Synthesis and maturation of the major yolk protein by the ovaries of the firebrat,Thermobia domestica (Insecta,thysanura)

• 1.1. Ovaries of Therobia domestica, dissected from inseminated females and incubated with tritiated amino acids, synthesize labeled proteins, the major fraction of which is indistinguishable from the major vitellogenin secreted by the fat body, when considering the electrophoretic mobility, the polypeptide composition and the immunoreactivity.
• 2.2. Peptide mapping, using two different proteases, shows a striking structural similarity between the proteins of both origins and reveals interrelationships between their subunits.
• 3.3. The ovary synthesizes the 210–212 kD precursors of the major vitellogenin, as does the fat body, and processes them intensively into smaller subunits (176–182, 57 and 46 kD). The follicle cells are tentatively nominated for both roles.
• 4.4. The quantitative contribution of the two ovaries to the vitellogenin pool was found to be much higher than that of the fat body.

     

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.     

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.     

Heterosynthetic origin of the major yolk protein,vitellin, in a nereid,Perinereis cultrifera (polychaete annelid)

• 1.1. An examination of proteins synthesized by Perinereis cultrifera oocytes incubated in vitro with [³H]leucine clearly shows that these cells are not capable of synthesizing the main yolk protein previously identified in this worm.
• 2.2. In addition, the detection of radiolabelled vitellin in oocytes after in vitro incubation of an oocyte-coelomocyte cell mixture in presence of [³H]leucine strongly suggests that the coelomocytes, free cells in the coelomic cavity, synthesize and secrete a vitellin precursor, vitellogenin, that is subsequently taken up by the oocytes.
• 3.3. Two native proteins differing in mol. wt but reacting with anti-vitellin antibodies have been identified in coelomocyte incubation medium. Also found in the coelomic fluid, they have been designated VG1 (M_r = 530,000) and VG2 (M_r = 320,000).
• 4.4. The two vitellogenins consist of a single type of polypeptide of M_r = 176,000 and are incorporated in the oocytes where they are apparently observed under a single molecular form corresponding to VG1, the highest mol. wt protein similar in size to the initial form of vitellin (VI, 530,000).
• 5.5. From these data, it seems likely that VG2 is a monomeric molecule that is taken up by the oocytes as a dimer of VG1.
• 6.6. We conclude that P. cultrifera accumulates vitellin heterosynthetically and that vitellogenin is produced by the coelomocytes. Moreover, a single polypeptide similar in size to the polypeptidic component of secreted vitellogenin has been detected in the coelomocytes.
• 7.7. Since this polypeptide has been identified previously as the single intraoocytic precursor of the four lower mol. wt products that make up the mature form of vitellin (V5), it appears that P. cultrifera exhibits for vitellogenin a processing pathway in which cleavage of the precursor occurs only after uptake by the oocyte.

     

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.     

Synthesis of vitellogenin by the follicle cells of Rhodnius prolixus

The synthesis and secretion of vitellogenin by the ovary of Rhodnius prolixus was investigated. Using whole ovary or epithelial cells isolated from follicles of different sizes, it is shown that the follicle cells are a site of synthesis for this protein in the ovary. The ovaries or follicle cells were incubated in vitro with [(35)S]-methionine or (32)Pi and the secretion of newly synthesized ovarian vitellogenin (O-Vg) was estimated by the radioactivity associated with the immunoprecipitate or acid-precipitate proteins in the culture medium. The radioactive O-Vg was analyzed by SDS-PAGE followed by autoradiography or after elution from a DEAE-Toyopearl column. The presence of O-Vg inside the follicle cells was detected by immunofluorescence and immunogold labels. Both methods revealed strong labeling inside the follicle cells. While the capacity for total protein synthesis by the follicle cells was maximal during the early phase of vitellogenesis (in small follicles), the synthesis of O-Vg reached its peak during the late phase of oocyte growth, just before formation of the chorion. A possible role for ovarian vitellogenin in Rhodnius and its relationship with Vg synthesis by the fat body is discussed.     

