Project description:Like embryonic stem cells, induced pluripotent stem cells (iPSCs) can differentiate into all three germ layers in an in vitro system. Here, we developed a new technology for obtaining neural stem cells (NSCs) from iPSCs through chimera formation, in an in vivo environment. iPSCs contributed to the neural lineage in the chimera, which could be efficiently purified and directly cultured as NSCs in vitro. The iPSC-derived, in vivo-differentiated NSCs expressed NSC markers, and their gene-expression pattern more closely resembled that of brain-derived NSCs than in vitro-differentiated NSCs. This system could be applied for differentiating pluripotent stem cells into specialized cell type whose differentiation protocols are not well established.

Project description:Congenital heart defects (CHDs) are very frequent in children with Down syndrome (DS), the genetic condition caused by trisomy of chromosome 21 (T21). However, the mechanisms by which T21 causes susceptibility to CHDs are poorly understood. Here, using a combination of human induced pluripotent stem cell (iPSC)-based model and Dp(16)1Yey/+ (Dp16) a mouse model of DS, we identified downregulation of canonical Wnt signaling that is caused by increased dosage of interferon (IFN) receptors encoded on chromosome 21 (HSA21) as a causative factor of CHDs in DS. We differentiated human iPSCs derived from individuals with DS as well as CHDs (DS/CHD iPSCs), and controls (control iPSCs) into cardiac cells. We observed that T21 upregulates IFN signaling, downregulates the canonical WNT pathway, and impairs cardiac differentiation. Furthermore, genetic and pharmacological normalization of IFN pathways restored canonical WNT signaling and rescued defects during cardiac differentiation of DS/CHD iPSCs. Strikingly, treatment with an inhibitor of Janus kinase, which is activated by IFN receptor engagement normalized the canonical Wnt pathway and ameliorated CHDs in Dp16 embryos. Our findings provide new mechanisms underlying CHDs in DS, ultimately aiding the development of novel therapeutic strategies.

Project description:The differentiation capability of induced pluripotent stem cells (iPSCs) towards certain cell types for disease modelling and drug screening assays might be influenced by their somatic cell of origin. Here, we have compared the neural induction of human iPSCs generated from either fetal neural stem cells (fNSCs), dermal fibroblasts or CD34+ hematopoietic stem cells. Neural progenitor cells (NSCs) and neurons could be generated at similar efficiencies from all iPSCs. Whole genome transcriptome analysis and an expression analysis of neural genes in iPSC-derived NSCs revealed a separation of neuroectoderm- from mesoderm-derived cells. Furthermore, we found genes, which were similarly expressed between fNSCs and neuroectoderm- but not mesoderm-derived NSCs. Notably, these neural signatures were retained after transplantation into the cortex of mice and paralleled with increased survival and integration of neuroectoderm-derived cells in vivo. These results indicated distinct origin- dependent neural cell identities in differentiated human iPSCs both in vitro and in vivo.

Project description:Fanconi Anemia (FA) is a recessive disorder associated with genomic instability We generated iPSC from FA patient fibroblasts and further corrected the mutated FANCA gene with a homologous recombination-based approach. The NSCs were differentiated from control-iPSCs, FA-iPSCs, and corrected FA-NSCs, and their gene expressions were determined by microarray analysis.

Project description:Background: Hepatocyte-like cells (HLCs) differentiated from induced pluripotent stem cells (iPSCs) have emerged as a promising cell culture model to study metabolism, biotransformation, viral infections and genetic liver diseases. However the derivation of iPSCs is restricted by ethical and procedural constraints. Furthermore, incomplete HLC differentiation remains a major challenge. iPSC may carry-on a tissue of origin dependent expression memory influencing iPSC differentiation into different cell types. If liver derived iPSCs (Li-iPSCs) maintain a liver specific gene expression profile is not known. It is also not known, if Li-iPSCs would allow the generation of more fully differentiated HLCs.Methods: Primary liver cells (PLCs) were expanded from liver needle biopsies and reprogrammed into Li-iPSCs using a non-integrative Sendai virus-based system. Li-iPSCs were differentiated into HLCs using established differentiation protocols. The HLC phenotype was characterized at the protein, functional and transcriptional level. RNA sequencing data were generated from the originating liver biopsies, the Li-iPSCs, fibroblast derived iPSCs, and differentiated HLCs, and used to characterize and compare their transcriptome profiles.Results: PLCs were obtained from small pieces of liver biopsies and could be reprogrammed into Li-iPSCs. Li-iPSCs indeed retain a liver specific transcriptional footprint. Li-iPSCs can be propagated to provide an unlimited supply of cells for differentiation into Li-HLCs. Similar to HLCs derived from fibroblasts, Li-HLCs could not be fully differentiated into hepatocytes. Relative to the originating liver, Li-HLCs showed lower expression of liver specific transcription factors and increased expression of genes involved in the differentiation of other tissues.Conclusions: PLCs and Li-iPSCs obtained from small pieces of human needle liver biopsies constitute a novel unlimited source for the production of HLCs. Despite the preservation of a liver specific gene expression footprint in Li-iPSCs, the generation of fully differentiated hepatocytes cannot be achieved with the current differentiation protocols.

