Project description:Somatic cells can be reprogrammed to pluripotency using different methods. In comparison to pluripotent cells obtained through somatic nuclear transfer, induced pluripotent stem cells (iPSCs) exhibit a higher number of epigenetic errors. Furthermore, most of these abnormalities have been described to be intrinsic to the iPSC technology. Here we investigate whether the aberrant epigenetic patterns detected in iPSCs are specific to transcription factor-mediated reprogramming. We used germline stem cells (GSCs), which are the only adult cell type that can be converted into pluripotent cells (gPSCs) under specific culture conditions, and compared GSC-derived iPSCs and gPSCs at the transcriptomic, epigenetic and functional level. Our results show that both reprogramming methods generate indistinguishable states of pluripotency. GSC-derived iPSCs and gPSCs retained similar levels of donor cell-type memory and exhibited comparable numbers of reprogramming errors. Therefore, our study demonstrates that the epigenetic memory detected in iPSCs is not intrinsic to transcription factor-mediated reprogramming.

Project description:Somatic cells can be reprogrammed to pluripotency using different methods. In comparison to pluripotent cells obtained through somatic nuclear transfer, induced pluripotent stem cells (iPSCs) exhibit a higher number of epigenetic errors. Furthermore, most of these abnormalities have been described to be intrinsic to the iPSC technology. Here we investigate whether the aberrant epigenetic patterns detected in iPSCs are specific to transcription factor-mediated reprogramming. We used germline stem cells (GSCs), which are the only adult cell type that can be converted into pluripotent cells (gPSCs) under specific culture conditions, and compared GSC-derived iPSCs and gPSCs at the transcriptomic, epigenetic and functional level. Our results show that both reprogramming methods generate indistinguishable states of pluripotency. GSC-derived iPSCs and gPSCs retained similar levels of donor cell-type memory and exhibited comparable numbers of reprogramming errors. Therefore, our study demonstrates that the epigenetic memory detected in iPSCs is not intrinsic to transcription-factor mediated reprogramming.

