Changes in rate of RNA synthesis and ribosomal gene number during oogenesis of Drosophila melanogaster

Finishing the egg

Gamete development is a fundamental process that is highly conserved from early eukaryotes to mammals. As germ cells develop, they must coordinate a dynamic series of cellular processes that support growth, cell specification, patterning, the loading of maternal factors (RNAs, proteins, and nutrients), differentiation of structures to enable fertilization and ensure embryonic survival, and other processes that make a functional oocyte. To achieve these goals, germ cells integrate a complex milieu of environmental and developmental signals to produce fertilizable eggs. Over the past 50 years, Drosophila oogenesis has risen to the forefront as a system to interrogate the sophisticated mechanisms that drive oocyte development. Studies in Drosophila have defined mechanisms in germ cells that control meiosis, protect genome integrity, facilitate mRNA trafficking, and support the maternal loading of nutrients. Work in this system has provided key insights into the mechanisms that establish egg chamber polarity and patterning as well as the mechanisms that drive ovulation and egg activation. Using the power of Drosophila genetics, the field has begun to define the molecular mechanisms that coordinate environmental stresses and nutrient availability with oocyte development. Importantly, the majority of these reproductive mechanisms are highly conserved throughout evolution, and many play critical roles in the development of somatic tissues as well. In this chapter, we summarize the recent progress in several key areas that impact egg chamber development and ovulation. First, we discuss the mechanisms that drive nutrient storage and trafficking during oocyte maturation and vitellogenesis. Second, we examine the processes that regulate follicle cell patterning and how that patterning impacts the construction of the egg shell and the establishment of embryonic polarity. Finally, we examine regulatory factors that control ovulation, egg activation, and successful fertilization.

The role of metabolism in cellular quiescence

Cellular quiescence is a dormant, non-dividing cell state characterized by significant shifts in physiology and metabolism. Quiescence plays essential roles in a wide variety of biological processes, ranging from microbial sporulation to human reproduction and wound repair. Moreover, when the regulation of quiescence is disrupted, it can drive cancer growth and compromise tissue regeneration after injury. In this Review, we examine the dynamic changes in metabolism that drive and support dormant and transiently quiescent cells, including spores, oocytes and adult stem cells. We begin by defining quiescent cells and discussing their roles in key biological processes. We then examine metabolic factors that influence cellular quiescence in both healthy and disease contexts, and how these could be leveraged in the treatment of cancer.

Mitochondrial respiratory quiescence: A new model for examining the role of mitochondrial metabolism in development

Mitochondria are vital organelles with a central role in all aspects of cellular metabolism. As a means to support the ever-changing demands of the cell, mitochondria produce energy, drive biosynthetic processes, maintain redox homeostasis, and function as a hub for cell signaling. While mitochondria have been widely studied for their role in disease and metabolic dysfunction, this organelle has a continually evolving role in the regulation of development, wound repair, and regeneration. Mitochondrial metabolism dynamically changes as tissues transition through distinct phases of development. These organelles support the energetic and biosynthetic demands of developing cells and function as key structures that coordinate the nutrient status of the organism with developmental progression. This review will examine the mechanisms that link mitochondria to developmental processes. We will also examine the process of mitochondrial respiratory quiescence (MRQ), a novel mechanism for regulating cellular metabolism through the biochemical and physiological remodeling of mitochondria. Lastly, we will examine MRQ as a system to discover the mechanisms that drive mitochondrial remodeling during development.

Highly conserved shifts in ubiquitin-proteasome system (UPS) activity drive mitochondrial remodeling during quiescence

Defects in cellular proteostasis and mitochondrial function drive many aspects of infertility, cancer, and other age-related diseases. All of these conditions rely on quiescent cells, such as oocytes and adult stem cells, that reduce their activity and remain dormant as part of their roles in tissue homeostasis, reproduction, and even cancer recurrence. Using a multi-organism approach, we show that dynamic shifts in the ubiquitin proteasome system drive mitochondrial remodeling during cellular quiescence. In contrast to the commonly held view that the ubiquitin-proteasome system (UPS) is primarily regulated by substrate ubiquitination, we find that increasing proteasome number and their recruitment to mitochondria support mitochondrial respiratory quiescence (MRQ). GSK3 triggers proteasome recruitment to the mitochondria by phosphorylating outer membrane proteins, such as VDAC, and suppressing mitochondrial fatty acid oxidation. This work defines a process that couples dynamic regulation of UPS activity to coordinated shifts in mitochondrial metabolism in fungi, Drosophila, and mammals during quiescence.

