Project description:Reconstitution of female germ-cell development in vitro is a key challenge in reproductive biology and medicine. We show here that female (XX) embryonic stem cells (ESCs) and induced pluripotent stem cells (iPSCs) in mice are induced into primordial germ cell-like cells (PGCLCs), which, when aggregated with female gonadal somatic cells as reconstituted ovaries, develop pre-meiotic germ cell characteristics, including X-reactivation, imprint erasure, and cyst formation. Upon transplantation under ovarian bursa, PGCLCs in the reconstituted ovaries mature into germinal vesicle-stage oocytes, which, through in vitro maturation and fertilization, contribute to fertile offspring. Our culture system serves as a robust foundation for the investigation of key properties of female germ cells, including the acquisition of totipotency, and for the reconstitution of whole female germ-cell development in vitro. We performed expression analysis of female PGC-like cells [PGCLCs; day 3 (d3), day 6 (d6), and day 3 followed by day 6 in aggregation with female embryonic day (E) 12.5 gonadal somatic cells (d3ag6)] in comparison to in vivo embryonic PGCs (E12.5 female PGCs and E9.5 PGCs) and male d6 PGCLCs. PGCLCs were marked with fluorescence of Blimp1-mVenus, stella-ECFP transgenic reporters (BVSC). PGCs were marked with fluorescence of the stella-EGFP transgenic reporter.

Project description:Genome-wide DNA demethylation, including the erasure of genome imprints, in primordial germ cells (PGCs), is critical as a first step for creating the totipotent epigenome in the germ line. Here, we provide evidence that contrary to the prevailing model involving active DNA demethylation, imprint erasure in mouse PGCs occurs in a manner consistent with replication-coupled passive DNA demethylation: PGCs erase imprints during their rapid proliferation with little de novo as well as maintenance DNA methylation potential and no major chromatin alterations. Our findings necessitate the re-evaluation of and provide novel insights into the mechanism of genome-wide DNA demethylation in PGCs.

Project description:Epigenetic reprogramming including demethylation of DNA occurs in mammalian primordial germ cells (PGCs) and in early embryos, and is important for the erasure of imprints and epimutations, and the return to pluripotency. The extent of this reprogramming and its molecular mechanisms are poorly understood. We previously showed that the cytidine deaminases Aid and Apobec1 can deaminate 5-methylcytosine in vitro and in E coli, and in the mouse are expressed in tissues in which demethylation occurs. Here we profiled DNA methylation throughout the genome by unbiased bisulfite Next Generation Sequencing (BS-Seq) in wildtype and Aid deficient PGCs at E13.5. Wildtype PGCs revealed dramatic genome-wide erasure of methylation to a level below that of methylation deficient (Np95-/-) ES cells, with female PGCs being less methylated than male ones. By contrast, Aid deficient PGCs were up to three times more methylated than wildtype ones; this substantial difference occurred throughout the genome, with introns, intergenic regions and transposons being relatively more methylated than exons. Relative hypermethylation in Aid deficient PGCs was confirmed by analysis of individual loci in the genome. Our results reveal that erasure of DNA methylation in the germ line is a global process, hence limiting the potential for transgenerational epigenetic inheritance. Aid deficiency interferes with genome-wide erasure of DNA methylation patterns, suggesting that Aid has a critical function in epigenetic reprogramming and potentially in restricting the inheritance of epimutations in mammals. Comparison of methylation in wild-type and Aid deficient mouse tissues

Project description:Epigenetic reprogramming including demethylation of DNA occurs in mammalian primordial germ cells (PGCs) and in early embryos, and is important for the erasure of imprints and epimutations, and the return to pluripotency. The extent of this reprogramming and its molecular mechanisms are poorly understood. We previously showed that the cytidine deaminases Aid and Apobec1 can deaminate 5-methylcytosine in vitro and in E coli, and in the mouse are expressed in tissues in which demethylation occurs. Here we profiled DNA methylation throughout the genome by unbiased bisulfite Next Generation Sequencing (BS-Seq) in wildtype and Aid deficient PGCs at E13.5. Wildtype PGCs revealed dramatic genome-wide erasure of methylation to a level below that of methylation deficient (Np95-/-) ES cells, with female PGCs being less methylated than male ones. By contrast, Aid deficient PGCs were up to three times more methylated than wildtype ones; this substantial difference occurred throughout the genome, with introns, intergenic regions and transposons being relatively more methylated than exons. Relative hypermethylation in Aid deficient PGCs was confirmed by analysis of individual loci in the genome. Our results reveal that erasure of DNA methylation in the germ line is a global process, hence limiting the potential for transgenerational epigenetic inheritance. Aid deficiency interferes with genome-wide erasure of DNA methylation patterns, suggesting that Aid has a critical function in epigenetic reprogramming and potentially in restricting the inheritance of epimutations in mammals.