Juvenile hormone regulation of structural changes and DNA synthesis in the follicular epithelium of Leucophaea maderae

Juvenile hormone (JH I) stimulates specific morphological and biochemical changes in the follicular epithelium surrounding the terminal oöcytes in Leucophaea maderae. These include extracellular and intracellular structural changes, increased rates of follicle cell DNA synthesis, and elevated follicle cell DNA concentrations.Using females decapitated 24 hr after ecdysis, we have shown that JH I injections stimulate the following structural changes in the follicular epithelium: the appearance of channels between adjacent follicle cells and of spaces between the follicular epithelium and the maturing oöcyte; an increase in follicle cell size; the development of an extensive rough endoplasmic reticulum system; and an enlarged nucleus within each follicle cell. No increase in the number of follicle cells surrounding the developing terminal follicles is found in 7-day JH I-treated females, although the terminal follicles are almost twice as long as those in untreated females.In addition, we have demonstrated that JH stimulates the following biochemical events in the ovary: a 3.5 fold increase in thymidine incorporation into follicle cell DNA, with no subsequent transfer of such DNA to the developing oöcyte, and a 1.4 fold increase in ovarian DNA in 7-day JH-treated females. These data indicated that JH stimulates follicle cell DNA synthesis. The absence of any corresponding division of follicle cells suggests that JH I may induce polyploidy in follicle cells.Extended exposure of decapitated females to JH I does not result in complete ovarian maturation. Although fat bodies in the treated insects continue to display an increasing rate of vitellogenin synthesis, DNA synthesis in the terminal follicles declines rapidly after day 9, and the terminal follicles ultimately degenerate.     

A quantitative description of vitellogenesis in Locusta migratoria migratorioides

During the main period of development of the oöcytes in Locusta migratoria migratorioides from 1.5 mm to 5.5 mm in length, a steady-state level of about 8 mg/ml VG (vitellogenin)² is maintained. During this period, total uptake rate of VG by the terminal oocytes was calculated to increase linearly from about 0.05 mg/hr to about 0.5 mg/hr. This increase is matched by an increase in the rate of VG synthesis, as determined by ³H-leucine incorporation rates, while the rate of synthesis of nonvitellogenic proteins at the same time remains constant.     

The vitellogenin of Leucophaea maderae: Synthesis as a large phosphorylated precursor

Phosphorylation of vitellogenin (yolk protein precursor) and vitellin (major yolk protein) polypeptides of Leucophaea maderae was studied by [³²P]ortho phosphate labeling and subsequent sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) autoradiography. The vitellogenin molecule was isolated from the hemolymph and fat body by antibody precipitation and high-performance liquid chromatography (HPLC), and shown to consist of at least five polypeptides (“subunits”) which had apparent molecular masses of 155, 112, 95, 92 and 54 kD. Labeling studies with ³²P showed that the covalently attached phosphorus was distributed in an uneven fashion among the five polypeptides. The two heavily-phosphorylated polypeptides, 112 and 54 kD, corresponded to the large and small, mature vitellin subunits. Quantitative SDS-PAGE analysis of long-term ³²P-labeled vitellin showed that these large and small “subunits” contained 55 and 30%, respectively, of the total radioactivity.When fat body was pulse-labeled with ³²P we found a heavily-phosphorylated intracellular 215 kD polypeptide which was precipitable with anti-vitellogenin. The synthesis of this intracellular precursorform of vitellogenin (pre-Vg) was under absolute juvenile hormone control. In vitro³²P pulse-chase experiments showed that pre-Vg was proteolytically processed within the fat body into some (or possibly all) of the mature vitellogenin subnits. Furthermore, peptide mapping confirmed that all of the phosphorylated vitellogenin subunits were derived from pre-Vg. Since previous studies have shown that phosphoserine residues account for essentially all of the covalently-attached phosphorus of the native vitellogenin molecule, we speculate that the asymmetric pattern of vitellogenin and vitellin subunit-phosphorylation is due to an uneven distribution of phosphoserine residues along the initial pre-Vg polypeptide chain. Finally, we conclude that phosphorylation of vitellogenin occurred post-translationally in the fat body endoplasmic reticulum because we could identify ³²P-labeled pre-Vg in purified microsomal vesicles but not in nascent vitellogenin polypeptide chains attached to vitellogenin polyribosomes.     

