Project description:In this study, we developed a feeder-, serum-, and animal product-free culture condition, and successfully induced high percentage of SLCs from human PSCs. Genome-wide expression analyses demonstrated a significant upregulation of germ cell specific genes in SLCs derived from PSCs compared to in vivo isolated human CD90+ SSCs. And furthermore, under this optimized feeder-free condition SLCs have went through meiosis and formed putative round spermatids. Our data demonstrated a robust feeder-, serum- and xeno-free protocol to induce differentiation of PSCs to SLCs from which putative haploid spermatids may develop.

Project description:Induced pluripotent stem cells (iPSCs) have been generated from various somatic cells under feeder-layer conditions. These feeder-derived iPSCs generated in different labs exhibit greater variability than between different traditional embryo derived hESC lines. For that reason, it is important to develop a standard and defined system for deriving autologous patient stem cells. We have generated iPSCs under feeder-free conditions using Matrigel coated vessels in chemically defined medium, mTeSR1. These feeder-free derived iPSCs are in many ways similar to feeder-derived iPSCs and also to hESCs, with respect to their pluripotent gene expression (OCT4, NANOG, SOX2), protein expression (OCT4, NANOG, SSEA4, TRA160) and differentiation capabilities. We conducted a whole genomic transcript analysis using Affymetrix Human Gene 1.0 ST arrays to elucidate the important differences between traditional feeder-derived iPSCs and feeder-free derived iPSCs. We reveal that feeder-free iPSCs have over-represented terms belonging to DNA replication and cell cycle genes which are lacking in feeder-derived iPSCs. Feeder-free iPSCs are in many aspects more similar to hESCs including; apoptosis, chromatin modification enzymes and mitochondrial energy metabolism. We have also identified potential biomarkers for fully reprogrammed iPSCs (FRZB) and partially reprogrammed iPSCs (POTEG, MX2) based on their expression trends across all cell types. In conclusion, feeder-free derived iPSCs is transcriptomically more similar to hESCs than feeder derived iPSCs, in many biological functions.

Project description:Induced pluripotent stem cells (iPSCs) have been generated from various somatic cells under feeder-layer conditions. These feeder-derived iPSCs generated in different labs exhibit greater variability than between different traditional embryo derived hESC lines. For that reason, it is important to develop a standard and defined system for deriving autologous patient stem cells. We have generated iPSCs under feeder-free conditions using Matrigel coated vessels in chemically defined medium, mTeSR1. These feeder-free derived iPSCs are in many ways similar to feeder-derived iPSCs and also to hESCs, with respect to their pluripotent gene expression (OCT4, NANOG, SOX2), protein expression (OCT4, NANOG, SSEA4, TRA160) and differentiation capabilities. We conducted a whole genomic transcript analysis using Affymetrix Human Gene 1.0 ST arrays to elucidate the important differences between traditional feeder-derived iPSCs and feeder-free derived iPSCs. We reveal that feeder-free iPSCs have over-represented terms belonging to DNA replication and cell cycle genes which are lacking in feeder-derived iPSCs. Feeder-free iPSCs are in many aspects more similar to hESCs including; apoptosis, chromatin modification enzymes and mitochondrial energy metabolism. We have also identified potential biomarkers for fully reprogrammed iPSCs (FRZB) and partially reprogrammed iPSCs (POTEG, MX2) based on their expression trends across all cell types. In conclusion, feeder-free derived iPSCs is transcriptomically more similar to hESCs than feeder derived iPSCs, in many biological functions. For each cell sample, 2 or 3 biological replicates were obtained.

Project description:Since the creation of Dolly, the first sheep cloned via somatic cell nuclear transfer (SCNT), in 1997, more than a dozen species of mammals have been cloned using this technology. One hypothesis for the limited success of cloning via SCNT (1-5%) is that the clones are likely derived from adult stem cells, which form an extremely small fraction in most adult tissues. Support for this hypothesis is that the cloning efficiency of full term development using embryonic stem (ES) cells as nuclear donors is 5-10 times higher than that for somatic cells as nuclear donors. Additionally, cloned pups could not be produced directly from cloned embryos derived from nuclei of differentiated B and T cells or neuronal cells. The question remains: can SCNT-derived animal clones be derived from truly differentiated somatic cells? We tested this hypothesis with mouse hematopoietic cells at different differentiation stages: hematopoietic stem cells (HSCs), progenitor cells (HPCs), and granulocytes. Surprisingly, we found that cloning efficiency increases over the differentiation hierarchy. The terminally differentiated post-mitotic granulocytes yielded the greatest cloning efficiency and we produced two cloned pups from granulocytes. We conclude that cloned mammals could be directly derived from post-mitotic differentiated somatic cells. Keywords: cell type comparison

Project description:Here, we examined the effect of LDN-193189, an inhibitor of the BMP signaling pathway, on pig embryonic stem cells (ESCs) in the absence of feeder cells to develop a feeder-free culture system. Feeder cells play an important role in supporting the pluripotency of pig ESCs by blocking trophoblast and mesodermal differentiation through inhibition of the BMP pathway. Transcriptome analysis revealed that LDN-193189 treatment instead of coculturing with feeder cells could help maintain the pluripotency and homogenous cell population of pig ESCs by stimulating the secretion of chemokines and suppressing differentiation. We confirmed that LDN-193189-treated pig ESCs cultured without feeder cells maintained pluripotency for an extended period and were capable of differentiating in vivo and in vitro. The pig ESCs represented distinct characteristics of pig epiblasts as an in vivo counterpart at a transcriptomic level. In summary, we developed feeder-free culture systems for pig ESCs, and our findings will improve the understanding of pluripotency gene networks and comparative embryogenesis.