Project description:Single Cell Microarray <br>E10.5 genital ridges (TM at E7.5) incubated in 0.5mM EDTA/ PBS for 20 minutes at 37ï¾°C were transferred to 2% BSA/ PBS. PGCs were collected from the genital ridges pierced with fine glass needles. Released PGCs were identified by their morphological characteristics and transferred into lysis buffer with a mouth pipette. PGCs were genotyped with the remaining genital ridges. The amplified cDNA library of each PGC was classified by qPCR-based expression analyses of Nanog, Oct4, and Stella/Dppa3 (Kurimoto et al., 2007). cDNAs were labeled by in vitro transcription (Affymetrix). The cRNAs were hybridized with the GeneChip Mouse Genome 430 2.0 Array (Affymetrix). Data were analyzed using the Microsoft Excel and MeV (multiple experimental viewer) software. <br>

Project description:The generation of properly functioning gametes in vitro, a key goal in developmental/reproductive biology, requires multi-step reconstitutions of complex germ cell development. Based on the logic of primordial germ cell (PGC)-specification, we demonstrate here the generation of PGC-like cells (PGCLCs) in mice with robust capacity for spermatogenesis from embryonic stem cells (ESCs) and induced pluripotent stem cells (iPSCs) through epiblast-like cells (EpiLCs), a cellular state highly similar to pre-gastrulating epiblasts, but distinct from epiblast stem cells (EpiSCs). The global transcription profiles, epigenetic reprogramming, and cellular dynamics during PGCLC induction from EpiLCs are a meticulous capture of those associated with PGC specification from the epiblasts. Furthermore, we identify Integrin-beta 3 and SSEA1 as markers that purify PGCLCs with spermatogenic capacity free from tumorigenic undifferentiated cells. With the reconstitution of PGC specification pathway from the naive inner cell mass state, our study defines a paradigm for the essential step of in vitro gametogenesis. We performed this analysis to reveal the characters of the cells that we created in this study, epiblast-like cells (EpiLCs) and primordial germ cells-like cells (PGCLCs). Because EpiLCs were induced from embryonic stem cells (ESCs), and equivalent to pre-gastrulating epiblast (embryonic day [E] 5.5-6.0) in vivo (embryo), ESCs and epiblast were included in this analysis. Epiblast stem cells (EpiSCs) are a culture cell type derived from epiblast, and were also included. PGCLCs were supposed to be equivalent to E9.5 PGCs based on reporter fluorescent transgene expressions and epigenetic properties, and therefore E9.5 PGCs were also inckuded in this analysis. Because epiblast and E9.5 PGCs are of a small number of cells in embryos (a few hundred to thousand cells), cDNAs were amplified with a quantitative global PCR method (Kurimoto et al., 2006, Nucleic Acids Research) for microarray analyses. We took two biological replicate for each cell type.

Project description:Naive pluripotent embryonic stem cells (ESCs) and embryonic germ cells (EGCs) are derived from the preimplantation epiblast and primordial germ cells (PGCs), respectively. We investigated whether differences exist between ESCs and EGCs, in view of their distinct developmental origins. PGCs are programmed to undergo global DNA demethylation; however, we find that EGCs and ESCs exhibit equivalent global DNA methylation levels. Importantly, inhibition of Erk and Gsk3b by 2i conditions leads to pronounced reduction in DNA methylation in both cell types. This is driven by Prdm14 and is associated with downregulation of Dnmt3a and Dnmt3b. However, genomic imprints are maintained in 2i, and we report derivation of EGCs with intact genomic imprints. Collectively, our findings establish that culture in 2i instills a naive pluripotent state with a distinctive epigenetic configuration that parallels molecular features observed in both the preimplantation epiblast and nascent PGCs.