Dynamic regulation of cellular proteostasis is linked to the metabolic state of quiescent cells in vivo. Here, the authors show, in multiple organisms, that shifts in the ubiquitin-proteome system are coupled to mitochondrial metabolic changes and subsequent respiratory quiescence.

Heritable shifts in redox metabolites during mitochondrial quiescence reprogramme progeny metabolism

Changes in maternal diet and metabolic defects in mothers can profoundly affect health and disease in their progeny. However, the biochemical mechanisms that induce the initial reprogramming events at the cellular level have remained largely unknown owing to limitations in obtaining pure populations of quiescent oocytes. Here, we show that the precocious onset of mitochondrial respiratory quiescence causes a reprogramming of progeny metabolic state. The premature onset of mitochondrial respiratory quiescence drives the lowering of Drosophila oocyte NAD⁺ levels. NAD⁺ depletion in the oocyte leads to reduced methionine cycle production of the methyl donor S-adenosylmethionine in embryos and lower levels of histone H3 lysine 27 trimethylation, resulting in enhanced intestinal lipid metabolism in progeny. In addition, we show that triggering cellular quiescence in mammalian cells and chemotherapy-resistant human cancer cell models induces cellular reprogramming events identical to those seen in Drosophila, suggesting a conserved metabolic mechanism in systems reliant on quiescent cells.

Drosophila oocyte proteome composition covaries with female mating status

Oocyte composition can directly influence offspring fitness, particularly in oviparous species such as most insects, where it is the primary form of parental investment. Oocyte production is also energetically costly, dependent on female condition and responsive to external cues. Here, we investigated whether mating influences mature oocyte composition in Drosophila melanogaster using a quantitative proteomic approach. Our analyses robustly identified 4,485 oocyte proteins and revealed that stage-14 oocytes from mated females differed significantly in protein composition relative to oocytes from unmated females. Proteins forming a highly interconnected network enriched for translational machinery and transmembrane proteins were increased in oocytes from mated females, including calcium binding and transport proteins. This mating-induced modulation of oocyte maturation was also significantly associated with proteome changes that are known to be triggered by egg activation. We propose that these compositional changes are likely to have fitness consequences and adaptive implications given the importance of oocyte protein composition, rather than active gene expression, to the maternal-to-zygotic transition and early embryogenesis.

CTP synthase polymerization in germline cells of the developing Drosophila egg supports egg production

Polymerization of metabolic enzymes into micron-scale assemblies is an emerging mechanism for regulating their activity. CTP synthase (CTPS) is an essential enzyme in the biosynthesis of the nucleotide CTP and undergoes regulated and reversible assembly into large filamentous structures in organisms from bacteria to humans. The purpose of these assemblies is unclear. A major challenge to addressing this question has been the inability to abolish assembly without eliminating CTPS protein. Here we demonstrate that a recently reported point mutant in CTPS, Histidine 355A (H355A), prevents CTPS filament assembly in vivo and dominantly inhibits the assembly of endogenous wild-type CTPS in the Drosophila ovary. Expressing this mutant in ovarian germline cells, we show that disruption of CTPS assembly in early stage egg chambers reduces egg production. This effect is exacerbated in flies fed the glutamine antagonist 6-diazo-5-oxo-L-norleucine, which inhibits de novo CTP synthesis. These findings introduce a general approach to blocking the assembly of polymerizing enzymes without eliminating their catalytic activity and demonstrate a role for CTPS assembly in supporting egg production, particularly under conditions of limited glutamine metabolism.This article has an associated First Person interview with the first author of the paper.

The role of metabolic states in development and disease

During development, cells adopt distinct metabolic strategies to support growth, produce energy, and meet the demands of a mature tissue. Some of these metabolic states maintain a constrained program of nutrient utilization, while others providing metabolic flexibility as a means to couple developmental progression with nutrient availability. Here we discuss our understanding of metabolic programs, and how they support specific aspects of animal development. During phases of rapid proliferation a subset of metabolic programs provide the building blocks to support growth. During differentiation, metabolic programs shift to support the unique demands of each tissue. Finally, we discuss how a model system, such as Drosophila egg development, can provide a versatile platform to discover novel mechanisms controlling programmed shift in metabolism.

