Maternal Messenger RNA as a Determinant of Pole Cell Formation in Drosophila Embryos

Some polar plasm components are UV-sensitive. Messenger RNA extracted from oocytes or cleavage embryos can to induce pole cells in embryos that have been deprived of ability to form pole cells by UV-irradiation. This article reviews studies on the role of this mRNA in the developmental pathway leading to germ cell formation.     

Delocalization of polar plasm components caused by grandchildless mutations, gs(1)N26 and gs(1)N441, in Drosophila melanogaster

Two maternal-effect grandchildless (gs) mutations of Drosophila melanogaster, gs(1)N26 and gs(1)N441, cause delay in nuclear arrival at the polar plasm. In mutant embryos, polar plasm loses its ability to induce pole cells during retarded nuclear migration to the posterior pole of embryos. In the present study, it was shown that in N26 and N441 embryos, mitochondrial large rRNA (mtlrRNA), an essential factor for pole cell formation, is delocalized during the delay in nuclear arrival. This suggests that the loss of mtlrRNA causes failure of the mutants to form pole cells. Furthermore, it was shown that all of the other polar plasm components examined, namely Vasa protein, Germ cell-less protein, nanos mRNA and Polar granule component RNA start to be delocalized during the delay in nuclear arrival. This suggests that polar plasm integrity is not maintained in mutant embryos. It was finally shown that Vas is also delocalized in embryos that are inhibited to form pole cells by reducing the amount of mtlrRNA. This indicates that the segregation of polar plasm into pole cells is required to maintain polar plasm integrity. The mechanism regulating polar plasm integrity in embryos is discussed.     

Differences in Fine Structures between Normal and RNA-induced Drosophila Pole Cells

Fine structures were compared between normal pole cells and those induced in embryos that had been uv-irradiated and then injected with intact polar plasm or with poly(A)⁺RNA extracted from cleavage embryos. Nuclei in nomal pole cells were spherical. In contrast, those in the induced pole cells were deformed to variable extents depending on materials injected with. Polar granules were smaller in pole cells induced by injection of poly(A)⁺RNA than in normal pole cells. The size of polar granules in polar-plasm-induced pole cells was intermediate between those in poly(A)⁺RNA-induced and normal pole cells. Small polar granules were observed in posterior cells of embryos uv-irradiated, nevertheless those cells were columnar and with identical morphology to somatic cells. Nuclear bodies showed a similar tendency in size differences as observed in polar granules in three types of pole cells observed.     

Isolation of a factor inducing pole cell formation from Drosophila embryos

Summary

An attempt to isolate an ooplasmic factor active in inducing pole cells in Drosophila embryos is described. With the help of a bioassay system, we demonstrated that RNA extracted from embryos was active in inducing pole cells. These RNA-induced pole cells were morphologically identical to the normal ones. In addition, a local application of cycloheximide suggests that translation in the posterior pole cytoplasm is a precondition for pole cell formation.     

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.     

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.     

Altered expression of spatially regulated embryonic genes in the progeny of separated sea urchin blastomeres

We have examined the importance of the extracellular environment on the ability of separated cells of sea urchin embryos (Strongylocentrotus purpuratus) to carry out patterns of mRNA accumulation and decay characteristic of intact embryos. Embryos were dissociated into individual blastomeres at 16-cell stage and maintained in calcium-free sea water so that daughter cells continuously separated. Levels of eleven different mRNAs in these cells were compared to those in control embryos when the latter reached mesenchyme blastula stage, by which time cells in major regions of the intact embryo have assumed distinctive patterns of message accumulation. Abrogation of interactions among cells resulted in marked differences in accumulation and/or turnover of the individual mRNAs, which are expressed with diverse temporal and spatial patterns of prevalence in intact embryos. In general, separated cells are competent to execute initial events of mRNA accumulation and decay that occur uniformly in most or all blastomeres of the intact embryo and are likely to be regulated by maternal molecules. The ability of separated cells to accumulate mRNAs that appear slightly later in development depends upon the presumptive tissue in which a given mRNA is found in the normal embryo. Messages that normally accumulate in cells at the vegetal pole also accumulate in dissociated cells either at nearly normal levels or at increased levels. In one such case, that of actin CyIIa, which is normally restricted to mesenchyme cells, in situ hybridization demonstrates that the fraction of dissociated cells expressing this message is 4- to 5-fold higher than in the normal embryo. In contrast, separated cells accumulate significant levels of a message expressed uniformly in the early ectoderm but are unable to execute accumulation and decay of different messages that distinguish oral and aboral ectodermal regions. These data are consistent with the idea that interactions among cells in the intact embryo are important for both positive and negative control of expression of different genes that are early indicators of the specification of cell fate.     