Project description:Brief expression of pluripotency-associated factors such as OCT4, KLF4, SOX2 and c-MYC (OKSM), in combination with differentiation-inducing signals, was reported to trigger transdifferentiation of fibroblasts into alternative cell types. Here, we show that OKSM expression gives rise to both induced pluripotent stem cells (iPSCs) and iNSCs under conditions that were previously shown to induce only NSC transdifferentiation. Fibroblast-derived iNSC colonies silenced retroviral transgenes and reactivated silenced X chromosomes, both hallmarks of pluripotent stem cells. Moreover, lineage tracing via an Oct4-CreER labeling system demonstrated that virtually all iNSC colonies originate from cells transiently expressing Oct4, whereas ablation of Oct4-positive cells prevented iNSC formation. Lastly, use of an alternative transdifferentiation cocktail that lacks OCT4 and was reportedly unable to support induced pluripotency, yielded iPSCs and iNSCs carrying the Oct4-CreER-derived lineage label. Together, these data suggest that iNSC generation using OKSM and related reprogramming factors requires passage through a transient iPSC state. 5 samples were anlyzed in total, 2 induced pluripotent stem cells (iPSCs), 1 neural stem cells (NSCs) and 2 induced NSCs (iNSCs)

Project description:Transcriptional profiling of Human ESCs vs Human iPSCs, Human NSCs-ES vs Human NSCs-iPS iPSCs generated by using different method, and are not very good at Neural differentiation comapred with Human ESCs

Project description:The clinical translation of induced pluripotent stem cells (iPSCs) holds great potential for personalized therapeutics. However, the current workflow to generate iPSCs is expensive, time-consuming, and requires standardization. We present a simplified microfluidic approach for reprogramming fibroblasts into iPSCs and their subsequent differentiation into neural stem cells (NSCs). Our method exploits microphysiological technology, providing a 100-fold reduction in reagents for reprogramming and a 9-fold reduction in number of input cells. The iPSCs generated from microfluidic reprogramming of fibroblasts show upregulation of pluripotency markers and downregulation of fibroblast markers, on par with those reprogrammed in the standardized well-conditions. The NSCs differentiated in microfluidic chips show upregulation of neuroectodermal markers (ZIC1, PAX6, SOX1), highlighting their propensity for nervous system development. We then compare the cells obtained on conventional well plates and microfluidic chips for reprogramming and neural induction by bulk RNA sequencing. Pathway enrichment analysis of NSCs generated in the chip showed neural stem cell development enrichment and boosted commitment to the neural stem cell lineage in the initial phases of neural induction, attributed to the confined environment in a microfluidic chip. This method provides a cost-effective pipeline to reprogram and differentiate iPSCs which can be made compliant with the current good manufacturing practices for therapeutics.

Project description:we identified gene-expression changes in induced pluripotent stem cells (iPSCs) and iPSC-derived neural stem cells (NSCs) from a patients with GLD (K-iPSCs/NSCs) and normal control (AF-iPSCs/NSCs), in order to investigate the potential mechanism underlying GLD pathogenesis. We identified 194 (K-iPSCs vs. AF-iPSCs) and 702 (K-NSCs vs. AF-NSCs) significantly dysregulated mRNAs when comparing the indicated groups. We also identified dozens of Gene Ontology and Kyoto Encyclopedia of Genes and Genomes pathway terms that were enriched for the differentially expressed genes.

Project description:Down syndrome (DS) is the most frequent cause of human congenital mental retardation. Cognitive deficits in DS result from perturbations of normal cellular processes both during development and in adult tissues, but the mechanisms underlying DS etiology remain poorly understood. To assess the ability of iPSCs to model DS phenotypes, as a prototypical complex human disease, we generated bona-fide DS and wild-type (WT) non-viral iPSCs by episomal reprogramming. DS iPSCs selectively overexpressed chromosome 21 genes, consistent with gene dosage, which was associated with deregulation of thousands of genes throughout the genome. DS and WT iPSCs were neurally converted at >95% efficiency, and had remarkably similar lineage potency, differentiation kinetics, proliferation and axon extension at early time points. However, at later time points DS cultures showed a two-fold bias towards glial lineages. Moreover, DS neural cultures were up to two times more sensitive to oxidative stress induced apoptosis, and this could be prevented by the anti-oxidant N-acetylcysteine. Our results reveal a striking complexity in the genetic alterations caused by trisomy-21 that are likely to underlie DS developmental phenotypes, and indicate a central role for defective early glial development in establishing developmental defects in DS brains. Furthermore, oxidative stress sensitivity is likely to contribute to the accelerated neurodegeneration seen in DS, and we provide proof of concept for screening corrective therapeutics using DS iPSCs and their derivatives. Non-viral DS iPSCs can therefore recapitulate features of complex human disease in vitro, and provide a renewable and ethically unencumbered discovery platform. Control (WT) and Down Syndrome iPSC lines were generated via episomal reprogramming of human donor fibroblasts. Two iPSC clones conforming to iPS criteria (determined by immunocytochemistry detection of pluripotency markers) were developed from each fibroblast donor. Two control (WT) and DS lines each were further characterized and underwent neural differentiation. Multiple biological replicates of donor fibroblast and iPSC from both control (WT) and DS lines, including 3 euploid DS samples and 3 MEL1 hESC controls (total 54 samples) were hybridized to Illumina HT-12 v4 microarray for gene expression analysis.