Lineage analysis of transplanted individual cells in embryos of Drosophila melanogaster

Summary A method is presented which allows the study of the progeny of single cells during Drosophila embryogenesis. Cells from various larval anlagen of donor embryos labelled with a lineage tracer are individually transplanted from defined positions into similar, or different, positions in unlabelled hosts. The clones produced by these cells can be seen in whole mounts or in sections of fixed material, when using a histochemical marker (i.e. HRP), and/or in living embryos, when using fluorescent lineage tracers. The characteristics of the clones disclose lineage parameters, such as division patterns, morphogenetic movements and differentiation. The method is especially useful for testing the respective roles of positional information and cell lineage on the commitment of progenitor cells by transplanting these cells into heterotopic positions or into hosts of different genotypes.     

Lineage analysis of transplanted individual cells in embryos of Drosophila melanogaster

Summary We describe the results of cell transplantation experiments performed to investigate mesodermal lineages in Drosophila melanogaster, particularly the lineages of the somatic muscles, the visceral muscles and the fat body. Cells to be transplanted were labelled by injecting a mixture of horseradish peroxidase (HRP) and fluorescein-dextran (FITC) in wild-type embryos at the syncytial blastoderm stage. For transplantation cells were removed from the ventral furrow, 8–12 min after the start of gastrulation, and individually transplanted into homotopic or heterotopic locations of unlabelled wild-type hosts of the same age. HRP labelling in the resulting cell clones was demonstrated histochemically in the fully developed embryo; histotypes could be distinguished without ambiguity. Mesodermal cells were already found to be committed to mesodermal fates at the time of transplantation. They developed only into mesodermal derivatives and did not integrate in non-mesodermal organs upon heterotopical transplantation. No evidence was found for commitment to any particular mesodermal organ at the time of transplantation. The majority of somatic muscle clones contributed cells to only one segment. However, clones were not infrequently distributed through two or even three segments. Clones of fat body cells were generally restricted to a small region. However, cells of clones of visceral musculature were widely distributed. With respect to the proliferative abilities of transplanted cells the clones were difficult to interpret due to the syncytial character of the somatic musculature and the fact that the organization of the other organs is poorly understood. Evidence from histological observations of developing normal embryos indicates only three mitoses for mesodermal cells. Clones larger than seven cells were not found when embryos were fixed previous to germ-band shortening; larger clones were found in the fat body and visceral musculature after fixing the embryos at the end of organogenesis. Quantitative considerations suggest that a few mesodermal cells might perform more than three mitoses.     

Pole cells of Drosophila paulistorum: embryologic differentiation with symbionts.

The pole cells of young D. paulistorum embryos are destined to form the germinal cells of both male and female imagoes. In addition, specialized portions of the midgut may be derived from pole cell progenitors. In this initial study of their embryogenesis by means of electron microscopy, various stages of pole cell development are shown in both non-hybrid (potentially fertile) and intersemispecific hybrid (potentially sterile as males) materials. Originally, approximately 5 or 6 cells emerge to form the early polar cap and subsequently divide asynchronously until the 35-50 cells of the late polar cap are derived. Unlike other Drosophila species, however, mycoplasma-like symbionts, apparently an hereditary infection, have been traced to locations within the cytoplasm of these pole cells. They are depicted as arriving there after transmission via the egg cytoplasm, implicating this as their probable route of entry into the future germinal tissues of adult flies. It is postulated that these microorganisms function as an infectious reproductive isolating mechanism fostering hybrid male sterility between D. paulistorum semispecies.     

Organogenèse d'ovaries et de testicules stériles après cautérisation des cellules polaires de l'embryon du Doryphore (Leptinotarsa decemlineata SAY)

Summary Cauterization of pole cells in embryos of the Colorado beetle does not prevent organogenesis of the gonads. So, pole cells do not govern to the differentiation of the gonadal mesoderm (this latter is limited to abdominal segments 6, 7 and 8). Moreover, this mesoderm develops into testis or ovary even without any innitial germ cells.

     

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.     