Spatial and developmental changes in the respiratory activity of mitochondria in early Drosophila embryos.

Mitochondria of early Drosophila embryos were observed with a transmission electron microscope and a fluorescent microscope after vital staining with rhodamine 123, which accumulates only in active mitochondria. Rhodamine 123 accumulated particularly in the posterior pole region in early cleavage embryos, whereas the spatial distribution of mitochondria in an embryo was uniform throughout cleavage stages. In late cleavage stages, the dye showed very weak and uniform accumulation in all regions of periplasm. Polar plasm, sequestered in pole cells, restored the ability to accumulate the dye. Therefore, it is concluded that the respiratory activity of mitochondria is higher in the polar plasm than in the other regions of periplasm in early embryos, and this changes during development. The temporal changes in rhodamine 123-staining of polar plasm were not affected by u.v. irradiation at the posterior of early cleavage embryos at a sufficient dosage to prevent pole cell formation. This suggests that the inhibition of pole cell formation by u.v. irradiation is not due to the inactivation of the respiratory activities of mitochondria. In addition, we found that the anterior of Bicaudal-D mutant embryos at cleavage stage was stained with rhodamine 123 with the same intensity as the posterior of wild-type embryos. No pole cells form in the anterior of Bic-D embryos, where no restoration of mitochondrial activity occurs in the blastoderm stage. The posterior group mutations that we tested (staufen, oskar, tudor, nanos) and the terminal mutation (torso) did not alter staining pattern of the posterior with rhodamine 123.     

Cellular polarity in cultured animal pole cells of Xenopus embryos

The expression of intracellular and surface polarity in cultured animal pole cells of Xenopus embryos (stages 6, 8, and 10) was examined morphologically and immunocytochemically. When control embryos reached stage 23, daughter cells derived from a single or a few animal pole cells formed aggregates. Outer cells of the aggregates displayed intracellular and surface polarity and expressed an epidermis-specific antigen (XEPI-1) on the apical surface circumference, while these characteristics had not yet been established in the animal pole cells at the time of isolation. However, inner cells of the aggregates did not display the cellular polarity along an outer-inner axis of the aggregates and displayed the antigen randomly within the aggregates. These results indicate that the expression of cellular polarity in epidermal differentiation of Xenopus embryos in vitro depends on the position within the aggregates formed by daughter cells derived from isolated animal pole cells.     

Identification of bovine and novel interferon-tau alleles in the American plains bison (Bison bison) by analysis of hybrid cattle x bison blastocysts

The objective of this study was to generate bison x cattle hybrid embryos by in vitro fertilization, to assess their developmental potential, to determine the pattern of secretion of the embryonic signaling molecule interferon-tau (IFN-tau), and to identify novel IFN-tau mRNA polymorphism in the American plains bison. A total of 600 bovine oocytes were inseminated with frozen-thawed bison semen. Of these, 40.7% cleaved and 14.8% proceeded to the blastocyst stage. Individual blastocysts were cultured on a basement membrane (Matrigel) and their ability to attach and form outgrowths was monitored. A total of 36 blastocysts were cultured of which 22 formed outgrowths. During individual culture, medium samples were collected and their IFN-tau concentration was measured. On day 6 after onset of individual culture, attached outgrowths produced significantly more IFN-tau than unattached viable or degenerate blastocysts. At this time, female conceptuses also produced significantly more IFN-tau than their male cohorts. However, by day 12 this difference had disappeared. Total mRNA was extracted from three individual outgrowths and analyzed by RT-PCR. Subsequent sequencing of 28 clones showed several known bovine IFN-tau sequences as well as two novel sequences termed bisIFN-tau1 and 2. To determine the origin of these, DNA was extracted from bison semen and analyzed by PCR. One bovine IFN-tau sequence (bovIFN-tau1d) as well as bisIFN-tau2 and a third novel sequence bisIFN-tau3 were detected. This study demonstrates the feasibility of using hybrid embryos for the analysis of developmentally regulated gene expression in species where embryos may not be available.     