Electron Transport Chain Remodeling by GSK3 during Oogenesis Connects Nutrient State to Reproduction

Reproduction is heavily influenced by nutrition and metabolic state. Many common reproductive disorders in humans are associated with diabetes and metabolic syndrome. We characterized the metabolic mechanisms that support oogenesis and found that mitochondria in mature Drosophila oocytes enter a low-activity state of respiratory quiescence by remodeling the electron transport chain (ETC). This shift in mitochondrial function leads to extensive glycogen accumulation late in oogenesis and is required for the developmental competence of the oocyte. Decreased insulin signaling initiates ETC remodeling and mitochondrial respiratory quiescence through glycogen synthase kinase 3 (GSK3). Intriguingly, we observed similar ETC remodeling and glycogen uptake in maturing Xenopus oocytes, suggesting that these processes are evolutionarily conserved aspects of oocyte development. Our studies reveal an important link between metabolism and oocyte maturation.

Ack kinase regulates CTP synthase filaments during Drosophila oogenesis

The enzyme CTP synthase (CTPS) dynamically assembles into macromolecular filaments in bacteria, yeast, Drosophila, and mammalian cells, but the role of this morphological reorganization in regulating CTPS activity is controversial. During Drosophila oogenesis, CTPS filaments are transiently apparent in ovarian germline cells during a period of intense genomic endoreplication and stockpiling of ribosomal RNA. Here, we demonstrate that CTPS filaments are catalytically active and that their assembly is regulated by the non-receptor tyrosine kinase DAck, the Drosophila homologue of mammalian Ack1 (activated cdc42-associated kinase 1), which we find also localizes to CTPS filaments. Egg chambers from flies deficient in DAck or lacking DAck catalytic activity exhibit disrupted CTPS filament architecture and morphological defects that correlate with reduced fertility. Furthermore, ovaries from these flies exhibit reduced levels of total RNA, suggesting that DAck may regulate CTP synthase activity. These findings highlight an unexpected function for DAck and provide insight into a novel pathway for the developmental control of an essential metabolic pathway governing nucleotide biosynthesis.

Generation of Minute phenotypes by a transformed antisense ribosomal protein gene

Antisense RNAs have been used for gene interference experiments in many cell types and organisms. However, relatively few experiments have been conducted with antisense genes integrated into the germ line. In Drosophila reduced ribosomal protein (r-protein) gene function has been hypothesized to result in a Minute phenotype. In this report we examine the effects of antisense r-protein 49 expression, a gene known to correspond to a Minute mutation An antisense rp49 gene driven by a strong and inducible promoter was transformed into the Drosophila germ line. Induction of this gene led to the development of flies with weak Minute phenotypes and to the transient arrest of oogenesis. Parameters that may affect the success of antisense gene inactivation are discussed.

Antisense ribosomal protein gene expression specifically disrupts oogenesis in Drosophila melanogaster

To assess the functional importance of ribosomal protein rpA1 gene expression during development of Drosophila melanogaster, we have transformed into the fly's genome an antisense rpA1 gene driven by a heat shock promoter. Antisense rpA1 expression severely disrupted oogenesis and produced a "small egg" female-sterile phenotype. The severities of these defects were proportional to the level of antisense rpA1 expression. Anti-rpA1 expression did not affect larval or pupal development. Quantitative RNA analysis suggested that high anti-rpA1 expression results in a general decrease of mRNA in the ovary.

Selective translational regulation of ribosomal protein gene expression during early development of Drosophila melanogaster

We have previously characterized a cloned cDNA coding for a developmentally regulated mRNA in Drosophila melanogaster whose expression is selectively regulated at the translational level during oogenesis and embryogenesis. In this report we show that this translationally regulated mRNA (rpA1) codes for an acidic ribosomal protein. Furthermore, our results indicate that most ribosomal protein mRNAs are regulated similarly to rpA1 mRNA. This conclusion is based on cell-free translation of mRNAs derived from polysomes and postpolysomal supernatants as well as in vivo labeling experiments. Thus, the translation of many ribosomal protein mRNAs appears to be temporally related to the synthesis of rRNA during D. melanogaster development. The relationship between rRNA transcription and ribosomal protein mRNA translation was further investigated by genetically reducing rRNA synthesis with the use of bobbed mutants. Unexpectedly, neither ribosomal protein mRNA abundance nor translation was altered in these mutants.