Project description:Pluripotency can be induced from different cell types using different methods. Several studies have reported that iPSC retain an epigenetic memory from the tissue from which they were derived. However, the influence of the method used for reprogramming in the final pluripotent state has not been investigated yet. Therefore, we have taken advantage of germline stem cells (GSCs) that can be converted into germline pluripotent stem cells (gPSCs) using specific culture conditions or into induced pluripotent stem cells (iPSCs) after the forced expression of four transcription factors. Here, we compare the gene expression profile, imprinting methylation pattern and differentiation potential between GSC-derived iPSCs and gPSCs. Our analysis demonstrates that both reprogramming methods induce equivalent levels of pluripotency and that a donor GSC transcriptional memory is retained only at early steps after reprogramming. In summary, our results show that different reprogramming methods generate undistinguishable pluripotent states and exclude a method-dependent epigenetic memory. Cell Culture. All the cell lines used in this study were derived from OG2 mice. Unless otherwise noted, all cell culture reagents were purchased from Gibco or PAA. Neonatal GSCs derived from 10 days postpartum (d.p.p) murine testis and adult GSCs derived from 35 d.p.p murine testis were derived as previously described and cultured on irradiated C3H feeder cells in a medium composed of StemPro-34 SFM (including supplement), N2 supplement (1:100), 1 % heat-inactivated fetal calf serum (FCS), 5 mg ml-1 bovine serum albumin (BSA) fraction V, 100 U ml-1 penicillin, 100 µg ml-1 streptomycin, 2 mM L‑glutamine, 0.1 mM non-essential amino acids (NEAA), 0.1 mM β‑mercaptoethanol, MEM vitamins (1:100), 6 mg ml-1 D‑(+)‑glucose (Sigma), 30 mg ml-1 pyruvic acid, 0.1 % DL‑lactic acid (Sigma), 60 ng ml-1 progesterone (Sigma), 30 ng ml-1 β‑estradiol (Sigma), 15 ng ml-1 mouse EGF (Peprotech), 10 ng ml-1 human bFGF (Peprotech), 10 ng ml-1 human GDNF (Peprotech), and 1000 U ml-1 mouse LIF (in‑house preparation). For maintenance culture, GSCs were passaged at a 1:2‑ratio once a week after digestion with 0.05 % trypsin/EDTA. In addition, ESCs, iPSC and gPSC were cultured on irradiated C3H feeders in the following medium: Knockout DMEM, 20% Knockout Serum Replacement, penicillin, streptomycin, L‑glutamine, NEAA, β‑mercaptoethanol, and LIF. Generation of pluripotent cell lines. iPSC were generated using tetracycline-inducible lentiviruses. For the lentiviral production, 293T cells were plated at 50 % confluency in 10-cm dishes one day prior to transfection. The next day, the lentiviral vector (3 µg) together with the packaging plasmids psPAX2 (2 µg) and pMD2.G (1 µg) (Addgene plasmids #12260 and #12259, respectively) were transfected using FuGENE 6 reagent (Roche) according to the manufacturer’s protocol. After 48 h, viral-containing supernatants were filtered (0.45 µm), concentrated around 30-fold by centrifugation (26,000 × g, 2 h, 4 °C) and stored at -80 °C. For the generation of iPSCs, a single-cell suspension of 50,000 GSCs was infected overnight with five tetracycline-inducible lentiviruses (5–20 µl concentrated supernatant each) encoding for Oct4, Sox2, Klf4, c-Myc, and the reverse tetracycline-transactivator M2-rtTA (Addgene plasmids #20323, #20326, #20322, #20324, and #20342) in the presence of 4 µg ml-1 polybrene (Sigma). One week after the infection, the expression of the viral transgenes was induced by adding 4 µg ml-1 doxycycline (Sigma) to the medium. MEFs-derived iPSCs were generated using the same protocol. gPSC were generated following a previous reported protocol. Briefly, GSCs were seeded at a density of approx. 1000 cells cm-2 on feeder cells and were not splitted until gPSC colonies were observed. Both iPSC and gPSC colonies were identified by Oct4-GFP expression, manually picked and expanded under ESC conditions. In vitro differentiation of pluripotent cells. Embryoid body (EB) formation was induced in suspension culture adopting the hanging drop method (600 cells in 20 µl) for 5 days in ESC medium without LIF. EBs were seeded on gelatine-coated plates and further cultured for 14 days in the same medium. Chimera formation. Aggregations of putative pluripotent cells with denuded 8-cell stage embryos were performed as previously reported. After overnight incubation at 37 °C and 5 % CO2, 11–14 aggregates were transferred into the uterine horns of 2.5 d.p.c pseudo-pregnant surrogate mothers (mated with vasectomized males). The chimeric pups were obtained and dissected at 14.5 d.p.c. Microarray gene expression analysis. Purified cRNA samples were prepared with the linear TotalPrep RNA Amplification Kit (Ambion) from 500 ng original RNA, involving synthesis of double-stranded cDNA by T7-promoter-linked oligo(dT) primers and 14 hours of in-vitro transcription incorporating biotin-labelled nucleotides. Hybridizations onto MouseRef 8 v2.0 Expression BeadChips (Illumina) was performed according to the manufacturer’s recommendations. Two replicates were hybridized from each sample. Chips were stained with streptavidin-Cy3 (GE Healthcare) and scanned using an iScan reader (Illumina). The bead intensities were mapped to gene information using BeadStudio 3.2 (Illumina). Background correction was performed using the Affymetrix robust multiarray analysis (RMA) background correction model. Variance stabilization was performed by log2 scaling, and gene expression normalization was calculated with the method implemented in the lumi package of R-Bioconductor. Samples were hybridised as biological replicates. 26 samples were analyzed. iPSC[GSCneonatal]#1: iPSC day 10 from GSC, clone 1, 2 biological rep iPSC[GSCneonatal]#2: iPSC day 10 from GSC, clone 2, 2 biological rep iPSC[GSCadult]#1: iPSC day 40 from GSC, clone 1, 2 biological rep iPSC[GSCadult]#2: iPSC day 40 from GSC, clone 2, 2 biological rep gPSC[GSCneonatal]#1: gPSC day 10 from GSC, clone 1, 2 biological rep gPSC[GSCneonatal]#2: gPSC day 10 from GSC, clone 2, 2 biological rep gPSC[GSCadult]#1: gPSC day 40 from GSC, clone 1, 2 biological rep gPSC[GSCadult]#2: gPSC day 40 from GSC, clone 2, 2 biological rep ESC: OG2 ESCs, 2 biological rep iPSC[MEF]: iPSC (Tet-4F) from OG2 MEFs, 2 biological rep GSC[neonatal]: GSC day 10, 2 biological rep GSC[adult]: GSC day 40, 2 biological rep MEF: Mouse embryonic fibroblasts, 2 biological rep

Project description:Mouse and human stem cells with features similar to those of embryonic stem cells have been derived from testicular cells. Although pluripotent stem cells have been obtained from defined germline stem cells (GSCs) of mouse neonatal testis, only multipotent stem cells have been obtained so far from defined cells of mouse adult testis. In this study we describe a robust and reproducible protocol for obtaining germline-derived pluripotent stem (gPS) cells from adult unipotent GSCs. Pluripotency of gPS cells was confirmed by in vitro and in vivo differentiation, including germ cell contribution and transmission. As determined by clonal analyses gPS cells indeed originate from unipotent GSCs. We propose that the conversion process requires a GSC culture microenvironment that depends on the initial number of plated GSCs and the length of culture time. Nine samples were analyzed. GSC1: Mouse Germ Stem Cells, line 1 (1 replicate), GSC2: Mouse Germ Stem Cells, line 2 (1 replicate), GSC3: Mouse Germ Stem Cells, line 3 (1 replicate), GSC4: Mouse Germ Stem Cells, line 4 (1 replicate) gPS1: Mouse clonal germ Pluripotent Stem cells, line 1, GFP-sorted (1 replicate), gPS2: Mouse clonal germ Pluripotent Stem cells, line 2, GFP-sorted (1 replicate), gPS3: Mouse clonal germ Pluripotent Stem cells, line 3, GFP-sorted (1 replicate) ESC: Mouse Embryonic Stem Cells (duplicate)