Developmental analysis of grandchildless (gs(1)N441) mutation in Drosophila melanogaster; abnormal formation of pole cells

A detailed examination of the developmental features of abnormal formation of pole cells and a functional analysis of the germ plasma of gs(1)N441 embryos were carried out. The germ plasma is morphologically normal. Embryos in which cleavage nuclei show retarded migration to the posterior pole do not form pole cells. Pole cells, following formation, are abnormally segregated and then intermingled between the blastoderm cell layer but retaining normal morphology and differentiating into functional germ cells. The results of cytoplasmic transplantation experiments indicate the autonomous segregation ability of the mutant polar plasma to form pole cells to possibly be affected.     

Localization of Actin mRNA during the Establishment of Cell Polarity and Early Cell Divisions in Fucus Embryos

Localization of mRNA is a well-described mechanism to account for the asymmetric distribution of proteins in polarized somatic cells and embryos of animals. In zygotes of the brown alga Fucus, F-actin is localized at the site of polar growth and accumulates at the cell plates of the first two divisions of the embryo. We used a nonradioactive, whole-mount in situ hybridization protocol to show the pattern of actin mRNA localization. Until the first cell division, the pattern of actin mRNA localization is identical to that of total poly(A)+ RNA, that is, a symmetrical distribution in the zygote followed by an actin-dependent accumulation at the thallus pole at the time of polar axis fixation. At the end of the first division, actin mRNA specifically is redistributed from the thallus pole to the cell plates of the first two divisions in the rhizoid. This specific pattern of localization in the zygote and embryo involves the redistribution of previously synthesized actin mRNA. The initial asymmetry of actin mRNA at the thallus pole of the zygote requires polar axis fixation and microfilaments but not microtubules, cell division, or polar growth. However, redistribution of actin mRNA from the thallus pole to the first cell plate is insensitive to cytoskeletal inhibitors but is dependent on cell plate formation. The F-actin that accumulates at the rhizoid tip is not accompanied by the localization of actin mRNA. However, maintenance of an accumulation of actin protein at the cell plates of the rhizoid could be explained, at least partially, by a mechanism involving localization of actin mRNA at these sites. The pattern and requirements for actin mRNA localization in the Fucus embryo may be relevant to polarization of the embryo and asymmetric cell divisions in higher plants as well as in other tip-growing plant cells.     

Expression of the zygotic genome in blastoderm stage embryos ofDrosophila: Analysis of a specific protein

Summary The synthesis of a protein which has been detected in blastoderm cells but not in pole cells (Gutzeit and Gehring 1979) has been studied further by means of two-dimensional gel electrophoresis. This protein could not be detected at the nuclear multiplication stage. The protein is translated from mRNA which is transcribed at the blastoderm stage since it is not synthesized in detectable amounts when embryos are injected with -amanitin prior to the blastoderm stage. Also the protein could not be detected when RNA from freshly laid eggs was translated in vitro. Embryos from females which are homozygous for the mutationmat (3) 1 form pole cells but no blastoderm cells (Rice and Garen 1975). Thesemat (3) 1 embryos, as we will call them in this report, express the protein if aged for a period of time sufficient for completion of blastoderm cell formation in control wild-type embryos.mat (3) 1 embryos and embryos injected with -amanitin show the same syndrome of visible developmental anomalies; however, the studied protein could only be detected inmat (3) 1 embryos but not in -amanitin injected embryos.Supported by the DFG, SFB 46     