Selective translational regulation of ribosomal protein gene expression during early development of Drosophila melanogaster

We have previously characterized a cloned cDNA coding for a developmentally regulated mRNA in Drosophila melanogaster whose expression is selectively regulated at the translational level during oogenesis and embryogenesis. In this report we show that this translationally regulated mRNA (rpA1) codes for an acidic ribosomal protein. Furthermore, our results indicate that most ribosomal protein mRNAs are regulated similarly to rpA1 mRNA. This conclusion is based on cell-free translation of mRNAs derived from polysomes and postpolysomal supernatants as well as in vivo labeling experiments. Thus, the translation of many ribosomal protein mRNAs appears to be temporally related to the synthesis of rRNA during D. melanogaster development. The relationship between rRNA transcription and ribosomal protein mRNA translation was further investigated by genetically reducing rRNA synthesis with the use of bobbed mutants. Unexpectedly, neither ribosomal protein mRNA abundance nor translation was altered in these mutants.

Translational regulation of mRNAs for ribosomal proteins during early Drosophila development

In Drosophila, the vast majority of mRNAs that are polysome associated during oogenesis are also polysome associated during early embryogenesis. We have previously identified an exceptional mRNA that appears to be depleted from early-embryo polysomes [Fruscoloni, P., Al-Atia, G. R., & Jacobs-Lorena, M. (1983) Proc. Natl. Acad. Sci. U.S.A. 80, 3359-3363]. This mRNA has been subsequently identified as coding for a ribosomal protein (r-protein) [Kay, M., & Jacobs-Lorena, M. (1985) Mol. Cell. Biol. (in press)]. Changes in association with polysomes of two r-protein mRNAs during early Drosophila development were investigated for this report. Hybridization of cloned DNA probes to blots of RNA obtained from sucrose gradient fractions reveals that r-protein mRNAs are substantially associated with polysomes during oogenesis, depleted from polysomes during early embryogenesis, and again polysome associated during late embryogenesis. Thus, translation of r-protein mRNAs parallels transcription of ribosomal RNA (rRNA) during this time of development. By contrast, no such differences were observed when actin and histone probes were used as controls and hybridized to the same blots. The abundance of mRNAs for r-proteins as a function of development was also measured. Abundance was relatively high and constant during oogenesis and embryogenesis (when translational regulation is apparent), somewhat decreased in larval and pupal stages, and low in adult nonovarian tissues. Coordination between r-protein and rRNA synthesis appears to be achieved by regulating translation of r-protein mRNAs in early embryos and by decreasing their abundance in adult tissues.

Biphasic pattern of histone gene expression during Drosophila oogenesis

The expression of histone genes during Drosophila oogenesis was compared to periods of DNA synthesis as well as to the pattern of actin gene expression. Accumulation of histone mRNAs was measured by RNA blot hybridization. Relatively low levels of histone mRNAs are present in egg chambers prior to stage 10, during the period of nurse and follicle cell polyploidization. Surprisingly, histone mRNAs accumulate rapidly and selectively after stage 10, coinciding with the onset of nurse cell degeneration and well after DNA synthesis and actin mRNA accumulation have ceased. A large proportion of the histone mRNAs is associated with polysomes at all times, indicating that expression of histone genes is not strictly coupled to DNA synthesis. The burst of histone mRNA accumulation near the end of oogenesis may provide a store of maternal histone mRNA to support the rapid cleavages that occur during early embryogenesis. These and previous results suggest that genes are independently regulated during differentiation of the Drosophila egg chamber.

mRNA usage during Drosophila melanogaster embryonic development. Analysis of nine cloned DNA segments

A set of nine phage lambda clones containing inserts from Drosophila melanogaster which are complementary to cDNA made from oocyte poly(A)+ RNA were selected from a larger group. These cloned elements code for a range of middle abundant RNA sequences which show no appreciable change in abundance during Drosophila embryogenesis. Seven of the nine clones are complementary to two oocyte RNAs, one to three RNAs and one to four RNAs. This study describes the changes that occur in these RNAs during embryonic development in the polysomal and non-polysomal fraction, and in the poly(A)+ RNA and poly(A)- RNA fraction. In all nine of these clones, greater than 70% of the complementary RNA is found in the polysomal region of a sucrose gradient. This proportion increases somewhat during development. Specific changes have been found during development in the proportion of RNA that is poly(A)+. Depending to the cloned sequence, this proportion may increase, decrease, or remain unchanged. For those clones that show a change, most of this change occurs between 8 and 19 h of development. Our data suggest, furthermore, the presence of a class of non-adenylated RNA being utilized during embryogenesis.