Vitellogenin uptake and vitellin localization in insect follicles examined using monoclonal antibodies and confocal scanning microscopy

Summary

Confocal scanning immunofluorescent microscopy and monoclonal antibodies were used to examine the route of uptake of vitellogenin (VG) by vitellogenic follicles and the ooplasmic localization of vitellin (VN) in the cricket, Acheta domesticus, and the stick insect, Carausius morosus. Uptake and cytoplasmic regionalization of a non-vitellogenic sulfated protein, sp 157/85, by C. morosus oocytes were also examined. By indirect immunofluorescence VG in both species and sp 157/85 were visualized in spaces between follicle cells and in peripheral yolk spheres. One cricket VG polypeptide had a regionalized distribution in the folliclular epithelium, and VN polypeptides in both species and sp 157/85 in C. morosus had regionalized distributions within the ooplasm. Localization of sp 157/85 to the anterior pole of the oocyte appeared to be stage-specific.     

Release of egg development neurosecretory hormone in Aedes aegypti and Aedes taeniorhynchus induced by an ovarian factor

Ovariectomized Aedes aegypti do not synthesize vitellogenin after a blood meal, unless an ovary from a blood-fed donor is implanted. Decapitation, however, prior to implantation inhibits vitellogenin synthesis. A female ovariectomized and decapitated 6 hr after a blood meal, synthesizes vitellogenin if an ovary from a blood-fed donor is implanted. On the other hand, females that are fed on blood and immediately decapitated can not be stimulated to synthesize vitellogenin with implanted ovaries removed from blood-fed donors. These experiments led to the hypothesis that the blood meal stimulates the ovary to secrete a corpus cardiacum stimulating factor, that in turn promotes release of egg development neurosecretory hormone stored in the corpus cardiacum.Injection of 20-hydroxy-ecdysone or ovarian extract prepared from ovaries removed from unfed females does not release egg development neurosecretory hormone. Thus corpus cardiacum stimulating factor is not 20-hydroxy-ecdysone, and ovaries removed from unfed females do not store it.The rate of inactivation of egg development neurosecretory hormone released from the corpus cardiacum after a blood meal was investigated by implanting an ovary into females that were blood fed for various intervals than decapitated and ovariectomized. Seventy per cent of implants grow when the operation is done 18 hr after feeding, and 30% when the operation is done between 18 and 24 hr after feeding, indicating that egg development neurosecretory hormone is stable for the first 18 hr after a blood meal.Aedes taeniorhynchus females ovariectomized 24 hr after adult emergence do not synthesize vitellogenin. When such a female is implanted with an ovary removed from a sugar-fed or blood-fed Aedes aegypti donor vitellogenin synthesis is initiated, and the implant grows. Decapitation prior to implantation inhibit vitellogenin synthesis and implants do not grow. These results indicate that corpus cardiacum stimulating factor is not species specific.     

Changes in follicle cell morphology,ovarian protein synthesis and ovarian DNA synthesis during oöcyte maturation in Leucophaea maderae: Role of juvenile hormone

Changes in follicle cell morphology were correlated with changes in rates of protein synthesis and DNA synthesis by the ovary during ovarian maturation in Leucophaea maderae. During the vitellogenic period of oöcyte development, which lasts approx, 15 days, morphological changes in the follicle cells are accompanied by moderate rates of ovarian protein synthesis and rapid rates of ovarian DNA synthesis. At approx. 15 days after mating, the shape of the follicle cells changes from cuboidal to squamous, ovarian DNA synthesis is arrested, and ovarian protein synthesis increases slightly. During the final period of oöcyte development, which lasts approx, two days, the interfollicular channels between the follicle cells have disappeared and the squamous follicle cells, which contain an extensive rough endoplasmic reticulum, deposit a chorion around the mature oöcyte. These morphological changes are accompanied by a radical increase in ovarian protein synthesis, while ovarian DNA synthesis remains arrested. Immediately before ovulation, ovarian protein synthesis starts to decline, reaching a minimal level 24 hr post-ovulation.Ovarian maturation is dependent on the presence of juvenile hormone (JH) only during the vitellogenic stage of oöcyte development. Decapitation of insects at any point during the first 10 days after mating arrests the synthesis of DNA and retards the synthesis of protein by the ovary, resulting in degeneration of the oöcyte. Subsequent injection of JH restores both events to normal levels within 72 hr. Decapitation on or after the tenth day following mating does not alter normal oöcyte development, chorion deposition, ovulation or egg case formation.Primary induction of protein synthesis in ovaries from virgin females can be achieved by either an in vivo or in vitro exposure of the tissue to JH, thus confirming a site of action for JH to be ovarian tissue. Electrophoretic analysis of the soluble proteins from JH-exposed ovaries in vivo reveals that JH stimulates general protein synthesis, rather than the synthesis of a specific major protein such as vitellogenin.     