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 Nanos and Pumilio regulate zygotic vasa expression autonomously in the germ-line progenitors of Drosophila melanogaster embryos

vasa (vas) is transcribed earliest among reported genes expressed in the germ-line progenitors, or pole cells, in Drosophila melanogaster embryos. Its expression is detected in the germ-line cells throughout their development, making vas expression a useful marker for the establishment of germ-line fate. In the present report, it is shown that maternal Nos and Pum are required for normal expression of vas in pole cells. First, expression of enhancer-trap marker BC69, which reflects vas expression, is promoted by maternal Nos and Pum. Second, expression of vas mRNA in pole cells is promoted by maternal Nos and Pum. Third, pole cell transplantation experiments reveal that maternal Nos and Pum are required autonomously in pole cells for proper expression of vas. Finally, Nos and Pum are dispensable for vas expression in oogenesis, although they are expressed zygotically in adult ovaries. These observations show that germ-line-specific vas expression is promoted by autonomous function of maternal Nos and Pum in the germ-line progenitors during embryogenesis, and is regulated differentially in embryogenesis and oogenesis.     

An Attempt to Hybridize Drosophila Species Using Pole Cell Transplantation

We have made hybrid embryos in Drosophila by pole cell transplants, by transfering pole cells from two species, D. rajasekari and D. eugracilis, into sterile D. melanogaster hosts. These females were then mated to melanogaster males and the older these females were, the further their hybrid offspring developed. In the case of the rajasekari/melanogaster hybrids, the embryos form cuticle but had defective heads, while the eugracilis/melanogaster hatched as larvae that grew but did not moult to the second instar. Hybrid pole cells could be transferred to melanogaster hosts but they failed to make eggs.     

Lineage analysis of transplanted individual cells in embryos of Drosophila melanogaster

Summary In this paper experiments concerning some aspects of the development of pole cells and midgut progenitors in Drosophila are reported. Cells were labelled by injecting horseradish-peroxidase (HRP) in embryos before pole bud formation and transplanted at different stages into unlabelled embryos, where the transplanted cells developed together with the unlabelled cells of the host. The hosts were then fixed and stained at different ages in order to demonstrate the presence of HRP in the progenies of transplanted cells. The main conlusions of the study are as follows. The gonads are the only organ to the formation of which pole cells normally contribute; those pole cells which do not participate in the formation of the gonads are finally eliminated or degenerate. Since the number of primordial germ cells in the gonads is the same irrespective of the number of pole cells present in the embryo, an (unknown) mechanism must exist regulating the final number of pole cells in each of the gonads. After their formation and before reaching the gonads, pole cells have been found to divide only up to two times. With respect to the midgut progenitors, the cells of both anlagen have been found to be committed to develop into midgut, although they behave as equivalent in that they do not apparently distinguish between the anterior and posterior anlage. Midgut progenitors have been found to divide a maximum of three times and to produce two different types of cells, epithelial cells of the midgut wall and spindle-like cells located internally in the gut.     

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.

     

Studies on the expression of intracellular and surface polarity in animal pole cells of Xenopus embryos cultured on various substrata

The expression of intracellular and surface polarity in animal pole cells of Xenopus embryos (stage 10) cultured on various substrata was studied by electron microscopy. When animal pole cells of Xenopus embryos were cultured on type I collagen- or gelatin-coated dishes until control embryos reached stage 23, the cells in confluent layers expressed an apical-basal polarity so that the apical surface membrane domain faced the culture medium. However, the cells in confluent layers cultured on naked plastic dishes were suppressed to express intracellular and surface polarity. In addition, single attached cells which were formed by being sparsely plated neither spread on any substrata nor displayed the apical-basal polarity perpendicular to the dishes. These results indicate that the expression of intracellular and surface polarity in cultured animal pole cells of Xenopus embryos requires not only cell-cell contact but also an adhesive substrata such as type I collagen or gelatin.