Determination of DNA content in the nurse and follicle cells from wild type and mutant Drosophila melanogaster by DNA-Feulgen cytophotometry

DNA replication patterns in the nurse and follicle cells of wild type and a female sterile mutant, fs(1)1304, of Drosophila melanogaster have been studied by DNA-Feulgen cytophotometry, using a cell dispersal technique that allowed the measurement of DNA amounts in individual nuclei from egg chambers of known developmental stages. DNA-Feulgen values associated with various ovarian nuclei from egg chambers at different stages of development were used to assess a base line DNA content for ovarian tissues and to estimate the extent of DNA replication in the nurse cells and follicle cells of growing and mature egg chambers. Our data show that both the nurse and follicle cells undergo multiple cycles of endonuclear DNA replication and that there may be selective amplification as well as underreplication by portions of the genome in these highly polyploid, ovarian cells. Alternative models are proposed to account for the DNA replication patterns observed. Comparisons of DNA-Feulgen levels in wild type ovarian nuclei with those found for the fs(1)1304 mutant and its heterozygote in the balanced stock fs/FM3, show that equivalent DNA levels are present in follicle cell nuclei from all three types of females. Nurse cell nuclei in the homozygous fs stock, however, fail to achieve the same high DNA levels observed in both fs/FM3 and wild type nurse cell nuclei. Although the nuclei of follicle cells in ovaries from fs/fs females appear morphologically like those surrounding egg chambers in wild type ovaries, nurse cell nuclei from mutant females show a more compacted organization of their chromatin than found for nurse cell nuclei from wild type ovaries at similar developmental stages. Our findings suggest that a major effect of the fs(1)1304 mutation may be on the coiling behavior of chromatin and the conformation of DNA-protein moieties in both nurse cell and follicle cell nuclei. These changes in chromatin structure apparently are manifest by perturbations in DNA replication patterns and normal gene function in these biosynthetically active cells.

Chromosome structure and DNA replication in nurse and follicle cells of Drosophila melanogaster

In the nurse cells of Drosophila, nuclear DNA is replicated many times without nuclear division. Nurse cells differ from salivary gland cells, another type of endoreplicated Drosophila cell, in that banded polytene chromosomes are not seen in large nurse cells. Cytophotometry of Feulgen stained nurse cell nuclei that have also been labeled with 3H-thymidine shows that the DNA contents between S-phases are not doublings of the diploid value. In situ hybridization of cloned probes for 28S + 18S ribosomal RNA, 5S RNA, and histone genes, and for satellite, copia, and telomere sequences shows that satellite and histone sequences replicate only partially during nurse cell growth, while 5S sequences fully replicate. However, during the last nurse cell endoreplication cycle, all sequences including the previously under-replicated satellite sequences replicate fully. In situ hybridization experiments also demonstrate that the loci for the multiple copies of histone and 5S RNA genes are clustered into a small number of sites. In contrast, 28S + 18S rRNA genes are dispersed. We discuss the implications of the observed distribution of sequences within nurse cell nuclei for interphase nuclear organization. In the ovarian follicle cells, which undergo only two or three endoreplication cycles, satellite, histone and ribosomal DNA sequences are also found by in situ hybridization to be underrepresented; satellite sequences may not replicate beyond their level in 2C cells. Hence the pathways of endoreplication in three cell types, salivary gland, nurse, and follicle cells, share basic features of DNA replication, and differ primarily in the extent of association of the duplicated chromatids.

Preferential expression of actin genes during oogenesis of Drosophila

The expression of actin genes was examined during oogenesis of Drosophila. Accumulation of actin proteins was quantitated by a two-stage electrophoresis procedure. Egg chambers accumulate actins preferentially, resulting in a twofold enrichment over other nonyolk proteins. RNA gel blot hybridization experiments demonstrated a concomitant twofold selective increase of actin mRNA levels over that of other mRNAs, suggesting regulation of actin genes at the pretranslational level. Despite an abrupt arrest of actin protein accumulation near the end of oogenesis, the bulk of the actin mRNAs remains associated with polysomes of constant size. It appears that this shut-off of actin protein accumulation is due to an overall decrease in translational efficiency, rather than actin mRNA degradation or its dissociation from polysomes.