Pole Cell Migration through the Gut Wall of the Drosophila Embryo: Analysis of Cell Interactions

Early in development the precursors of germ cells in Drosophila migrate at the posterior pole of the embryo and translocate to the bottom of the developing posterior midgut primordium. At the end of germ band elongation the pole cells cross the gut wall to enter in association with the gonadal mesoderm. We used laser scanning confocal microscopy on whole-mount Rh-phalloidin-stained embryos and transmission electron microscopy to investigate how pole cells cross the epithelial wall of the posterior midgut primordium. Our results suggest that pole cells leave the midgut sac by traveling through the intercellular spaces of the epithelium. During this process the epithelial cells at the bottom of the posterior midgut primordium are greatly deformed, but their junctional complexes do not completely release, avoiding breaks in the epithelial wall.     

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.     

Maternal Pumilio acts together with Nanos in germline development in Drosophila embryos

The maternal RNA-binding proteins Pumilio (Pum) and Nanos (Nos) act together to specify the abdomen in Drosophila embryos. Both proteins later accumulate in pole cells, the germline progenitors. Nos is required for pole cells to differentiate into functional germline. Here we show that Pum is also essential for germline development in embryos. First, a mutation in pum causes a defect in pole-cell migration into the gonads. Second, in such pole cells, the expression of a germline-specific marker (PZ198) is initiated prematurely. Finally, pum mutation causes premature mitosis in the migrating pole cells. We show that Pum inhibits pole-cell division by repressing translation of cyclin B messenger RNA. As these phenotypes are indistinguishable from those produced by nos mutation, we conclude that Pum acts together with Nos to regulate these germline-specific events.     

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.     

Developmental analysis of the grandchildless (gs(1)N26) mutation in Drosophila melanogaster: abnormal cleavage patterns and defects in pole cell formation

This article describes developmental analysis of gs(1)N26 mutation. gs(1)N26 is a temperature-sensitive maternal-effect mutation affecting the formation of the germ line (Y. Niki and M. Okada, Wilhelm Roux's Arch. Dev. Biol. 190, 1-10, 1981). At 25 degrees C, the cleavage nuclei do not divide synchronously and show various degrees of retarded migration to the posterior region. Blastoderm nuclei show antero-posterior mitotic waves; posterior yolk nuclei also are reduced in number at this stage. Pole cells form only when the cleavage nuclei migrate directly to the posterior pole. In fact, the posterior region of young eggs presents the usual ultrastructural features, and it is also able to participate in the formation of pole cells, as was proven by cytoplasmic transfer experiments. Therefore the defects in blastogenesis, in particular in the formation of pole cells of gs(1)N26 embryos, appear to result from the delayed migration of cleavage nuclei to the posterior pole.     

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.     

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.     

The isolation of functional pole cells from theDrosophila melanogaster maternal effect mutantmat(3)1

Summary A procedure for pole cell isolation has been developed that takes advantage of theDrosophila melanogaster maternal effect mutantmat(3) 1. Embryos derived from homozygousmat(3)1 mothers form exclusively pole cells. By outcrossing we could substantially increase the expressivity of the original mutant stock. We further introduced theTM8 balancer chromosome, which carries the dominant temperature sensitive mutationDTS-4. This allows the accumulation of large homozygousmat(3) 1 fly populations by eliminating the heterozygous flies at the restrictive temperature.Early embryos were mechanically fragmented and the cells were isolated by means of metrizamide step gradients. The isolated cells were demonstrated to exhibit the various ultrastructural and histochemical characteristics of pole cells. The isolated cells were transplanted into genetically marked host embryos. The germ line mosaics that were obtained indicate that the isolated cells represent functional pole cells.Proteins synthesized by the isolated pole cells during short term in vitro labelling with³⁵S-methionine were compared to the proteins synthesized by blastoderm cells fromOregon-R embryos. At least one protein could be demonstrated in the pole cell samples that is not synthesized byOregon-R blastoderm cells.The method allows a fast and gentle isolation of highly enriched pole cell populations which are a prerequisite for the biochemical analysis of germ cell determination and differentiation.     

Mitochondrial small ribosomal RNA is present on polar granules in early cleavage embryos of Drosophila melanogaster

In Drosophila, formation of the germline progenitors, the pole cells, is induced by polar plasm localized in the posterior pole region of early embryos. The polar plasm contains polar granules, which act as a repository for the factors required for pole cell formation. It has been postulated that the factors are stored as mRNA and are later translated on polysomes attached to the surface of polar granules. Here, the identification of mitochondrial small ribosomal RNA (mtsrRNA) as a new component of polar granules is described. The mtsrRNA was enriched in the polar plasm of the embryos immediately after oviposition and remained in the polar plasm throughout the cleavage stage until pole cell formation. In situ hybridization at an ultrastructural level revealed that mtsrRNA was enriched on the surface of polar granules in cleavage embryos. Furthermore, the localization of mtsrRNA in the polar plasm depended on the normal function of oskar, vasa and tudor genes, which are all required for pole cell formation. The temporal and spatial distribution of mtsrRNA is essentially identical to that of mitochondrial large ribosomal RNA (mtlrRNA), which has been shown to be required for pole cell formation. Taken together, it is speculated that mtsrRNA and mtlrRNA are part of the translation machinery localized to polar granules, which is essential for pole cell formation.     

