Project description:Generation of research quality, clinically relevant cell types in vitro from human pluripotent stem cells (hPSCs) requires detailed understanding of the equivalent cell types in humans. Here we analyzed 130 human fetal samples at 6-20 weeks of development and identified the stages in which human cKIT+ primordial germ cells (PGCs), the precursors of gametes, undergo whole genome epigenetic reprogramming and ultimately initiation of imprint erasure with loss of both 5mC and 5-hydroxy-mC at differentially methylated regions. Using five alternate in vitro differentiation strategies combined with a single-cell microfluidic analysis, high throughput RNA sequencing and a bona fide human cKIT+ PGC signature, we show that hPSC differentiation generates a rare cKIT+ PGC subtype found in both the human fetal gonad and mouse embryo. Taken together, our study creates a resource of human germ line ontogeny that is absolutely essential for future studies aimed at interpreting in vitro differentiation of the human germ line. cKIT+ cells analyzed from 2 biological samples for testes and 2 samples for ovaries at 16 and 16.5 weeks. 3 biological replicates of TRA-1-60+ cells sorted from H1 hESCs

Project description:We performed RNA-Seq analyses on 15 human fetal samples at 53-137 days of development, 9 female and 5 male, and identified the transcriptional changes during the transition of human cKIT+ primordial germ cells (PGCs), the precursors of gametes, to the generation of Advanced Germline Cells. Comparing the transcriptional profile of PGCs to that of H1 and UCLA1 hESCs identifies differences between the two cell types and pinpoints molecules that can be used in the development of in vitro germ cell differentiation protocols starting from human pluripotent stem cells.

Project description:We performed RNA-Seq analyses on 15 human fetal samples at 53-137 days of development, 9 female and 5 male, and identified the transcriptional changes during the transition of human cKIT+ primordial germ cells (PGCs), the precursors of gametes, to the generation of Advanced Germline Cells. Comparing the transcriptional profile of PGCs to that of H1 and UCLA1 hESCs identifies differences between the two cell types and pinpoints molecules that can be used in the development of in vitro germ cell differentiation protocols starting from human pluripotent stem cells. RNA-Seq of cKIT+ cells analyzed from 6 biological samples for testes and 9 samples for ovaries from 53-137 days. 2 biological replicates of TRA-1-81+ cells sorted from H1 and UCLA1 hESCs. WGBS of cKIT+ cells analyzed from 4 biological samples of ovaries and 1 biological sample of testes at 57-137 days of development.

Project description:The molecular mechanisms of human primordial germ cell (PGC) specification are poorly understood due to the inaccessibility of cell materials and the lack of an alternative in vitro model that enables tracking of the earliest stages of germ cell development. Here, we introduce a defined and efficient differentiation system for the induction of pre-migratory PGC-like cells from human embryonic stem cells (ESCs) and induced pluripotent stem cells (iPSCs). By step-wise differentiation, we generated an OCT4+/ T+/BLIMP1+ cell population that transitioned into STELLA expressing PGC-like cells that exhibited a similar key gene expression as mouse PGCs as well as global epigenetic reprogramming. Even though, these PGC-like cells expressed PRDM14 at very low levels, they underwent activation of pluripotency/PGC genes, suppression of neural induction and suppression of de novo DNA methylation, events that are regulated by Prdm14 during mouse PGC specification. This study demonstrates that human PGC commitment shares many key features with mouse PGC specification, but harbors unique and so far unknown mechanisms that, point to a novel human transcriptional regulation. 7 samples were analyzed. ESC: Human Embryonic Stem Cells, 1 biological rep iPSC: Human induced Pluripotent Stem Cells, 1 biological rep d2: Human induced Pluripotent Stem Cells, 2 days differentiation treatment , 2 biological rep d4PGCLC: Human induced Pluripotent Stem Cells, 4 days differentiation treatment towards Primordial Germ Cells Like Cells, 1 biological rep d6PGCLC: Human induced Pluripotent Stem Cells, 6 days differentiation treatment towards Primordial Germ Cells Like Cells, 2 biological rep

Project description:We performed WGBS analyses on 6 human fetal samples at 53-137 days of development, 4 female and 2 male. We show that methylation reprogramming in the human germline is global yet incomplete with exons, 3’UTRs and human-specific transposons remaining methylated. Whole Genome Bisulfite-Seq of cKIT+ cells analyzed from 4 biological samples for fetal ovaries from 57-113 days of development and 2 samples for fetal testes at 59 and 137 days of development.