Expression of the ribosomal DNA insertions in bobbed mutants of Drosophila melanogaster

We have shown earlier that interrupted rRNA genes in Drosophila melanogaster do not contribute significantly to rRNA production by a splicing mechanism (Long and Dawid 1979). In the work reported here the expression of interrupted rRNA genes was tested in several stocks that carry bobbed mutations, i.e., have partial deletions of their rRNA gene clusters. Transcripts of the major 5 kb type 1 insertion are very rare in bobbed flies as they are in the wild type, occurring at a concentration in embryos of less than one copy per nucleus. Transcripts of short type 1 insertions are more abundant in certain bobbed stocks, especially those carrying the car bb chromosome. However, other severely bobbed flies have no increase in these insertion transcripts over the wild-type levels. Type 2 insertions are transcribed into very rare RNA molecules in the wild type and in the bobbed genotypes that were studied. From these results we conclude that interrupted rRNA genes are not expressed through a splicing mechanism into mature rRNA in mutant or wild-type flies. Since even severely bobbed flies fail to utilize their interrupted rRNA genes, we suggest that these genes cannot be transcribed productively in D. melanogaster.

Characterization of the female sterile (1) 1304 mutant of Drosophila melanogaster: pattern of RNA metabolism in the ovary

The female sterile mutant of Drosophila melanogaster, fs(1)1304 (1-19 +/- 2), has been characterized. Our studies show that the mutation affects the organization of nucleolar material in the ovarian nurse cells and the pattern of RNA metabolism in the ovary. Autoradiographic analysis of incorporation of 3H-uridine in vivo and analysis of 3H-uridine incorporation into high molecular weight RNA in vitro suggest that RNA from the ovaries of homozygous fs flies is degraded at a higher rate than that from heterozygous fs and wild-type ovaries. It is likely that the RNA class affected is ribosomal RNA. These data are discussed in the context of the functional role for the wild-type gene allelic to fs(1)1304, and it is suggested that one of the effects of the mutation may be on the biogenesis of ribosomes that are to be stored in the oocyte.

DNA-dependent RNA polymerases from Drosophila melanogaster adults: isolation and partial characterization

In preparation for the isolation and biochemical characterization of putative RNA polymerase mutants, DNA-dependent RNA polymerases of Drosophila melanogaster adults were isolated and partially characterized. Approximately 70% of the female adult RNA polymerase is located in ovaries. Multiple forms of ovarian RNA polymerases I and II are separable by DEAE-Sephadex chromatography. The two forms of RNA polymerase II differ in ammonium sulfate optima. RNA polymerase IIA is more active with double-stranded DNA as template, whereas RNA polymerase IIB transcribes single-stranded DNA most efficiently. Rechromatography of RNA polymerase IIA on DEAE-Sephadex results in the loss of ability of this form to transcribed double-stranded DNA most efficiently. Ovariectomized carcasses have two forms of RNA polymerase I and one form of RNA polymerase II and each transcribes single-stranded DNA most efficiently. As judged by gel filtration chromatography, female adult extracts have forms of RNA polymerase II that differ in molecular weight and template preference.

Expression of ribosomal DNA insertions in Drosophila melanogaster

Approximately half of the ribosomal genes on the X chromosome of Drosophila melanogaster are interrupted by an insertion of type 1. Nuclear RNA from D. melanogaster embryos was transferred to DBM paper and hybridized with cloned type 1 insertion sequences. With a DNA fragment derived specifically from large insertions, transcripts were detected between 5 and 10 kb. These insertion transcripts represent less than one RNA molecule per nucleus, which is more than three orders of magnitude below the concentration of nascent rRNA chains, as determined by kinetics of hybridization. With a DNA fragment derived from the right end of large insertions which is also complementary to short insertions, more discrete RNA bands appeared with sizes between 1 and 8.5 kb, representing altogether about 13 RNA molecules per nucleus. Insertion transcripts large enough to be potential precursors to 28S rRNA represent less than one molecule per nucleus. It was shown by sandwich hybridization that at least some of the insertion transcripts are derived from rDNA. No significant difference was found between insertion transcripts in RNA extracted from ovaries, embryos, larvae, pupae or adult flies. Unless a mechanism other than splicing is involved, ribosomal genes with insertions cannot contribute significantly to the synthesis of 28S rRNA. A cytoplasmic RNA approximately 1 kb long, which is complementary to a short insertion and to ribosomal gene sequences flanking both sides of the insertion, was found. The abundance of this short unspliced RNA is about 50 molecules per embryo cell.