Project description:In mouse embryos at mid-gestation, primordial germ cells (PGCs) undergo licensing to become gametogenesis-competent cells (GCCs), gaining the capacity for meiotic initiation and sexual differentiation. GCCs then initiate either oogenesis or spermatogenesis in response to gonadal cues. Germ cell licensing has been considered to be a cell-autonomous and gonad-independent event, based on observations that some PGCs, having migrated not to the gonad but to the adrenal gland, nonetheless enter meiosis in a time frame parallel to ovarian germ cells -- and do so regardless of the sex of the embryo. Here we test the hypothesis that germ cell licensing is cell-autonomous by examining the fate of PGCs in Gata4 conditional mutant (Gata4 cKO) mouse embryos. Gata4, which is expressed only in somatic cells, is known to be required for genital ridge initiation. PGCs in Gata4 cKO mutants migrated to the area where the genital ridge, the precursor of the gonad, would ordinarily be formed. However, these germ cells did not undergo licensing and instead retained characteristics of PGCs. Our results indicate that licensing is not purely cell-autonomous but is induced by the somatic genital ridge.

Project description:This SuperSeries is composed of the SubSeries listed below.

Project description:The scarcity of primordial germ cells (PGCs) in the developing mammalian embryo hampers robust biochemical analysis of the processes that underlie early germ cell formation. Here, we demonstrate that DAZL, a germ cell-specific RNA binding protein, is a robust PGC marker during in vitro germ cell development. Using Dazl-GFP reporter ESCs, we demonstrate that DAZL plays a central role in a large mRNA/protein interactive network that blocks the translation of core pluripotency factors, including Sox2 and Sall4, as well as of Suz12, a polycomb family member required for differentiation of pluripotent cells. Thus, DAZL limits both pluripotency and somatic differentiation in nascent PGCs. In addition, we observed that DAZL associates with mRNAs of key Caspases and similarly inhibits their translation. This elegant fail-safe mechanism ensures that, whereas loss of DAZL results in prolonged expression of pluripotency factors, teratoma formation is avoided due to the concomitant activation of the apoptotic cascade.

Project description:In mouse embryos, sex-specific differentiation of primordial germ cells (PGCs) begins with distinct cell cycle regulations: while PGCs in female (XX) gonads enter meiosis, PGCs in male (XY) gonads defer meiosis and arrest cell cycle1,2. The mitotic quiescence in XY gonads requires Nanos2, an evolutionarily conserved RNA-binding protein implicated in RNA degradation3-5; however, underlying mechanisms including the identity of its target mRNAs in vivo remain unknown. Here we show that Nanos2 negatively regulates Dazl (Deleted in azoospermia-like), a germline-specific gene encoding an RNA-binding protein that is implicated in translational control and meiotic initiation6,7. Comprehensive microarray analyses identified Dazl as one of the genes that were up-regulated in Nanos2-deficient XY gonads, but down-regulated in Nanos2-expressing XX gonads. Analysis of a BAC transgenic mouse line, in which the 3’UTR of Dazl can be removed by Flp-Frt recombination system, showed that repression of Dazl is likely achieved by the association of Nanos2 with Dazl’s 3’UTR. Elevated levels of Dazl expression in the transgenic XY PGCs resulted in abnormal progression of cell cycles including meiosis, reminiscent of the phenotype observed in Nanos2-/- XY gonads. This phenotype was suppressed by inhibiting retinoic acid (RA) signaling, suggesting that Nanos2 represses Dazl to prevent RA-induced cell cycle progression in XY PGCs. Furthermore, we show that a part of Nanos2-associated mRNAs, most of which are up-regulated in Nanos2-/- XY gonads, can also associate with Dazl, and that excess Dazl impedes localization of Nanos2 to processing-bodies where RNA degradation takes place, suggesting that repression of Dazl is required for Nanos2 to efficiently degrade its target mRNAs. These data provide the first link between the two RNA-binding proteins that play pivotal roles in sexual differentiation of murine PGCs.

Project description:In mouse embryos, sex-specific differentiation of primordial germ cells (PGCs) begins with distinct cell cycle regulations: while PGCs in female (XX) gonads enter meiosis, PGCs in male (XY) gonads defer meiosis and arrest cell cycle1,2. The mitotic quiescence in XY gonads requires Nanos2, an evolutionarily conserved RNA-binding protein implicated in RNA degradation3-5; however, underlying mechanisms including the identity of its target mRNAs in vivo remain unknown. Here we show that Nanos2 negatively regulates Dazl (Deleted in azoospermia-like), a germline-specific gene encoding an RNA-binding protein that is implicated in translational control and meiotic initiation6,7. Comprehensive microarray analyses identified Dazl as one of the genes that were up-regulated in Nanos2-deficient XY gonads, but down-regulated in Nanos2-expressing XX gonads. Analysis of a BAC transgenic mouse line, in which the 3’UTR of Dazl can be removed by Flp-Frt recombination system, showed that repression of Dazl is likely achieved by the association of Nanos2 with Dazl’s 3’UTR. Elevated levels of Dazl expression in the transgenic XY PGCs resulted in abnormal progression of cell cycles including meiosis, reminiscent of the phenotype observed in Nanos2-/- XY gonads. This phenotype was suppressed by inhibiting retinoic acid (RA) signaling, suggesting that Nanos2 represses Dazl to prevent RA-induced cell cycle progression in XY PGCs. Furthermore, we show that a part of Nanos2-associated mRNAs, most of which are up-regulated in Nanos2-/- XY gonads, can also associate with Dazl, and that excess Dazl impedes localization of Nanos2 to processing-bodies where RNA degradation takes place, suggesting that repression of Dazl is required for Nanos2 to efficiently degrade its target mRNAs. These data provide the first link between the two RNA-binding proteins that play pivotal roles in sexual differentiation of murine PGCs.

