The ontogeny of germ plasm during oogenesis in Drosophila

Primordial germ cells can be induced at both the anterior and ventral region of the Drosophila egg by transplanted posterior polar plasm. Two questions arise from these results: (1) Is fertilization required for germ plasm to be functional, and (2) at what stage during oogenesis does the posterior polar plasm become established as a germ-cell determinant?Polar plasm from unfertilized eggs and from oocytes at stage 10 to 14 of Drosophila melanogaster was implanted into the anterior region of cleavage embryos. Some injected embryos were analyzed at the ultrastructural level during blastoderm formation. Polar plasm from unfertilized eggs and from oocytes of stages 13 and 14 was found to be integrated into several anterior cells that resembled morphologically normal pole cells. The formation of such cells, however, could not be detected in embryos injected with polar plasm from oogenetic stages 10 to 12. Experimentally induced pole cells proved to be capable of differentiating into functional germ cells when cycled through the germ line of genetically different host embryos. About 5% of the flies developing from these embryos produced progeny that originated from the induced pole cells. Germ-line mosaicism in those flies also could be detected histochemically in their gonads. No germ cells were recovered with polar plasm transplants from oogenetic stages 10 to 12.The results show that posterior polar plasm of the unfertilized egg is functional in germ-cell determination, and that prior to egg maturation this cytoplasm has already acquired its determinative ability. This is the first demonstration that specific developmental information stored in the cytoplasm can be traced back to a particular region of the oocyte.     

Activation of ascidian eggs with lectins

Eggs of Phallusia mammillata, dechorionated with trypsin, were activated in solutions of concanavalin A and wheat germ agglutinin. The polar bodies were extruded, and an aster appeared, but there was no cleavage. Ooplasmic segregation took place and mitochondria accumulated at the vegetal pole. Large chromatic granules formed in older eggs. The striking parallel between the migration of lectin receptors to the vegetal pole and “capping” was noted.     

Interspecific transplantation of polar plasm between Drosophila embryos

Posterior polar plasm of the Drosophila egg has been shown to function autonomously in germ cell determination after transplantation to either the anterior or mid-ventral region of the early embryo. By means of similar transplantations, we have tested the ability of polar plasm of Drosophila immigrans to induce the formation of pole cells in a Drosophila melanogaster embryo. After the transplantation of polar plasm, "hybrid" pole cells were found in which both pole cell-specific organelles, the polar granules and nuclear body, were structurally similar to those characteristic of the transplanted cytoplasm. In order to determine whether these hybrid cells can function as germ cell precursors, these cells were transplanted to the posterior tip of genetically marked embryos. Approximately 5% of the flies obtained from embryos receiving potential pole cells produce offspring derived from the induced pole cells. This result demonstrates that polar plasm can function in interspecific species combinations and indicates that the molecular mechanisms of germ cell determination are conservative in evolution. Finally, in order to test whether there is any evidence for cytoplasmic inheritance of polar granules, embryos derived from hybrid pole cells were examined for their polar granule morphology. The fine structure of the granules conformed to that of the nucleus. Thus, no evidence was found for the cytoplasmic inheritance of these particular organelles.     

tudor, a gene required for assembly of the germ plasm in Drosophila melanogaster

Developmental analysis of a newly isolated maternal effect grandchildless mutant, tudor (tud), in Drosophila melanogaster indicates that tud+ activity is required during oogenesis for the determination and/or formation of primordial germ cells (pole cells) and for normal embryonic abdominal segmentation. Regardless of their genotype, progeny of females homozygous for strong alleles (tud1 and tud3) never form pole cells, apparently lack polar granules in the germ plasm, and approximately 40% of them die during late embryogenesis exhibiting severe abdominal segmentation pattern defects. Females carrying weak allele, tud4, produce progeny with some functional pole cells and form polar granules approximately one-third the size of those observed in wild-type oocytes and embryos. No segmentation abnormalities are observed in the inviable embryos derived from tud4/tud4 females.     

Identification of a component of Drosophila polar granules

Information necessary for the formation of pole cells, precursors of the germ line, is provided maternally and localized to the posterior pole of the Drosophila egg. The maternal origin and posterior localization of polar granules suggest that they may be associated with pole cell determinants. We have generated an antibody (Mab46F11) against polar granules. In oocytes and early embryos, the Mab46F11 antigen is sharply localized to the posterior embryonic pole. In pole cells, it becomes associated with nuclear bodies within, and nuage around, the nucleus. Immunoreactivity remains associated with cells of the germ line throughout the life cycle of both males and females. This antibody recognizes a 72-74 X 10(3) Mr protein and is useful both as a pole lineage marker and in biochemical studies of polar granules.     

