Project description:Hepatocytes generated from human induced pluripotent stem cells (hiPSCs) are unprecedented resources for pharmaceuticals and cell therapy. However, little attention has so far been paid to variations among hiPSC lines in terms of their hepatic differentiation. We developed an improved hepatic differentiation protocol and compared multiple hiPSC lines. This comparison indicated that the hepatic differentiation propensity varies among sibling hiPSC clones derived from the same adult human dermal fibroblasts (aHDFs). In addition, hiPSC clones derived from peripheral blood cells (PB-iPSCs) consistently showed good hepatic differentiation efficiency, whereas many hiPSC clones from adult dermal fibroblasts (aHDF-iPSCs) showed poor hepatic differentiation. However, when we compared hiPSCs from blood and dermal fibroblasts from the same individuals, we found that variations in hepatic differentiation were largely attributable to donor differences, rather than to the types of the original cells. In order to understand the molecular mechanisms underlying the observed variations in hepatic differentiation, we performed microarray analyses of sibling aHDF-iPSC clones, and aHDF- and PB-iPSC clones from the same individuals. Undifferentiated aHDF- and PB-iPSCs from the same individuals (two Parkinson’s disease patients (PD #1 and PD #2) and one adult healthy donor (donor91))

Project description:Human induced pluripotent stem cells (hiPSCs) are useful as a tool for reproducing neural development in vitro. However, each hiPSC line has a different ability to differentiate into specific lineages, as known as differentiation propensity, resulting in reduced reproducibility and increased time and cost requirements for research use. To overcome this issue, we searched for predictive signatures of neural differentiation propensity of hiPSCs using DNA methylation which is the main modulator of cellular properties. We obtained 32 lines of hiPSC and its comprehensive DNA methylation data by Infinium MethylationEPIC beadchip. To assess the neural differentiation efficiency of these hiPSCs, we measured the percentage of PAX6-positive cells on day 7 of neural stem cell induction by the dual-SMAD inhibition protocol. Using DNA methylation data of undifferentiated hiPSCs and their measured differentiation efficiency into neural stem cells as the set of data, and HSIC Lasso, a machine learning-based nonlinear feature selection method, we attemted to identify neural differentiation associated differentially methylated sites. Epigenome-wide unsupervised clustering could not distinguish between hiPSCs with varying differentiation efficiency. On the other hand, HSIC Lasso identified 62 probes that can explain the neural differentiation efficiency of hiPSCs. Selected features by HSIC Lasso were particularly enriched within the 3 Mbp on chromosome 5, harboring the IRX2, C5orf38, and IRX1 genes. Within this region, DNA methylation rates were correlated with neural differentiation efficiency particular to female hiPSCs and negatively correlated with gene expression of the IRX1/2 genes. In addition, forced expression of the IRX1/2 genes impaired the neural differentiation ability of hiPSCs. We have shown for the first time that DNA methylation state on the IRX1/2 genes of hiPSCs is predictive biomarker of their ability for neural differentiation. The predictive markers for neural differentiation efficiency identified in this study can be useful for selection of suitable undifferetiated hiPSCs prior to differentiation induction.

Project description:Human induced pluripotent stem cells (hiPSCs) are useful as a tool for reproducing neural development in vitro. However, each hiPSC line has a different ability to differentiate into specific lineages, as known as differentiation propensity, resulting in reduced reproducibility and increased time and cost requirements for research use. To overcome this issue, we searched for predictive signatures of neural differentiation propensity of hiPSCs using DNA methylation which is the main modulator of cellular properties. We obtained 32 lines of hiPSC and its comprehensive DNA methylation data by Infinium MethylationEPIC beadchip. To assess the neural differentiation efficiency of these hiPSCs, we measured the percentage of PAX6-positive cells on day 7 of neural stem cell induction by the dual-SMAD inhibition protocol. Using DNA methylation data of undifferentiated hiPSCs and their measured differentiation efficiency into neural stem cells as the set of data, and HSIC Lasso, a machine learning-based nonlinear feature selection method, we attemted to identify neural differentiation associated differentially methylated sites. Epigenome-wide unsupervised clustering could not distinguish between hiPSCs with varying differentiation efficiency. On the other hand, HSIC Lasso identified 62 probes that can explain the neural differentiation efficiency of hiPSCs. Selected features by HSIC Lasso were particularly enriched within the 3 Mbp on chromosome 5, harboring the IRX2, C5orf38, and IRX1 genes. Within this region, DNA methylation rates were correlated with neural differentiation efficiency particular to female hiPSCs and negatively correlated with gene expression of the IRX1/2 genes. In addition, forced expression of the IRX1/2 genes impaired the neural differentiation ability of hiPSCs. We have shown for the first time that DNA methylation state on the IRX1/2 genes of hiPSCs is predictive biomarker of their ability for neural differentiation. The predictive markers for neural differentiation efficiency identified in this study can be useful for selection of suitable undifferetiated hiPSCs prior to differentiation induction.