Unlike in Drosophila Meroistic Ovaries,Hippo Represses Notch in Blattella germanica Panoistic Ovaries,Triggering the Mitosis-Endocycle Switch in the Follicular Cells

During insect oogenesis, the follicular epithelium undergoes both cell proliferation and apoptosis, thus modulating ovarian follicle growth. The Hippo pathway is key in these processes, and has been thoroughly studied in the meroistic ovaries of Drosophila melanogaster. However, nothing is known about the role of the Hippo pathway in primitive panoistic ovaries. This work examines the mRNA expression levels of the main components of the Hippo pathway in the panoistic ovary of the basal insect species Blattella germanica, and demonstrates the function of Hippo through RNAi. In Hippo-depleted specimens, the follicular cells of the basal ovarian follicles proliferate without arresting cytokinesis; the epithelium therefore becomes bilayered, impairing ovarian follicle growth. This phenotype is accompanied by long stalks between the ovarian follicles. In D. melanogaster loss of function of Notch determines that the stalk is not developed. With this in mind, we tested whether Hippo and Notch pathways are related in B. germanica. In Notch (only)-depleted females, no stalks were formed between the ovarian follicles. Simultaneous depletion of Hippo and Notch rescued partially the stalk to wild-type. Unlike in the meroistic ovaries of D. melanogaster, in panoistic ovaries the Hippo pathway appears to regulate follicular cell proliferation by acting as a repressor of Notch, triggering the switch from mitosis to the endocycle in the follicular cells. The phylogenetically basal position of B. germanica suggests that this might be the ancestral function of Hippo in insect ovaries.     

Vitellogenesis inhibition in Oncopeltus fasciatus females (Heteroptera: Lygaeidae) exposed to cadmium

Newly moulted females of the insect Oncopeltus fasciatus were exposed to cadmium (Cd) dissolved in the drinking water (50-400 mg l(-1) Cd) for 5 days. Cd exposure delayed ovarian maturation and inhibited egg production. Exposure to Cd, moreover, decreased hemolymph levels of the two major vitellogenin polypeptides of O. fasciatus, VG1 and VG2, in a concentration-dependent way, probably by a reduction in their synthesis. The ovarian levels of VG1 and VG2 were also decreased in Cd-exposed females. It was next investigated whether Cd effects might be a consequence of the endocrine disruption of vitellogenin synthesis, which is controlled by juvenile hormone (JH). JH replacement therapy did not restore VG1 or VG2 levels in Cd-exposed females, but did so in starved females. Our results do not therefore support a disturbance of JH production or a reduction in feeding as the cause of the reduced vitellogenin polypeptide levels, but rather point to the site of action of JH, the JH receptor, as the target of Cd effects.     

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.     

Vitellogenin transcytosis in follicular cells of the honeybee <Emphasis Type="Italic">Apis mellifera</Emphasis> and the wasp <Emphasis Type="Italic">Polistes simillimus</Emphasis>

Vitellogenin receptor (VgR) is a low-density lipoprotein receptor responsible for the mediated endocytosis of vitellogenin (Vg) during egg formation in insects. The maturing oocyte is enveloped by a follicular epithelium, which has large intercellular spaces during Vg accumulation (patency). However, Vg has been reported in the cytoplasm of follicular cells, indicating that there may be a transcellular route for its transport. This study verified the presence of VgR in the follicular cells of the ovaries of the honeybee Apis mellifera and the wasp Polistes simillimus in order to evaluate if Vg is transported via transcytosis in these insects. Antibodies specific for vitellogenin receptor (anti-VgR), vitellogenin (anti-Vg), and clathrin (anti-Clt) were used for immunolocalization. The results showed the presence of VgR on the apical and basal plasma membranes of follicular cells of the vitellogenic follicles in both species, indicating that VgR may have been transported from the basal to the apical cell domain, followed by its release into the perivitelline space, evidenced by the presence of apical plasma membrane projections containing VgR. Co-localization proved that Vg bind to VgR and that the transport of this protein is mediated by clathrin. These data suggest that, in these social insects, Vg is transported via clathrin-mediated VgR transcytosis in follicular cells.     

