Project description:Background: The hES-T3 cell line with normal female karyotype was used to differentiate into autogeneic fibroblast-like cells (T3HDF) as feeder to support the undifferentiated growth of hES-T3 cells (T3/HDF) for 14 passages. A feeder-free culture on Matrigel in hES medium conditioned by these autogeneic feeder cells (T3HDF) was established to maintain the undifferentiated growth of hES-T3 cells (T3/CMHDF) for 8 passages. Results: The gene expression profiles of mRNAs, microRNAs and proteins between the undifferentiated T3/HDF and T3/CMHDF cells were shown to be very similar, and their expression profiles were also found to be similar to those of T3/MEF and T3/CMMEF cells grown on MEF feeder and feeder-free Matrigel in MEF-conditioned medium, respectively. The abundantly expressed genes of T3/HDF, T3/CMHDF, T3/MEF and T3/CMMEF cells were found to play prominent roles in signaling pathways and GO process networks. The miR-302/367 cluster and miR-371/372/373 cluster were extremely abundantly expressed in undifferentiated T3/HDF and T3/CMHDF as well as T3/MEF andT3/CMMEF cells. The undifferentiated state of T3/HDF and T3/CMHDF cells was evidenced by the very high expression levels of ¡§stemness¡¨ genes and low expression levels of differentiation markers of ectoderm, mesoderm and endoderm in addition to the strong staining of OCT4 and NANOG. Conclusion: The T3HDF feeder and T3HDF-conditioned medium were able to support the undifferentiated growth of hES cells, and they would be useful for drug development and toxicity testing in addition to the reduced risks of xenogeneic pathogens when used for medical applications such as cell therapies. Keywords: genetic modification In this investigation, both miRNA and mRNA expression profiles from human embryonic stem cells (hES-T3) grown on MEF feeder (T3_MEF), feeder-free Matrigel in MEF-conditioned medium (T3_CMMEF), T3HDF (hES-T3 differentiated fibroblast-like cells) feeder and feeder-free Matrigel in T3HDF-conditioned medium were quantitatively determined. Several target genes of T3BA and T3CM cells-specific miRNAs were identified. ***This submission represents the mRNA expression component of the study only***

Project description:Type 1 diabetes is an autoimmune destruction of pancreatic islet beta cell disease, and it is important to find new alternative source of the islet beta cells to replace the damaged cells. Human embryonic stem (hES) cells possess unlimited self-renewal and pluripotency and thus have the potential to provide an unlimited supply of different cell types for tissue replacement. The hES-T3 cells with normal female karyotype were first differentiated into embryoid bodies and then induced to generate the pancreatic islet-like cell clusters, which expressed pancreatic islet cell-specific markers of insulin, glucagon and somatostatin. The expression profiles of microRNAs and mRNAs from the pancreatic islet-like cell clusters were further analyzed and compared with those of undifferentiated hES-T3 cells and differentiated embryoid bodies. MicroRNAs negatively regulate the expression of protein-coding mRNAs. The pancreatic islet-like cell clusters were found to exhibit very high expression of microRNAs miR-186, miR-199a and miR-339, which down-regulated the expression of LIN28, PRDM1, CALB1, GCNT2, RBM47, PLEKHH1, RBPMS2 and PAK6. Therefore, these microRNAs are very likely to play important regulatory roles in the differentiation of pancreatic islet cells and early embryonic development. In this investigation, both miRNA and mRNA expression profiles from the pancreatic islet-like cell clusters differentiated from hES-T3 cells (T3pi) were quantitatively determined and compared with those of undifferentiated hES-T3 cells grown on mouse embryonic fibroblast (MEF) feeder (T3ES) and embryoid bodies differentiated from hES-T3 cells (T3EB). Several target genes of pancreatic islet cell-specific miRNAs were identified. ***This submission represents the mRNA expression component of the study only***

Project description:MicroRNAs (miRNAs) are noncoding RNAs of approximately 22 nucleotides in length that usually suppress the translation of target messenger RNAs (mRNAs) through partial complementarity to the 3¡¦ untranslated region (3¡¦ UTR) of protein-coding mRNAs in animals. However, there is increasing evidence that miRNAs can also reduce the steady-state levels of their target mRNAs in animals. In this investigation, both miRNA and mRNA profiles from the undifferentiated human embryonic stem cell line hES-T3 (T3ES), hES-T3 derived embryoid bodies (T3EB) and hES-T3 differentiated fibroblast-like cells (T3DF) were quantitatively determined. Three common target genes of three highly expressed hES cell-specific miRNAs were identified by inverse expression levels of miRNAs to their target mRNAs. Experiment Overall Design: Three types of human embryonic stem cells and their derived cells (the undifferentiated human embryonic stem cell line hES-T3 (T3ES), hES-T3 derived embryoid bodies (T3EB) and hES-T3 differentiated fibroblast-like cells (T3DF)) were selected for RNA extraction. The genome-wide mRNA expression of T3ES, T3EB and T3DF cells was determined using Affymetrix human genome U133 plus 2.0 GeneChip. The abundantly expressed genes (10-fold above overall mean) in T3ES, T3EB and T3DF cells are selected to compare with the predicted gene targets of differentially expressed miRNAs in the same set of cells.