Project description:The use of pluripotent stem cells in regenerative medicine and disease modeling is complicated by the variation in differentiation properties between lines. In this study, we characterized 13 human embryonic stem cell. (hESC) and 26 human induced pluripotent stem cell (hiPSC) lines to identify markers that predict neural differentiation behavior. At a general level, markers previously known to distinguish mouse ESCs from epiblast stem cells (EpiSCs) correlated with neural differentiation behavior. More specifically, quantitative analysis of miR-371-3 expression prospectively identified hESC and hiPSC lines with differential neurogenic differentiation propensity and in vivo dopamine neuron engraftment potential. Transient KLF4 transduction increased miR-371-3 expression and altered neurogenic behavior and pluripotency marker expression. Conversely, suppression of miR- 371-3 expression in KLF4-transduced cells rescued neural differentiation propensity. miR-371-3 expression level therefore appears to have both a predictive and a functional role in determining human pluripotent stem cell neurogenic differentiation behavior. [mRNA profiling (Illumina)]: Four human ESC lines (H9, I4, I6, HUES6) at undifferentiation stages were purified with stem cell surface marker SSEA4 and subjected to RNA extraction and hybridization on Illumina microarrays. Each sample has 3 biological repeats, one of which has two technical repeats. [miRNA profiling (Agilent)]: Four human ESC lines (H9, I4, I6, HUES6) at undifferentiation stages were purified with stem cell surface marker SSEA4 and subjected to RNA extraction and hybridization on Agilent microarrays. Each sample has 3 biological repeats, one of which has two technical repeats.

Project description:Hepatocytes generated from human induced pluripotent stem cells (hiPSCs) are unprecedented resources for pharmaceuticals and cell therapy. However, little attention has so far been paid to variations among hiPSC lines in terms of their hepatic differentiation. We developed an improved hepatic differentiation protocol and compared multiple hiPSC lines. This comparison indicated that the hepatic differentiation propensity varies among sibling hiPSC clones derived from the same adult human dermal fibroblasts (aHDFs). In addition, hiPSC clones derived from peripheral blood cells (PB-iPSCs) consistently showed good hepatic differentiation efficiency, whereas many hiPSC clones from adult dermal fibroblasts (aHDF-iPSCs) showed poor hepatic differentiation. However, when we compared hiPSCs from blood and dermal fibroblasts from the same individuals, we found that variations in hepatic differentiation were largely attributable to donor differences, rather than to the types of the original cells. In order to understand the molecular mechanisms underlying the observed variations in hepatic differentiation, we performed microarray analyses of sibling aHDF-iPSC clones, and aHDF- and PB-iPSC clones from the same individuals. sibling aHDF-iPSC clones (201B6 and 201B7; derived from the same aHDFs) (1) undifferentiated state (n=4, biological replicate #1-#4) (2) CXCR4-positive cell populations sorted by flowcytometry after 7 days of endodermal differentiation (n=4, biological replicate #1-#4) (3) CXCR4-negative cell populations sorted by flowcytometry after 7 days of endodermal differentiation (n=4, biological replicate #1-#4)