Tudor protein is essential for the localization of mitochondrial RNAs in polar granules of Drosophila embryos

In Drosophila, polar plasm contains polar granules, which deposit the factors required for the formation of pole cells, germ line progenitors. Polar granules are tightly associated with mitochondria in early embryos, suggesting that mitochondria could contribute to pole cell formation. We have previously reported that mitochondrial large and small rRNAs (mtrRNAs) are transported from mitochondria to polar granules prior to pole cell formation and the large rRNA is essential for pole cell formation. Here we show that the localization of mtrRNAs is diminished in embryos laid by tudor mutant females, although the polar granules are maintained. We also found that Tud protein was colocalized with mtrRNAs at the boundaries between mitochondria and polar granules when the transport of mtrRNAs takes place. These observations suggest that Tud mediates the transport of mtrRNAs from mitochondria to polar granules.     

Expression and intracellular localization of mouse Vasa-homologue protein during germ cell development

To demonstrate the cellular and subcellular localization of mouse vasa homologue protein during germ cell development, specific antibody was raised against the full-length MVH protein. The immunohistochemical analyses demonstrated that MVH protein was exclusively expressed in primordial germ cells just after their colonization of embryonic gonads and in germ cells undergoing gametogenic processes until the post-meiotic stage in both males and females. The co-culture of EG cells with gonadal somatic cells indicated inductive MVH expression caused by an intercellular interaction with gonadal somatic cells. In adult testis, MVH protein was localized in the cytoplasm of spermatogenic cells, including chromatoid bodies in spermatids, known to be a perinuclear nuage structure which includes polar granules that contain VASA protein in Drosophila.     

Isolation of polar granules and the identification of polar granule-specific protein.

During early embryogenesis in Drosophila melanogaster the posterior polar plasm has the capacity to induce the formation of primordial germ cells. Polar granules, organelles located exclusively in this polar plasm, have been implicated in this determinative capacity. Using cell populations enriched for pole cells as starting material, we have obtained a particulate subcellular fraction that by EM analysis consists predominately of polar granules. The chemical nature of the polar granule has been defined by establishing a strict correlation between the morphological entity and the presence of specific chemical components. We have identified a basic protein with a molecular weight on SDS-polyacrylamide gels of 95,000 daltons that is unique to embryonic cell populations containing pole cells. This protein is enriched specifically in particulate subcellular fractions containing polar granules and is the only major protein species present in preparations in which polar granules are the major morphological constituent. Based on these data, polar granules appear to be composed primarily of one major basic protein species.     

Pole cells of Drosophila melanogaster in culture. Normal metabolism, ultrastructure, and functional capabilities.

The metabolism, ultrastructure, and function of mass-isolated pole cells were examined during short-term culture in vitro. In addition to demonstrating that these cells functioned normally in culture, a number of new features of embryonic pole cells were discovered. Cell populations isolated from Renografin density gradients were incubated in medium containing tritiated valine, uridine, or thymidine. Although pole cells incorporated similar amounts of valine into protein as other embryonic cells throughout the first 6 hr in culture, they began to synthesize RNA only after 2 hr in culture. Approximately 30% of the pole cells synthesized DNA in vitro and this synthetic activity occurred largely during the first hour of culture. An ultrastructural analysis of colcemid-treated cells showed that 10% of the pole cells divide shortly after placement in culture. During pole cell culture in vitro, polar granules and nuclear bodies fragment and disperse so that they are eventually not detected in these cells. These changes also occur during pole cell development in vivo. Finally, we have obtained 25 to 33% germ line mosaicism among the fertile adults which were derived from embryos receiving transplantation of isolated pole cells before and after culture in vitro. These results demonstrate that these cells are able to follow their normal developmental program in vitro and are able to give rise to functional germ cells in vivo.     