Project description:Analysis of genes that were differentially expressed in MSC-derived hES cells (VUB01 and SA01) as compared to VUB01 and SA01 undifferentiated hES cells Experiment Overall Design: Two cell lines (VUB01 and SA01) with three biological replicates for each

Project description:Human embryonic stem (hES) cells have the capacities to propagate for extended periods and to differentiate into cell types from all three germ layers both in vitro and in vivo. These characteristics of self-renewal and pluripotency enable hES cells having the potential to provide an unlimited supply of different cell types for tissue replacement, drug screening, and functional genomics studies. The hES-T3 cells with normal female karyotype cultured on either mouse embryonic fibroblasts (MEF) in hES medium (containing 4 ng/ml bFGF) (T3MF) or feeder-free Matrigel in MEF-conditioned medium (supplemented with additional 4 ng/ml bFGF) (T3CM) were found to express very similar profiles of mRNAs and microRNAs, indicating that the unlimited self-renewal and pluripotency of hES cells can be maintained by continuing culture on these two conditions. However, the expression profiles, especially microRNAs, of the hES-T3 cells cultured on Matrigel in hES medium supplemented with 4 ng/ml bFGF and 5 ng/ml activin A (T3BA) were found to be different from those of T3MF and T3CM cells. In T3BA cells, four hES cell-specific microRNAs miR-372, miR-302d, miR-367 and miR-200c, as well as three other microRNAs miR-199a, miR-19a and miR-217, were found to be up-regulated, whereas five miRNAs miR-19b, miR-221, miR-222, let-7b and let-7c were down-regulated by activin A. Thirteen abundantly differentially expressed mRNAs, including NR4A2, ERBB4, CXCR4, PCDH9, TMEFF2, CD24 and COX6A1 genes, targeted by seven over-expressed miRNAs were identified by inverse expression levels of these seven microRNAs to their target mRNAs in T3BA and T3CM cells. The NR4A2, ERBB4 and CXCR4 target genes were further found to be regulated by EGF and/or TNF. The 50 abundantly differentially expressed genes targeted by five under-expressed miRNAs were also identified. The abundantly expressed mRNAs in T3BA and T3CM cells were also analyzed for the network and signaling pathways, and roles of activin A in cell proliferation and differentiation were found. These findings will help elucidate the complex signaling network which maintains the self-renewal and pluripotency of hES cells.

Project description:This SuperSeries is composed of the following subset Series: GSE7177: Comparison of gene expression data between wild-type and DM1-affected Mesodermal Precursors Cells (MPC) GSE7178: Comparison of gene expression data between wild-type and DM1-affected Neural Precursors Cells (NPC) GSE7179: Comparison of gene expression data between wild-type and DM1-affected undifferentiated hES cells. Keywords: SuperSeries Refer to individual Series

Project description:I developed a new culture system for hES cells; this system does not require supplementation with bFGF to obtain hES cells that are suitable for tissue engineering and regenerative medicine. This culture system employed mesenchymal stem cells derived from hES cells (hESC-MSCs) as autologous human feeder cells in the absence of bFGF. For pluripotency-related gene expression profiling, a cDNA microarray analysis was performed SNUhES3 cultured on the autofeeder hESC-MSCs layer maintained the undifferentiated state for 30 passages in a manner similar to the SNUhES3 cells on xenofeeder STO cell layer. To compare the pluripotency-related genes in SNUhES3 cells cultured on autofeeder or xenofeeder system, I used agilent one-color array. Two independant experiment performed.