Studies on follicular growth in the immature rat and hamster: Effect of a single injection of gonadotropin or estrogen on the rate of3H-thymidine incorporation into ovarian DNAin vitro

Initiation of follicular growth by specific hormonal stimuli in ovaries of immature rats and hamsters was studied by determining the rate of incorporation of³H-thymidine into ovarian DNAin vitro. Incorporation was considered as an index of DNA synthesis and cell multiplication. A single injection of pregnant mare serum gonadotropin could thus maximally stimulate by 18 hr³H-thymidine incorporation into DNA of the ovary of immature hamsters. Neutralization of pregnant mare serum gonadotropin by an antiserum to ovine follicle stimulating hormone only during the initial 8–10 hr and not later could inhibit the increase in³H-thymidine incorporationin vitro observed at 18 hr, suggesting that the continued presence of gonadotropin stimulus was not necessary for this response. The other indices of follicular growth monitored such as ovarian weight, serum estradiol and uterine weight showed discernible increase at periods only after the above initial event. A single injection of estrogen (diethyl stilbesterol or estradiol-l7β) could similarly cause 18 hr later, a stimulation in the rate of incorporation of³H-thymidine into DNAin vitro in ovaries of immature rats. The presence of endogenous gonadotropins, however, was obligatory for observing this response to estrogen. Evidence in support of the above was two-fold: (i) administration of antiserum to follicle stimulating hormone or luteinizing hormone along with estrogen completely inhibited the increase in³H-thymidine incorporation into ovarian DNAin vitro; (ii) a radioimmunological measurement revealed following estrogen treatment, the presence of a higher concentration of endogenous follicle stimulating hormone in the ovary. Finally, administration of varying doses of ovine follicle stimulating hormone along with a constant dose of estrogen to immature rats produced a dose-dependent increment in the incorporation of³H-thymidine into ovarian DNAin vitro. These observations suggested the potentiality of this system for developing a sensitive bioassay for follicle stimulating hormone.     

Isolation of mosquito vitellogenin genes and induction of expression by 20-hydroxyecdysone

Vitellogenic female Aedes aegypti contain abundant, 6500 nucleotide long RNAs that are not present in males or non-vitellogenic females and which were presumed to encode vitellogenin (VG). Three clones that hybridized to cDNA made to poly(A⁺)RNA from vitelogenic females, but not to cDNA made to male RNA, were selected from a genomic library. DNA from each clone hybridized to the 6500 nucleotide RNA species. Restriction enzyme mapping suggests the clones represent three distinct genes. The two that have been characterized share an uninterrupted region of homology about 6.5 kb long. Part of the coding region of one of the cloned genes was inserted into an expression vector, and the resulting polypeptide reacted specifically with antibodies to vitellogenin, thus confirming that the clones contain VG genes. Using one of the cloned genes as a probe on northern hybridizations we found that injection of 20-hydroxyecdysone into non-blood-fed decapitated females stimulated vitellogenin gene expression. The response was much greater in blood-fed decapitated females than in non-blood-fed females.     

Identification and genetic localization of mRNAs from ovarian follicle cells of Drosophila melanogaster.

RNA synthesis in ovarian follicles of Drosophila melanogaster was studied by methods which eliminate experimentally induced alterations in gene expression. Gel electrophoresis of follicular RNA, labeled after injection of precursors into females, revealed qualitative and quantitative differences in synthesis during the course of oogenesis. A highly heterogeneous group of poly(A)-containing RNAs is produced during much of the course of follicular development. However, post-vitellogenic stages synthesize a small number of stage-specific poly(A)-containing RNAs. During this period, RNA synthesis is known to take place primarily in the follicle cells, which are engaged in the production of the endochorion and exochorion. Two intense bands of nonmitochondrial poly(A)⁺ RNA are labeled between stage 11 and early stage 13. The synthesis of a more heterogeneous group of very small poly(A)-containing RNAs characterizes the last part of oogenesis, stages 13 and 14. Evidence is presented to show that these RNAs are specifically localized in the follicle cells of the egg chamber. We propose that they represent mRNAs for chorion proteins. In situ hybridization of preparations of late stage poly(A)-containing RNA to salivary gland chromosomes revealed two major sites of complementarity, 7E11 and 12E, as well as several minor sites. Experiments in which RNAs were separated on gels prior to hybridization in situ suggested that both the major stage 12-specific RNA bands contained molecules which were complementary to DNA in the 7E11 region. It is particularly interesting that this site is within a small chromosomal interval known to contain the gene ocelliless. Females homozygous for ocelliless have been shown to produce structurally abnormal chorions (Johnson and King, 1974).