The Germ Plasm of Drosophila: An Experimental System for the Analysis of Determination

The posterior polar plasm of Drosophila melanogaster may providea model for understanding processes involved in cellular determinationduring early embryonic development. The presence of germ celldeterminants in the posterior tip of the egg has been demonstratedby transplanting this material to new locations and showingthat cells, induced at the site of transplantation, can functionas germ cells. Furthermore, by utilizing similar procedures,the posterior polar plasm of late stage oocytes has been shownto be functional in inducing germ cells, thus demonstratingthat the active components are formed during oogenesis. A numberof maternal effect mutations affecting germ cell formation havebeen analyzed ultrastructurally and the mutant phenotype described.Ultrastructural studies have focused on polar granules, theunique organelle of the polar plasm, and these studies indicatethat they are nonmembrane bound structures containing RNA andprotein. Although ultrastructural observations have suggestedthat the protein components of polar granules may be continuousin the cytoplasm of germ cells during the whole life cycle,nucleo-cytoplasmic hybrid pole cells indicate that the structureof the polar granule is dependent upon the nucleus in each newgeneration of oocytes. Finally, attempts are being made to obtaina purified polar granule fraction in order to test their rolein germ cell determination. Initial results indicate that clustersof ribosomes are attached to polar granules. Pole cells haverecently been isolated as an enriched source of polar granules.These isolated cells will also provide an opportunity to analyzethe unique traits of these cells at the time that they becomesegregated from the remaining cells of the embryo.     

Germline autonomous sterility of P-M dysgenic hybrids and their application to germline transfers in Drosophila melanogaster

The gonadal (GD) sterility of the P-M hybrid dysgenesis of Drosophila melanogaster was analyzed with reciprocal pole cell transfers. GD sterility was found to result from autonomous degeneration of germline cells; the death of individual germline cells could not be prevented by the surrounding tissues of nondysgenic flies. Germline cells of the M strains developed predominantly in the hybrid-dysgenic flies even at a low rate of GD sterility. The autonomous ability of germ plasm to induce functional germ cells was confirmed using hybrid-dysgenic hosts for transferring ectopically formed pole cells. The advantages of germline transfers using the hybrid-dysgenic hosts are discussed.     

Isolation and characterization ofgrandchildless-like mutants inDrosophila melanogaster

Summary Two temperature-sensitive sex-linkedgrandchildless (gs)-like mutations (gs(1)N26 andgs(1)N441) were induced by ethylmethane sulphonate inDrosophila melanogaster. They complemented each other and mapped at two different loci (1–33.8±0.7 forgs(1)N26 and 1–39.6±1.7 forgs(1)N441), which were not identical to those of any of thegs-like mutants reported in earlier work.Homozygous females of the newly isolated mutants produced eggs that were unable to form pole cells and developed into agametic adults. Competence of the embryos to form pole cells was not restored by wild-type sperm in either mutant; that is, the sterility caused by these mutations is controlled by a maternal effect.Fecundity and fertility ofgs(1)N26 females were low, and their male offspring showed a higher mortality than that of female offspring, causing an abnormal sex ratio. The frequency of agametic progeny was 93.1% and 55.8%, when the female parents were reared at 25° C and 18° C, respectively. In eggs produced by thegs(1)N26 females reared at 25° C, the migration of nuclei to the posterior pole was abnormal, and almost no pole cell formation occurred in these egg. Furthermore, half of these eggs failed to cellularize at the posterior pole. When the females were reared at 18° C, almost all of the eggs underwent complete blastoderm formation, and in half of these blastoderm embryos normal pole cells were formed.In the other mutant,gs(1)N441, the fecundity and fertility of the females were normal. The agametic frequency in the progeny was 70.8% and 18.6% when the female parents were reared at 25° C and 18° C, respectively. In the eggs laid by females reared either at 25° C or at 18° C, the migration of nuclei to the periphery and cellularization proceeded normally; nevertheless, in the majority of the embryos no pole cell formation occured at the stage when nuclei penetrated into the periplasm. When the females were reared at 18° C, some of the embryos from these females formed some round blastoderm cells with cytologically recognizable polar granules and nuclear bodies, which are attributes of pole cells. The temperature sensitive period ofgs(1)N441 was estimated to extend from stage 9 to 13 of King's stages of oogenesis.     

C-terminal moiety of Tudor contains its in vivo activity in Drosophila

Background

In early Drosophila embryos, the germ plasm is localized to the posterior pole region and is partitioned into the germline progenitors, known as pole cells. Germ plasm, or pole plasm, contains the polar granules which form during oogenesis and are required for germline development. Components of these granules are also present in the perinuclear region of the nurse cells, the nuage. One such component is Tudor (Tud) which is a large protein containing multiple Tudor domains. It was previously reported that specific Tudor domains are required for germ cell formation and Tud localization.