Project description:Naive pluripotent embryonic stem cells (ESCs) and embryonic germ cells (EGCs) are derived from the preimplantation epiblast and primordial germ cells (PGCs), respectively. We investigated whether differences exist between ESCs and EGCs, in view of their distinct developmental origins. PGCs are programmed to undergo global DNA demethylation; however, we find that EGCs and ESCs exhibit equivalent global DNA methylation levels. Importantly, inhibition of Erk and Gsk3b by 2i conditions leads to pronounced reduction in DNA methylation in both cell types. This is driven by Prdm14 and is associated with downregulation of Dnmt3a and Dnmt3b. However, genomic imprints are maintained in 2i, and we report derivation of EGCs with intact genomic imprints. Collectively, our findings establish that culture in 2i instills a naive pluripotent state with a distinctive epigenetic configuration that parallels molecular features observed in both the preimplantation epiblast and nascent PGCs. EGC lines were derived from E8.5 mouse embryos using three different protocols: FCS+LIF on MEFs (FCS, n = 4)), FCS+LIF on MEFs for 48 hours followed by 2i+LIF (2is, n = 4), and direct derivation into 2i+LIF (2i, n = 4). ESC lines were derived in either FCS+LIF on MEFs or in 2i+LIF conditions and once established the cell lines were also switched between the two culture environments (n = 5 for each culture condition). All cell lines were derived from genetically identical embryos.

Project description:Primordial germ cells (PGCs) and preimplantation embryos undergo epigenetic reprogramming, which entails comprehensive erasure of DNA methylation. We found that PRMT5, an arginine methyltransferase, translocates from the cytoplasm to the nucleus during this process. Here we show that conditional loss of PRMT5 in early PGCs caused complete male and female sterility, which is preceded by upregulation of LINE1 and IAP transposons and DNA damage response. Similarly, loss of maternal-zygotic PRMT5 also leads to IAP upregulation and early embryonic lethality. We detected the PRMT5-catalysed repressive H2A/H4R3me2s modification on LINE1 and IAP in early wildtype PGCs, directly implicating this mark in the maintenance of transposon silencing during DNA hypomethylation. PRMT5 subsequently translocates back to the cytoplasm of PGCs to participate in the previously described PIWI-interacting RNA (piRNA) pathway that promotes transposon silencing via de novo DNA re-methylation. Thus, PRMT5 has a novel direct role in genome defense during preimplantation development and in PGCs at the time of global DNA demethylation PGCs mRNA profiles of embryonic day 11.5 dpc control (Blimp1Cre;Prmt5flox/+) and Prmt5 germ cell knockout (Blimp1Cre;Prmt5 flox/flox) were generated by deep sequencing (SOLiD next generation sequencing).

Project description:Primordial germ cells (PGCs) and preimplantation embryos undergo epigenetic reprogramming, which entails comprehensive erasure of DNA methylation. We found that PRMT5, an arginine methyltransferase, translocates from the cytoplasm to the nucleus during this process. Here we show that conditional loss of PRMT5 in early PGCs caused complete male and female sterility, which is preceded by upregulation of LINE1 and IAP transposons and DNA damage response. Similarly, loss of maternal-zygotic PRMT5 also leads to IAP upregulation and early embryonic lethality. We detected the PRMT5-catalysed repressive H2A/H4R3me2s modification on LINE1 and IAP in early wildtype PGCs, directly implicating this mark in the maintenance of transposon silencing during DNA hypomethylation. PRMT5 subsequently translocates back to the cytoplasm of PGCs to participate in the previously described PIWI-interacting RNA (piRNA) pathway that promotes transposon silencing via de novo DNA re-methylation. Thus, PRMT5 has a novel direct role in genome defense during preimplantation development and in PGCs at the time of global DNA demethylation PGCs mRNA profiles of embryonic day 11.5 dpc control (Blimp1Cre;Prmt5flox/+) and Prmt5 germ cell knockout (Blimp1Cre;Prmt5 flox/flox) were generated by deep sequencing (SOLiD next generation sequencing).