Project description:Here, we examined the effect of LDN-193189, an inhibitor of the BMP signaling pathway, on pig embryonic stem cells (ESCs) in the absence of feeder cells to develop a feeder-free culture system. Feeder cells play an important role in supporting the pluripotency of pig ESCs by blocking trophoblast and mesodermal differentiation through inhibition of the BMP pathway. Transcriptome analysis revealed that LDN-193189 treatment instead of coculturing with feeder cells could help maintain the pluripotency and homogenous cell population of pig ESCs by stimulating the secretion of chemokines and suppressing differentiation. We confirmed that LDN-193189-treated pig ESCs cultured without feeder cells maintained pluripotency for an extended period and were capable of differentiating in vivo and in vitro. The pig ESCs represented distinct characteristics of pig epiblasts as an in vivo counterpart at a transcriptomic level. In summary, we developed feeder-free culture systems for pig ESCs, and our findings will improve the understanding of pluripotency gene networks and comparative embryogenesis.

Project description:Since the creation of Dolly, the first sheep cloned via somatic cell nuclear transfer (SCNT), in 1997, more than a dozen species of mammals have been cloned using this technology. One hypothesis for the limited success of cloning via SCNT (1-5%) is that the clones are likely derived from adult stem cells, which form an extremely small fraction in most adult tissues. Support for this hypothesis is that the cloning efficiency of full term development using embryonic stem (ES) cells as nuclear donors is 5-10 times higher than that for somatic cells as nuclear donors. Additionally, cloned pups could not be produced directly from cloned embryos derived from nuclei of differentiated B and T cells or neuronal cells. The question remains: can SCNT-derived animal clones be derived from truly differentiated somatic cells? We tested this hypothesis with mouse hematopoietic cells at different differentiation stages: hematopoietic stem cells (HSCs), progenitor cells (HPCs), and granulocytes. Surprisingly, we found that cloning efficiency increases over the differentiation hierarchy. The terminally differentiated post-mitotic granulocytes yielded the greatest cloning efficiency and we produced two cloned pups from granulocytes. We conclude that cloned mammals could be directly derived from post-mitotic differentiated somatic cells. Experiment Overall Design: single channel Affymetrix arrays to confirm cell-type specific gene expression profiles

Project description:Trophoblast stem cells (TSCs) are derived from the trophoectoderm of blastocysts and maintain ability to self-renewal and differentiation. TSC is a good model to research placenta development in vitro. It will contribute to understanding and improving cloned placentomegaly to compare the transcription and methylation between cloned and natural fertilized embryos throughout TSC derivation process. In the present study, we used SCNT (NT) and SCNT with HDACi treatment (SNT) as cloned groups and natural fertilized (NF) embryos to derive TSCs and chosed 5-time points to peform RNA-seq and RRBS. We found only NT got a barriar in TSC maintenace and both cloned groups exhited abnormal accumulating DNA methylation and it might be resiponsible for some malformations of cloned placentas.

Project description:Trophoblast stem cells (TSCs) are derived from the trophoectoderm of blastocysts and maintain ability to self-renewal and differentiation. TSC is a good model to research placenta development in vitro. It will contribute to understanding and improving cloned placentomegaly to compare the transcription and methylation between cloned and natural fertilized embryos throughout TSC derivation process. In the present study, we used SCNT (NT) and SCNT with HDACi treatment (SNT) as cloned groups and natural fertilized (NF) embryos to derive TSCs and chosed 5-time points to peform RNA-seq and RRBS. We found only NT got a barriar in TSC maintenace and both cloned groups exhited abnormal accumulating DNA methylation and it might be resiponsible for some malformations of cloned placentas.

Project description:We performed transcriptomic profiling of freshly isolated primary adult human alveolar epithelial type 2 cells (AEC2s), their isogenic cultured progeny, and human induced pluripotent stem cell-derived AEC2s (iAEC2s). Distal lung preparations from adult donor lung explants from two individuals were cryopreserved using methods we have previously described. Primary AEC2s were purified using fluorescence activated cell sorting (FACS) to isolate cells co-expressing EPCAM and HTII-280. To establish cultures of primary AEC2s, these cells were combined with MRC5 fibroblasts at an 1:10 ratio on cell culture inserts in CK+DCI medium. iAEC2s were derived using our previously published lung directed differentiation protocol. We used the SPC2 human iPSC line and specifically the SPC2-ST-B2 (SFTPC tdT/WT ) clone containing a SFTPC tdTomato knock-in reporter. SFTPC tdTomato+ cells were sorted on day 41 of differentiation. iAEC2s were single-cell passaged in self-renewing feeder-free 3D cultures approximately every 2 weeks. We used the 10X Chromium System to generate single-cell transcriptomic data from 5 samples prepared in parallel and sequenced on the same day. We profiled (a) preculture primary AEC2s, (b) cultured primary AEC2s, (c) 3D feeder-free iAEC2s, (d) feeder-free iAEC2 cultured on cell culture inserts, and (e) iAEC2s cultured on cell inserts with MRC5 fibroblasts. The cultured primary AEC2 samples and the iAEC2 sample co-cultured with MRC5s were sorted for live EPCAM+ cells prior to encapsulation. All other samples were sorted for live cells. We find that although each population (fresh, primary cultured, and iPSC-derived AEC2s) occupies a distinct transcriptomic space, both cultured primary AEC2s and cultured feeder-free iAEC2s closely resemble their primary pre-cultured counterparts. We also find a continuum of progressively more proliferative states (from fresh primary to cultured primary to cultured iAEC2s) inversely associated with progressively less mature AEC2 states.