible cell types responsible for ovarian vitellogenin synthesis are discussed; the follicle epithelial cells are tentatively nominated for this role. We also suggest that a specific repression mechanism for vitellogenin gene expression exists in the ovary.     

Differential control of yolk protein gene expression in fat bodies and gonads by the sex-determining gene tra-2 of Drosophila.

We studied the regulation of the yolk protein (YP) genes in the somatic cells of the gonads, using temperature sensitive mutations (tra-2ts) of transformer-2, a gene required for female sexual differentiation. XX;tra-2ts mutant animals were raised at the permissive temperature so that they developed as females and were then shifted to the restrictive male-determining temperature either 1-2 days before or 0-2 h after eclosion. These animals formed vitellogenic ovaries. Likewise, mutant gonads transplanted into either normal female hosts or normal male hosts, kept at the restrictive temperature, underwent vitellogenesis. Thus, the ovarian follicle cells can mature and express their YP genes in the absence of a functional product of the tra-2 gene. Although the gonadal somatic cells of ovary and testis may derive from the same progenitor cells, the testicular cells of XX;tra-2ts pseudomales did not express their YP genes nor take up YP from the haemolymph at the permissive female-determining temperature. We conclude that in the somatic cells of the gonad, the YP genes are no longer under direct control of the sex-determining genes, but instead are regulated by tissue specific factors present in the follicle cells. It is the formation of follicle cells which requires the activity of tra-2.     

Distribution of yolk polypeptides in the follicle cells during the differentiation of the follicular epithelium in Sarcophaga bullata egg follicles

In S. bullata, the ovaries contribute to the synthesis of yolk polypeptides. A specific antiserum for yolk polypeptides was used to visualize the presence of yolk polypeptides in the follicle cells during their differentiation. After vitellogenesis has started, all follicle cells contain yolk polypeptides. The squamous follicle cells covering the nurse cells and the border cells lose yolk polypeptides before mid-vitellogenesis, whereas the follicle cells over the oocyte contain yolk polypeptides until after late vitellogenesis. All follicle cells are immunonegative afterwards. In vitro translation of poly(A)+ RNA demonstrated that the presence of yolk polypeptide mRNA correlates well with follicle cell immunopositivity for yolk polypeptides. This suggests that the follicle cells synthesize the ovarian yolk polypeptides. Differences in cellular and nuclear morphology, total and poly(A)+ RNA synthesis and the rate of yolk polypeptide synthesis were shown to be correlated with the presence or absence of yolk polypeptides in the differentiating follicular epithelium. The possible relationship between these different aspects of follicle cell differentiation, follicle cell polyploidy and the extracellular current pattern around follicles are discussed.     

The major yolk protein is synthesized in the digestive tract and secreted into the body cavities in sea urchin larvae

Major yolk protein (MYP), a transferrin superfamily protein contained in yolk granules of sea urchin eggs, also occurs in the coelomic fluid of male and female adult sea urchins regardless of their reproductive cycle. MYP in the coelomic fluid (CFMYP; 180 kDa) has a zinc-binding capacity and has a higher molecular mass than MYP in eggs (EGMYP; 170 kDa). CFMYP is thought to be synthesized in the digestive tract and secreted into the coelomic fluid where it is involved in the transport of zinc derived from food. To clarify when and where MYP synthesis starts, we investigated the expression of MYP during larval development and growth in Pseudocentrotus depressus. MYP mRNA was detected using RT-PCR in the early 8-arm pluteus stage and its expression persisted until after metamorphosis. Real-time RT-PCR revealed that MYP mRNA increased exponentially from the early 8-arm stage to metamorphosis. Western blotting showed that maternal EGMYP disappeared by the 4-arm stage and that newly synthesized CFMYP was present at and after the mid 8-arm stage. In the late 8-arm larvae, MYP mRNA was detected in the digestive tract using in situ hybridization, and the protein was found in the somatocoel and the blastocoel-derived space between the somatocoel and epidermis using immunohistochemistry. These results suggest that CFMYP is synthesized in the digestive tract and secreted into the body cavities at and after the early 8-arm stage. We assume that in larvae, CFMYP transports zinc derived from food via the body cavities to various tissues, as suggested for adults.     

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.     

The effects of nutrition and methoprene treatment on ovarian ecdysteroid synthesis in Drosophila melanogaster

Radioimmunoassay of in vitro culture medium from ovaries of Drosophila melanogaster indicates that detectable ovarian ecdysteroid synthesis begins between 6 and 12 h after eclosion and reaches a peak between 24 and 30 h, when animals are reared at 25°C, 12 h photophase. Analysis of 24 and 72 h medium by a combination of high-performance liquid chromatography and radioimmunoassay demonstrates three ecdysteroid regions, two comigrating with known standards of ecdysone and 20-hydroxyecdysone and a third highly polar region containing one or more unidentified radioimmunoassay-active ecdysteroids. In 72 h medium the polar region comprises the majority of radioimmunoassay-active material while in 24 h medium the majority is in the ecdysone region. Provision of a nutritionally deficient diet to females at adult eclosion prevents the normal increase in vitellogenic-stage follicles and ovarian ecdysteroid synthesis. Methoprene treatment of such females stimulates a transient burst of ovarian ecdysteroid synthesis and the production of near normal numbers of vitellogenic oöcytes by 24 h, although by 48 h the number of vitellogenic oöcytes is less than normal.     

Factors involved in the testicular development from fetal mouse ovaries following transplantation

We have previously shown that fetal mouse ovaries develop testicular structures after transplantation into adult male mice. The mechanisms of gonadal sex reversal is poorly understood. In the present study, we examined how a host environment is involved in the induction of testicular development in ovarian grafts. Fetal ovaries on the twelfth day of gestation were microencapsulated with semipermeable membranes, transplanted beneath the kidney capsules of adult male mice, and fixed for histological examinations between the sixteenth and twenty-second day after transplantation. Fifteen of forty-seven ovarian grafts were found to be completely enclosed in microcapsules, whereas the microcapsule membranes of other grafts were partly broken or had been lost. These differences of microencapsulation conditions made it possible to study the role of host factors in gonadal sex reversal. All ovarian grafts surrounded by microcapsule membranes developed ovarian structures. In contrast, most ovarian grafts which had lost the microcapsules developed testicular structures in addition to ovarian structures. When ovarian grafts were partially enclosed in microcapsule membranes, testicular structures developed only in the area in contract with the host kidney. These results suggest that direct interaction between the ovarian graft and cells or large macromolecules from the host is involved in the development of testicular structures in ovarian grafts.