Project description:Using induced pluripotent stem cell (iPSC) technology, we reprogrammed GBM derived cells (GBM-DCs) into embryonic-like cells termed as induced core-GSCs (ic-GSCs). The aim of this experiment was to characterize the transcriptomic profile of ic-GSCs using RNA-seq. For this experiment, we selected three biological replicates of GBM-DCs (GBM-DC1, GBM-DC2 and GBM-DC3) and three independent clonal lines of ic-GSCs (ic-GSC#1, ic-GSC#3 and ic-GSC#7).

Project description:Mouse and human stem cells with features similar to those of embryonic stem cells have been derived from testicular cells. Although pluripotent stem cells have been obtained from defined germline stem cells (GSCs) of mouse neonatal testis, only multipotent stem cells have been obtained so far from defined cells of mouse adult testis. In this study we describe a robust and reproducible protocol for obtaining germline-derived pluripotent stem (gPS) cells from adult unipotent GSCs. Pluripotency of gPS cells was confirmed by in vitro and in vivo differentiation, including germ cell contribution and transmission. As determined by clonal analyses gPS cells indeed originate from unipotent GSCs. We propose that the conversion process requires a GSC culture microenvironment that depends on the initial number of plated GSCs and the length of culture time.

Project description:Mouse and human stem cells with features similar to those of embryonic stem cells have been derived from testicular cells. Although pluripotent stem cells have been obtained from defined germline stem cells (GSCs) of mouse neonatal testis, only multipotent stem cells have been obtained so far from defined cells of mouse adult testis. In this study we describe a robust and reproducible protocol for obtaining germline-derived pluripotent stem (gPS) cells from adult unipotent GSCs. Pluripotency of gPS cells was confirmed by in vitro and in vivo differentiation, including germ cell contribution and transmission. As determined by clonal analyses, gPS cells indeed originate from unipotent GSCs. We propose that the conversion process requires a GSC culture microenvironment that depends on the initial number of plated GSCs and the length of culture time.

Project description:Using induced pluripotent stem cell (iPSC) technology, we reprogrammed GBM derived cells (GBM-DCs) into embryonic-like cells termed as induced core-GSCs (ic-GSCs). The aim of this experiment was to characterize the DNA methylation profile of ic-GSCs using the Infinium MethylationEPIC array BeadChip (850K, Illumina). For this experiment, we selected three biological replicates of GBM-DCs (GBM-DC1, GBM-DC2 and GBM-DC3) and three independent clonal lines of ic-GSCs (ic-GSC#1, ic-GSC#3 and ic-GSC#7).

Project description:The maintenance and differentiation of highly potent animal stem cells generates an epigenetic cycle that underlies development. Drosophila female germline stem cells (GSC) produce cystoblast daughters that differentiate into nurse cells and oocytes. Developmental chromatin analysis profiling the differentiation of GSCs into cystoblasts and NCs of increasing ploidy shows that cystoblasts start developing by forming heterochromatin while in a transient syncytial state, the germline cyst, reminiscent of early embryonic cells. The open GSC chromatin state is further restricted by Polycomb repression of targets that include testis expressed genes briefly active in early female germ cells. Like other highly potent stem cells, GSC metabolism is reprogrammed and Myc-dependent growth is upregulated by altering mitochondrial membrane transport, gluconeogenesis and other processes. Thus, the animal generational cycle comprises similar but distinct maternal and zygotic stem cell epigenetic cycles. We propose that the pluripotent stem cell state and daughter cell differentiation were shaped by the pressure to resist transposon activity over evolutionary time scales. In this GEO submission, we present data and analyses pertaining to H3K27ac, H3K27me3, and H3K9me3 ChIPseq, ATACseq, and RNAseq of Germline Stem Cells (GSCs) and Nurse Cells (NCs) from Drosophila melanogaster ovaries.

Project description:In regenerative medicine, histocompatibility of pluripotent stem cells is required to solve the problem of immunorejection after therapeutic transplantation. In this study, we show that autologous germline stem cells (GSCs), often called spermatogonial stem cells, could be derived by testis biopsy from individual mice and that GSCs subsequently could be dedifferentiated into autologous germline-derived pluripotent stem (gPS) cells. The establishment of GSCs by testicular biopsy in the mouse model can prove the principle of human clinical application to derive autologous GSCs to generate patient-specific pluripotent cells for regenerative medicine.