Project description:BackgroundMammalian gonadal development is crucial for fertility. Sexual differentiation, meiosis and gametogenesis are critical events in the process of gonadal development. Abnormalities in any of these events may cause infertility. However, owing to the complexity of these developmental events, the underlying molecular mechanisms are not fully understood and require further research.ResultsIn this study, we employed RNA sequencing to examine transcriptome profiles of murine female and male gonads at crucial stages of these developmental events. By bioinformatics analysis, we identified a group of candidate genes that may participate in sexual differentiation, including Erbb3, Erbb4, and Prkg2. One hundred and two and 134 candidate genes that may be important for female and male gonadal development, respectively, were screened by analyzing the global gene expression patterns of developing female and male gonads. Weighted gene co-expression network analysis was performed on developing female gonads, and we identified a gene co-expression module related to meiosis. By alternative splicing analysis, we found that cassette-type exon and alternative start sites were the main forms of alternative splicing in developing gonads. A considerable portion of differentially expressed and alternatively spliced genes were involved in meiosis.ConclusionTaken together, our findings have enriched the gonadal transcriptome database and provided novel candidate genes and avenues to research the molecular mechanisms of sexual differentiation, meiosis, and gametogenesis.Supplementary informationSupplementary information accompanies this paper at 10.1186/s12575-019-0108-y.

Project description:Evolutionally conserved Nanos RNA-binding proteins play crucial roles in germ cell development. While a mammalian Nanos family protein, NANOS2, is required for sexual differentiation of male (XY) germ cells in mice, the underlying mechanisms and the identities of its target RNAs in vivo remain elusive. Using comprehensive microarray analysis and a bacterial artificial chromosome transgenic system, here we identify Dazl, a germ cell-specific gene encoding an RNA-binding protein implicated in translation, as a crucial target of NANOS2. Importantly, removal of the Dazl 3'-untranslated region in XY germ cells stabilizes the Dazl mRNA, resulting in elevated meiotic gene expression, abnormal resumption of the cell cycle and impaired processing-body formation, reminiscent of Nanos2-knockout phenotypes. Furthermore, our data suggest that NANOS2 acts as an antagonist of the DAZL protein. We propose a dual system of NANOS2-mediated suppression of Dazl expression as a pivotal molecular mechanism promoting sexual differentiation of XY germ cells.

Project description:Our understanding of human germ cell development is limited in large part due to inaccessibility of early human development to molecular genetic analysis. Pluripotent human embryonic stem cells (hESCs) and induced pluripotent stem cells (iPSCs) have been shown to differentiate to cells of all three embryonic germ layers, as well as germ cells in vitro, and thus may provide a model for the study of the genetics and epigenetics of human germline. Here, we examined whether intrinsic germ cell translational, rather than transcriptional, factors might drive germline formation and/or differentiation from human pluripotent stem cells in vitro. We observed that, with overexpression of VASA (DDX4) and/or DAZL (Deleted in Azoospermia Like), both hESCs and iPSCs differentiated to primordial germ cells, and maturation and progression through meiosis was enhanced. These results demonstrate that evolutionarily unrelated and divergent RNA-binding proteins can promote meiotic progression of human-derived germ cells in vitro. These studies describe an in vitro model for exploring specifics of human meiosis, a process that is remarkably susceptible to errors that lead to different infertility-related diseases.

Project description:Germ cell sexual differentiation requires Nanos2-mediated repression of Dazl in mice

Project description:BackgroundGerm cells arise from a small group of cells that express markers of pluripotency including OCT4. In humans formation of gonadal compartments (cords in testis, nests in ovary) takes place during the 1st trimester (6-8 weeks gestation). In the 2nd trimester germ cells can enter meiotic prophase in females whereas in males this does not occur until puberty. We have used qRTPCR, Westerns and immunohistochemical profiling to determine which of the germ cell subtypes in the human fetal gonads express OCT4, DAZL and VASA, as these have been shown to play an essential role in germ cell maturation in mice.ResultsOCT4 mRNA and protein were detected in extracts from both 1st and 2nd trimester ovaries and testes. In ovarian extracts a marked increase in expression of VASA and DAZL mRNA and protein occurred in the 2nd trimester. In testicular extracts VASA mRNA and protein were low/undetectable in 1st trimester and increased in the 2nd trimester whereas the total amount of DAZL did not seem to change. During the 1st trimester, germ cells were OCT4 positive but did not express VASA. These results are in contrast to the situation in mice where expression of Vasa is initiated in Oct4 positive primordial germ cells as they enter the gonadal ridge. In the 2nd trimester germ cells with intense cytoplasmic staining for VASA were present in both sexes; these cells were OCT4 negative. DAZL expression overlapped with both OCT4 and VASA and changed from the nuclear to the cytoplasmic compartment as cells became OCT4-negative. In males, OCT4-positive and VASA-positive subpopulations of germ cells coexisted within the same seminiferous cords but in the ovary there was a distinct spatial distribution of cells with OCT4 expressed by smaller, peripherally located, germ cells whereas DAZL and VASA were immunolocalised to larger (more mature) centrally located cells.ConclusionOCT4, DAZL and VASA are expressed by human fetal germ cells but their patterns of expression are temporally and spatially distinct. In the 1st trimester OCT4 was detected in most germ cells. In the 2nd trimester the onset of expression of VASA was associated with the formation of oocytes and spermatogonia both of which were OCT-4 negative. Relocation of DAZL from nucleus to cytoplasm paralleled the down regulation of OCT4 and the onset of expression of VASA. These data reveal similarities between the expression of key regulatory proteins within germ cells as they mature in male and female fetal human gonads suggesting that in the female these maturational changes are not determined by entry into meiosis.