Project description:The use of pluripotent stem cells in regenerative medicine and disease modeling is complicated by the variation in differentiation properties between lines. In this study, we characterized 13 human embryonic stem cell. (hESC) and 26 human induced pluripotent stem cell (hiPSC) lines to identify markers that predict neural differentiation behavior. At a general level, markers previously known to distinguish mouse ESCs from epiblast stem cells (EpiSCs) correlated with neural differentiation behavior. More specifically, quantitative analysis of miR-371-3 expression prospectively identified hESC and hiPSC lines with differential neurogenic differentiation propensity and in vivo dopamine neuron engraftment potential. Transient KLF4 transduction increased miR-371-3 expression and altered neurogenic behavior and pluripotency marker expression. Conversely, suppression of miR- 371-3 expression in KLF4-transduced cells rescued neural differentiation propensity. miR-371-3 expression level therefore appears to have both a predictive and a functional role in determining human pluripotent stem cell neurogenic differentiation behavior.

Project description:Hepatocytes generated from human induced pluripotent stem cells (hiPSCs) are unprecedented resources for pharmaceuticals and cell therapy. However, little attention has so far been paid to variations among hiPSC lines in terms of their hepatic differentiation. We developed an improved hepatic differentiation protocol and compared multiple hiPSC lines. This comparison indicated that the hepatic differentiation propensity varies among sibling hiPSC clones derived from the same adult human dermal fibroblasts (aHDFs). In addition, hiPSC clones derived from peripheral blood cells (PB-iPSCs) consistently showed good hepatic differentiation efficiency, whereas many hiPSC clones from adult dermal fibroblasts (aHDF-iPSCs) showed poor hepatic differentiation. However, when we compared hiPSCs from blood and dermal fibroblasts from the same individuals, we found that variations in hepatic differentiation were largely attributable to donor differences, rather than to the types of the original cells. In order to understand the molecular mechanisms underlying the observed variations in hepatic differentiation, we performed microarray analyses of sibling aHDF-iPSC clones, and aHDF- and PB-iPSC clones from the same individuals.

Project description:Hepatocytes generated from human induced pluripotent stem cells (hiPSCs) are unprecedented resources for pharmaceuticals and cell therapy. However, little attention has so far been paid to variations among hiPSC lines in terms of their hepatic differentiation. We developed an improved hepatic differentiation protocol and compared multiple hiPSC lines. This comparison indicated that the hepatic differentiation propensity varies among sibling hiPSC clones derived from the same adult human dermal fibroblasts (aHDFs). In addition, hiPSC clones derived from peripheral blood cells (PB-iPSCs) consistently showed good hepatic differentiation efficiency, whereas many hiPSC clones from adult dermal fibroblasts (aHDF-iPSCs) showed poor hepatic differentiation. However, when we compared hiPSCs from blood and dermal fibroblasts from the same individuals, we found that variations in hepatic differentiation were largely attributable to donor differences, rather than to the types of the original cells. In order to understand the molecular mechanisms underlying the observed variations in hepatic differentiation, we performed microarray analyses of sibling aHDF-iPSC clones, and aHDF- and PB-iPSC clones from the same individuals.

Project description:Donor-dependent hepatic differentiation propensity among hiPSC lines.

Project description:It remains controversial whether human induced pluripotent stem cells (hiPSCs) are distinct from human embryonic stem cells (hESCs) in their molecular signatures and differentiation properties. We examined the gene expression and DNA methylation of 49 hiPSC and 10 hESC lines and identified no molecular signatures that distinguished hiPSCs from hESCs. Comparisons of the in vitro directed neural differentiation of 40 hiPSC and four hESC lines showed that most hiPSC clones were comparable to hESCs. However, in seven hiPSC clones, significant amount of undifferentiated cells persisted even after neural differentiation and resulted in teratoma formation when transplantated into mouse brains. These differentiation-defective hiPSC clones were marked by higher expression of several genes, including those expressed from long terminal repeats of human endogenous retroviruses. These data demonstrated that many hiPSC clones are indistinguishable from hESCs, while some defective hiPSC clones need to be eliminated prior to their application for regenerative medicine. Bisulphite converted DNA from 10 hESCs, 49 hiPSCs, 2 hECCs, 6 somatic cells and 3 cancer cell lines were hybridized to the Illumina Infinium 27k Human Methylation Beadchip.