Project description:Analysis of genes that were differentially expressed in mutant VUB03_DM1 as compared to controls VUB01 and SA01 undifferentiated hES cells Embryonic stem (ES) cell lines provide, theoretically, unlimited access to any needed amount of any specific cell phenotype of an organism, due to their unique capacities at indefinite self-renewal and pluripotency (Smith 2001; Trounson 2006). These properties allow using the progeny of ES cell lines to model human pathologies (Martinat, Shendelman et al. 2004; Lerou and Daley 2005; Ben-Nun and Benvenisty 2006). In particular, human ES cell lines derived from embryos characterized as gene-carriers following pre-implantation genetic diagnosis (PGD) for any one of major monogenic diseases (Pickering, Minger et al. 2005; Mateizel, De Temmerman et al. 2006) may be considered as perfect cellular replicas of those diseases, as they exhibit the exact genotypes associated to them. Here, we confirm this hypothesis by demonstrating that the cell progeny of an ES cell line derived from an embryo with myotonic dystrophy type 1 (DM1) displayed the morphological stigma associated to the expression of the mutant gene –so-called intranuclear foci- as well as abnormal alternate splicing of the insulin receptor, a characteristic feature of DM1. Further differential transcriptomic analysis of the DM1 gene-carrying cells with phenotypically similar populations from native ES cell lines revealed abnormal expression of 89 genes, among which 48 were down-regulated and 39 over-expressed. This study demonstrates that DM1, though a disease with relatively late clinical onset, is associated with expression of genetic defects early on during development. It underlines the value of PGD-derived ES cell lines as a tool to decipher molecular mechanisms of genetic diseases. Ben-Nun, I. F. and N. Benvenisty (2006). Human embryonic stem cells as a cellular model for human disorders. Mol Cell Endocrinol 252(1-2): 154-9. Lerou, P. H. and G. Q. Daley (2005). Therapeutic potential of embryonic stem cells. Blood Rev 19(6): 321-31. Martinat, C., S. Shendelman, et al. (2004). Sensitivity to oxidative stress in DJ-1-deficient dopamine neurons: an ES- derived cell model of primary Parkinsonism. PLoS Biol 2(11): e327. Mateizel, I., N. De Temmerman, et al. (2006). Derivation of human embryonic stem cell lines from embryos obtained after IVF and after PGD for monogenic disorders. Hum Reprod 21(2): 503-11. Pickering, S. J., S. L. Minger, et al. (2005). Generation of a human embryonic stem cell line encoding the cystic fibrosis mutation deltaF508, using preimplantation genetic diagnosis. Reprod Biomed Online 10(3): 390-7. Smith, A. G. (2001). Embryo-derived stem cells: of mice and men. Annu Rev Cell Dev Biol 17: 435-62. Trounson, A. (2006). The production and directed differentiation of human embryonic stem cells. Endocr Rev 27(2): 208-19. Keywords: disease state analysis Two controls cell lines (VUB01 and SA01) and one mutant cell line (VUB03_DM1), with three biological replicats for each

Project description:Transcriptional profiling of XiGFP Epiblast Stem Cells (EpiSCs) overexpressing Klf2, Prdm14, Prdm14+Klf2, or vector control. Cells cultured in activin and bFGF (day 0) or on day 2 and day 4 after transfer to serum and LIF on feeder cells and sorting for dsRed expression to remove feeder cells.

Project description:After thawing, the mechanism of apoptosis advancing in human ES cells was invesitigated mainly by Gene conpath analysis. As time passed after thawing, nuclear fragmented cells increased more and more in cR-/mR- and cR+/mR-, but in cR+/mR+ and cR-/mR+, thawed cells formed cluster markedly, which was seen among three cell lines. Flow cytometry using TUNEL assay supported final colony formation ratio, which defined that such cell death was due to apoptosis. Gene map analysis 12 hours later after thawing of cR-/mR- showed activation of IL-1? & its receptor IL-1R and TGF-? & its receptor ACVR1C required for activation of caspase-8, initiation of caspase-8 and 10 and marked activation of ARHGDIB promoting actin reorganization comparing to cR+/mR+. Recovered cell lines in any condition did not lose proliferation and pluripotency regardless of ROCK inhibitor treatment.?These results showed apoptotic events after thawing were more marked in cR- and advanced through autoenhanced cascaded mechanism followed by initiation of self-cytokain activity, and were suppressed by ROCK inhibitor Y-27632. To investigate the protective mechanism caused by a novel cryo-technique of human embryonic stem (hES) cells using ROCK inhibitor Y-27632 against the cell death due to cryopreservation and thawing with Gene map analysis in addition to estimations of survival rate, apoptosis, undifferentiated states and pluripotency, the dissociated hES cells were cryopreserved in a freezing container in the following four conditions: addition of 10µM of Y-27632 to 1: cryoprotection solution and post-thawing medium (cR+/mR+), 2: only addition to cryoprotection (cR+/mR-), 3: only addition to post-thawing medium (cR-/mR+), 4: no addition to any medium (cR-/mR-).