Methodology/Principal Findings

In order to better understand the function of Tud the distribution and functional activity of fragments of Tud were analyzed. These fragments were fused to GFP and the fusion proteins were synthesized during oogenesis. Non-overlapping fragments of Tud were found to be able to localize to both the nuage and pole plasm. By introducing these fragments into a tud mutant background and testing their ability to rescue the tud phenotype, I determined that the C-terminal moiety contains the functional activity of Tud. Dividing this fragment into two parts reduces its localization in pole plasm and abolishes its activity.

Conclusions/Significance

I conclude that the C-terminal moiety of Tud contains all the information necessary for its localization in the nuage and pole plasm and its pole cell-forming activity. The present results challenge published data and may help refining the functional features of Tud.     

Ectopic formation of primordial germ cells by transplantation of the germ plasm: Direct evidence for germ cell determinant in Xenopus

In many animals, the germ line is specified by a distinct cytoplasmic structure called germ plasm (GP). GP is necessary for primordial germ cell (PGC) formation in anuran amphibians including Xenopus. However, it is unclear whether GP is a direct germ cell determinant in vertebrates. Here we demonstrate that GP acts autonomously for germ cell formation in Xenopus.EGFP-labeled GP from the vegetal pole was transplanted into animal hemisphere of recipient embryos. Cells carrying transplanted GP (T-GP) at the ectopic position showed characteristics similar to the endogenous normal PGCs in subcellular distribution of GP and presence of germ plasm specific molecules. However, T-GP-carrying-cells in the ectopic tissue did not migrate towards the genital ridge. T-GP-carrying cells from gastrula or tailbud embryos were transferred into the endoderm of wild-type hosts. From there, they migrated into the developing gonad. To clarify whether ectopic T-GP-carrying cells can produce functional germ cells, they were identified by changing the recipients, from the wild-type Xenopus to transgenic Xenopus expressing DsRed2. After transferring T-GP carrying cells labeled genetically with DsRed2 into wild-type hosts, we could find chimeric gonads in mature hosts. Furthermore, the spermatozoa and eggs derived from T-GP-carrying cells were fertile. Thus, we have demonstrated that Xenopus germ plasm is sufficient for germ cell determination.     

Early embryonic development and diapause stage in the band-legged ground cricket Dianemobius nigrofasciatus

The band-legged ground cricket Dianemobius nigrofasciatus enters diapause at an early embryonic stage when adults are reared under short-day conditions or the eggs are exposed to a low temperature. We examined the morphological features of the embryo during early development and determined the exact stage of entry into diapause. In non-diapause eggs, no periplasmic space was observed in the surface region and a small number of nuclei surrounded by cytoplasm (energids) were found among the yolk granules and lipid droplets 12 h after egg laying (AEL) at 25°C. The energids sparsely but evenly populated the surface region at 40 h AEL, but there were some gaps between these energids. A continuous thin layer of nuclei with cytoplasm had completely covered the egg surface at 56 h AEL, suggesting that the blastoderm is formed between 40 and 56 h AEL. At 72 h AEL, we found a germ band at the posterior pole. Electron microscopy revealed clear cell membranes at 40 h AEL. Staining with rhodamine-dextran dye demonstrated that the cell membrane is formed when the nuclei appear on the egg surface at 12–24 h AEL. These results indicate that cellularization occurs before blastoderm formation. In diapause eggs, neither the embryonic rudiment nor germ band was formed, but a continuous layer of cells covered the egg surface. It is concluded that D. nigrofasciatus enters diapause at the cellular blastoderm.     

Fat facets interacts with vasa in the Drosophila pole plasm and protects it from degradation

Anterior-posterior patterning and germ cell specification in Drosophila requires the establishment, during oogenesis, of a specialized cytoplasmic region termed the pole plasm. Numerous RNAs and proteins accumulate to the pole plasm and assemble in polar granules. Translation of some of these RNAs is generally repressed and active only in pole plasm. Vasa (VAS) protein, an RNA helicase and a component of polar granules, is essential maternally for posterior patterning and germ cell specification, and VAS is a candidate translational activator in the pole plasm. VAS is stabilized within the pole plasm in that it is initially present throughout the entire embryo but strictly limited to the pole cells by the cellular blastoderm stage. hsp83 mRNA, which accumulates in the pole plasm through a stabilization-degradation mechanism, is another example. Here, we used a biochemical approach to identify proteins that copurify with VAS in crosslinked extracts. Prominent among these proteins was the ubiquitin-specific protease Fat facets (FAF), a pole plasm component [7], but one whose roles in posterior patterning and germ line specification have remained unclear. We present evidence that FAF interacts with VAS physically and reverses VAS ubiquitination, thereby stabilizing VAS in the pole plasm.     