Three distinct distributions of F-actin occur during the divisions of polar surface caps to produce pole cells in Drosophila embryos

The F-actin distribution was studied during pole cell formation in Drosophila embryos using the phalloidin derivative rhodaminyl-lysine-phallotoxin. Nuclei were also stained with 4'-6 diamidine-2-phenylindole dihydrochloride to correlate the pattern seen with the nuclear cycle. The precursors of the pole cells, the polar surface caps, were found to have an F-actin-rich cortex distinct from that of the rest of the embryo surface and an interior cytoplasm that was less intensely stained but brighter than the cytoplasm deeper in the embryo. They were found to divide once without forming true cells and then a second time when cells formed as a result of a meridional and a basal cleavage. Three distinct distributions of the cortical F-actin have been identified during these cleavages. It is concluded that the first division, which cleaves the polar caps but does not separate them from the embryo, involves very different processes from those that lead to the formation of the pole cells. A contractile-ring type of F-actin organization may not be present during the first cleavage but is suggested to occur during the second.     

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.     

Effects of All-trans retinoic acid on germ cell development of embryos and larvae of the giant freshwater prawn, Macrobrachium rosenbergii

Embryos of the giant freshwater prawn, Macrobrachium rosenbergii, were treated with 1, 10 or 50 μg ml⁻¹ all-trans retinoic acid (AtRA) for 2 days. Survival and hatching rates were not affected. However, an increase in the number of primordial germ cells (PGCs), progenitors of gametes, and a slightly more advanced stage of the gonads were found in those treated with 10 or 50 μg ml⁻¹ AtRA. Newly hatched larvae were treated with 0.1, 0.5 or 1 μg ml⁻¹ AtRA for 2 days. Survival rates were lower in those treated with 0.5 or 1 μg ml⁻¹ AtRA; nevertheless, the gonads were slightly more developed. The results indicated that AtRA, an active metabolite of vitamin A, affected germ cell and gonad development of embryos and the larvae of giant freshwater prawn.     

Vegetal pole cells and commitment to form endoderm in Xenopus laevis

In order to compare their states of commitment with their normal developmental fate, single vegetal pole cells from early Xenopus embryos were labeled and transplanted into the blastocoels of host embryos. In a previous study we showed, using this single cell transplantation assay, that vegetal pole cells become committed to endoderm by the early gastrula stage. In this paper we examine some properties of the commitment process. First, we show that it is gradual. When vegetal blastomeres are taken from progressively older embryos an increasing number of them enter only the endoderm, until by the early gastrula stage they all do. Second, we show that commitment can continue in vitro when an appropriate tissue mass is present. We suggest that commitment to form endoderm may be, in the right conditions, a cell autonomous process.     

Genetic and developmental evidence for a repressed genital primordium in Drosophila melanogaster

Agametic, a maternal-effect mutation, causes the absence of germ cells in approximately 40% of the gonads of flies derived from homozygous females. The nature of the deficiency in the eggs produced by these flies was examined. Ultrastructural abnormalities were seen in the polar granules of some eggs shortly after fertilization. Although a normal number of pole cells form, some are abnormal with degenerating polar granules and nuclear bodies and they contain myeloid bodies. The pole cells reach the gonads and at 14 hr of development all the gonads contain germ cells. However, in 40% of the gonads the germ cells become necrotic and disappear. Thus, the source of agametic gonads in the adult is embryonic death of pole cells in some gonads. To test whether this gonadal death is an autonomous deficiency of the mutant pole cells, mosaic pole cell populations were produced by reciprocal pole cell transplantation. In both types of transplants, the mutant pole cells died autonomously. In eight instances gonads containing only donor pole cells were obtained. Since mutant pole cells die when wild-type pole cells normally begin dividing, we suggest that the lesion affects the ability of these mutant pole cells to reenter the cell cycle.