Project description:The molecular mechanisms of human primordial germ cell (PGC) specification are poorly understood due to the inaccessibility of cell materials and the lack of an alternative in vitro model that enables tracking of the earliest stages of germ cell development. Here, we introduce a defined and efficient differentiation system for the induction of pre-migratory PGC-like cells from human embryonic stem cells (ESCs) and induced pluripotent stem cells (iPSCs). By step-wise differentiation, we generated an OCT4+/ T+/BLIMP1+ cell population that transitioned into STELLA expressing PGC-like cells that exhibited a similar key gene expression as mouse PGCs as well as global epigenetic reprogramming. Even though, these PGC-like cells expressed PRDM14 at very low levels, they underwent activation of pluripotency/PGC genes, suppression of neural induction and suppression of de novo DNA methylation, events that are regulated by Prdm14 during mouse PGC specification. This study demonstrates that human PGC commitment shares many key features with mouse PGC specification, but harbors unique and so far unknown mechanisms that, point to a novel human transcriptional regulation.

Project description:Human embryonic stem cell lines HSF-1 and HSF-6 were differentiated on human fetal gonadal stromal cells for 7 days. The cells were labelled with antibodies against cKIT and SSEA1 and the double positive and double negative cells were collected for microarray analysis.

Project description:The molecular mechanisms underlying the commitment of cells to the germ cell lineage and the subsequent formation of germ cells during mammalian development remain poorly understood due to an inability to obtain sufficient amounts of cellular materials to conduct thorough in-vitro analyses. Although primordial germ cells (PGCs) have been generated and isolated from embryonic stem cells (ESCs) in vitro, concurrent expression of several cell surface receptors and transcription factors, at various levels, confounds the identification of these cells. To date, only a few genes that mark the onset of germ cell commitment to the epiblast, including tissue nonspecific alkaline phosphatase (TNAP), Blimp1, Stella, and Fragilis, have been used with some degree of success to detect PGC formation in in-vitro model systems. In light of the current literature, the generation of an unlimited supply of germ cells and gametes from pluripotent stem cells would greatly facilitate studies into reproductive development. To accomplish this, we would need to discover novel markers that are specifically expressed in germ cells. Here we identified four genes that are specifically expressed in male and female germ cells, both in vivo and in vitro, but are not expressed in somatic tissues or ESCs. Expression of these genes therefore allows us to distinguish committed germ cells from undifferentiated pluripotent cell populations, a prerequisite for the successful derivation of germ cells and gametes in vitro. For RNA isolation, PGCs were sorted by FACS, collected by centrifugation, lysed in RLT buffer (QIAGEN), and processed using RNeasy Micro kits with on-column DNase digestion as per the manufacturer's instructions. Integrity of RNA samples was quality-checked using a 2100 Bioanalyzer (Agilent). If possible, 300 ng of total RNA per sample was used as starting material for linear amplification (Illumina TotalPrep RNA amplification kit, Ambion), which involved synthesis of T7-linked double-stranded cDNA and 14 hrs of in-vitro transcription incorporating biotin-labeled nucleotides. Purified and labeled cRNA was then quality-checked on a 2100 Bioanalyser, and hybridized as biological or technical duplicates for 18 hrs onto MouseRef-8 v2 gene expression BeadChips (Illumina), following the manufacturer's instructions. After being washed, the chips were stained with streptavidin-Cy3 (GE Healthcare) and scanned using the iScan reader and accompanying software. 44 samples were analyzed. ESCm: OG2 male Embryonic Stem Cell, +/+ Oct4-GFP ES cells, 1 biological rep 11.5: 11.5 embryonic day PGC (Primordial Germ Cell), 2 biological reps 12.5F: 12.5 embryonic day female PGC (Primordial Germ Cell), 2 biological reps 13.5F: 13.5 embryonic day female PGC (Primordial Germ Cell), 2 biological reps 14.5F: 14.5 embryonic day female PGC (Primordial Germ Cell), 2 biological reps 15.5F: 15.5 embryonic day female PGC (Primordial Germ Cell), 2 biological reps 16.5F: 16.5 embryonic day female PGC (Primordial Germ Cell), 2 biological reps 17.5F: 17.5 embryonic day female PGC (Primordial Germ Cell), 2 biological reps 18.5F: 18.5 embryonic day female PGC (Primordial Germ Cell), 2 biological reps 12.5M: 12.5 embryonic day male PGC (Primordial Germ Cell), 2 biological reps 13.5M: 13.5 embryonic day male PGC (Primordial Germ Cell), 2 biological reps 14.5M: 14.5 embryonic day male PGC (Primordial Germ Cell), 2 biological reps 15.5M: 15.5 embryonic day male PGC (Primordial Germ Cell), 2 biological reps 16.5M: 16.5 embryonic day male PGC (Primordial Germ Cell), 2 biological reps 17.5M: 17.5 embryonic day male PGC (Primordial Germ Cell), 2 biological reps 18.5M: 18.5 embryonic day male PGC (Primordial Germ Cell), 2 biological reps 8M: 8 day after birth male PGC (Primordial Germ Cell), 2 biological reps 10M: 10 day after birth male PGC (Primordial Germ Cell), 2 biological reps 12M: 12 day after birth male PGC (Primordial Germ Cell), 2 biological reps 14M: 14 day after birth male PGC (Primordial Germ Cell), 1 biological rep 16M: 16 day after birth male PGC (Primordial Germ Cell), 2 biological reps 18M: 18 day after birth male PGC (Primordial Germ Cell), 2 biological reps 20M: 20 day after birth male PGC (Primordial Germ Cell), 2 biological reps