Restoration of fertility in sterilized Drosophila eggs by transplantation of polar cytoplasm

A technique for transplantation of cytoplasm between Drosophila eggs is described. Polar cytoplasm of newly laid eggs was first made ineffective for the determination of germ cells by UV irradiation. The sterility which results from this UV irradiation could be prevented by the injection of polar cytoplasm, but not by the injection of anterior cytoplasm from unirradiated donor eggs. The results provide the first demonstration of transplantation of agents causing determination in an insect and also provide a bioassay for these agents.Microscopical observations of UV irradiated eggs with and without transplanted polar cytoplasm revealed that UV irradiation delays the migration of cleavage nuclei into the posterior periplasm and prevents cytoplasmic protrusions at the posterior pole from becoming isolated from the periplasm to form pole cells. Transplantation of polar cytoplasm repairs these defects.     

Changes in subcellular localization of mtlrRNA outside mitochondria in oogenesis and early embryogenesis of Drosophila melanogaster

Mitochondrial large ribosomal RNA (mtlrRNA) has been identified as a cytoplasmic factor inducing pole cells in ultraviolet (UV)-sterilized Drosophila embryos. In situ hybridization studies have revealed that mtlrRNA is present outside mitochondria localized on the surface of polar granules during the cleavage stage. In the present study, we describe the developmental changes in extramitochondrial mtlrRNA distribution through early embryogenesis using in situ hybridization at the light and electron microscopic level. No mtlrRNA signal was discernible on polar granules in the mature oocyte, unless the oocyte was activated for development. mtlrRNA was localized on the surface of polar granules during a limited period of stages from oocyte activation to pole bud formation and disappeared as soon as being detached from polar granules without entering pole cells. These changes in the temporal and spatial distribution of mtlrRNA outside mitochondria are compatible with the idea that mtlrRNA is required for pole cell formation but not for the differentiation of pole cells as functional germ cells.     

Analysis of the Drosophila maternal effect mutant MAT(3)1 by pole cell transplantation experiments

Summary Pole cell transplantations were used to construct germ line mosaics of the Drosophila melanogaster maternal effect mutant mat(3)1. The mutant is of particular interest since the development of embryos derived from homozygous mat(3)1 females is arrested at the pole cell stage. Such embryos form exclusively pole cells and no blastoderm cells. By means of germ line mosaics we could demonstrate the primary target tissue of mutant gene expression. For normal development the mat(3)1 ⁺gene has to be expressed in the germ line. Pole cells formed in defective embryos derived from homozygous mutant mothers were transplanted into normal recipient embryos to test their developmental potential. Heterozygous mat(3)1 pole cells were found to form fertile gametes in both sexes whereas homozygous mat(3)1 pole cells form fertile gametes only in males. The lack of progeny derived from homozygous mat(3)1 donor pole cells in recipient females further demonstrates the germ line autonomy of the mat(3)1 mutation. Pole cells from defective embryos that are transplanted into normal hosts colonize the gonads with the same frequency as donor pole cells derived from normal embryos. This indicates that mat(3)1 derived pole cells are normal with respect to their function as germ cells and that the mat(3)1 mutant might therefore offer a convenient source for the mass isolation of functional pole cells.     

Role of mitochondrial ribosome-dependent translation in germline formation in Drosophila embryos

In Drosophila, mitochondrially encoded ribosomal RNAs (mtrRNAs) form mitochondrial-type ribosomes on the polar granules, distinctive organelles of the germ plasm. Since a reduction in the amount of mtrRNA results in the failure of embryos to produce germline progenitors, or pole cells, it has been proposed that translation by mitochondrial-type ribosomes is required for germline formation. Here, we report that injection of kasugamycin (KA) and chloramphenicol (CH), inhibitors for prokaryotic-type translation, disrupted pole cell formation in early embryos. The number of mitochondrial-type ribosomes on polar granules was significantly decreased by KA treatment, as shown by electron microscopy. In contrast, ribosomes in the mitochondria and mitochondrial activity were unaffected by KA and CH. We further found that injection of KA and CH impairs production of Germ cell-less (Gcl) protein, which is required for pole cell formation. The above observations suggest that mitochondrial-type translation is required for pole cell formation, and Gcl is a probable candidate for the protein produced by this translation system.