Project description:The successful segregation of germ cells from somatic lineages is vital for sexual reproduction and species survival. In the mouse, primordial germ cells (PGCs), precursors of all germ cells, are induced from the post-implantation epiblast. Induction requires BMP4 signalling to prospective PGCs and the intrinsic action of PGC transcription factors (TFs). However, the molecular mechanisms connecting BMP4 action to induction of PGC TFs that are responsible for segregation of PGCs from somatic lineages are unknown. Here we show that the transcription factor OTX2 is a key regulator of these processes. Down-regulation of Otx2 precedes the initiation of the PGC programme both in vitro and in vivo. Deletion of Otx2 in vitro dramatically increases PGCLC differentiation efficiency and prolongs the period of PGC competence. In the absence of Otx2 activity, PGCLC differentiation becomes independent of the otherwise essential cytokine signals, with germline entry initiating even in the absence of the PGC TF Blimp1. Deletion of Otx2 in vivo increases PGC numbers. These data demonstrate that Otx2 acts repressively upstream of PGC TFs and functions as a roadblock to prevent the untimely entry of pluripotent stem cells into the PGC lineage, thereby ensuring correct spatio-temporal segregation of the germline and soma.

Project description:Porcine embryonic germ cells (EGC) are cultured pluripotent cells derived from primordial germ cells (PGC). This study explored the possibilities to establish porcine EGC lines in the domestic breed pig more efficiently and from earlier embryonic stages than reported to date. In vitro culture of PGC from both pooled and individual embryos at days 17-24 of gestation resulted in the successful derivation of putative EGC lines from days 20-24 with high efficiency, while no lines could be established from days 17-18. The EGC-like colonies had characteristic morphology and electron microscopy revealed tight junctions and presence of primary cilia on the cell surfaces. The cells formed simple embryoid bodies in suspension culture and further differentiated into epithelial-like, mesenchymal-like, and neuronal-like cells. Our results show that putative porcine EGC can be derived from migrating PGC with high efficiency using individual embryos from different genetic backgrounds. RNA-Seq profiling of 2 different in vitro cultures of pig embryonic cells. The cells, both the pig Embryonic Germ cells (pEGCs) and the pig Fetal Fibroblasts (pFF) show properties of pluripotency and self renewal.