Project description:Human ES cells (hESCs) and human induced pluripotent stem cells (hiPSCs) are usually generated and maintained on living feeder cells like mouse embryonic fibroblasts or on a cell-free substrate like Matrigel. For clinical applications, a quality-controlled, xenobiotic-free culture system is required to minimize risks from contaminating animal-derived pathogens and immunogens. We previously reported that the pericellular matrix of decidua-derived mesenchymal cells (PCM-DM) is an ideal human-derived substrate on which to maintain hiPSCs/hESCs. In this study, we examined whether PCM-DM could be used for the generation and long-term stable maintenance of hiPSCs. Decidua-derived mesenchymal cells (DMCs) were reprogrammed by the retroviral transduction of four factors (OCT4, SOX2, KLF4, c-MYC) and cultured on PCM-DM. The established hiPSC clones expressed alkaline phosphatase, hESC-specific genes and cell-surface markers, and differentiated into three germ layers in vitro and in vivo. At over 20 passages, the hiPSCs cultured on PCM-DM held the same cellular properties with genome integrity as those at early passages. Global gene expression analysis showed that the GDF3, FGF4, UTF1, and XIST expression levels varied during culture, and GATA6 was highly expressed under our culture conditions; however, these gene expressions did not affect the cellsM-bM-^@M-^Y pluripotency. PCM-DM can be conveniently prepared from DMCs, which have a high proliferative potential. Our findings indicate that PCM-DM is a versatile and practical human-derived substrate that can be used for the feeder-cell-free generation and long-term stable maintenance of hiPSCs. Keywords: Induced pluripotent stem cells; Extracellular matrix; Decidua; Mesenchymal cells The microarray study was carried out using Affymetrix Human Genome U133 Plus 2.0 gene expression arrays. Total RNA was extracted from cells with RNeasy (Qiagen), and 100ng of total RNA was used to synthesize aRNA using the 3M-bM-^@M-^Y IVT Express Kit, according to the manufacturerM-bM-^@M-^Ys instructions (Affymetrix Inc., Santa Clara, CA). After aRNA purification, 15 M-NM-<g of aRNA was fragmented and hybridized with a pre-equilibrated GeneChip array (Human Genome U133 Plus 2.0 gene expression array, Affymetrix) at 45M-BM-0C for 16 hours. The GeneChip array was then washed, stained, and scanned according to the manufacturerM-bM-^@M-^Ys instructions. The gene expression data were extracted using Affymetrix Expression Console software.

Project description:Generation and maintenance of hiPSCs on PCM-DM

Project description:We developed simple, robust, efficient, and serum-free/feeder-free induction protocol for neural crest cells from human pluripotent stem cells. To characterize the hNCCs and hNCC-derived MSCs, we performed gene expression profiling experiments. Comparison of gene expressions among hiPSCs, hESCs, hNCCs and hNC-MSCs

Project description:Skeletal muscle research is transitioning towards 3D tissue engineered in vitro models reproducing muscle’s native architecture and supporting measurement of functionality. Human induced pluripotent stem cells (hiPSCs) offer high yields of cells for differentiation. It has been difficult to differentiate high quality, pure 3D muscle tissues from hiPSCs that show contractile properties comparable to primary myoblast-derived tissues. Here, we present a transgene-free method for the generation of purified, expandable myogenic progenitors (MPs) from hiPSCs grown under feeder-free conditions. We defined a protocol with optimal hydrogel and medium conditions that allowed production of highly contractile 3D tissue engineered skeletal muscles with forces similar to primary myoblast-derived tissues. Gene expression and proteomic analysis between hiPSC-derived and primary myoblast-derived 3D tissues revealed a similar expression profile of proteins involved in myogenic differentiation and sarcomere function. The protocol should be generally applicable for the study of personalized human skeletal muscle tissue in health and disease.

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:The self-renewal and differentiation capacities of human pluripotent stem cells (hPSCs) make them good sources of cells for cell transplantation therapy, drug development, and studies of cellular differentiation and development. However, the large numbers of cells necessary for many of these applications require extensive expansion of hPSC cultures, a process that has been associated with genetic and epigenetic alterations. We have performed a combinatorial study on both hESCs and hiPSCs to compare the effects of enzymatic vs. mechanical passaging, and feeder-free vs. mouse embryonic fibroblast feeder substrate, to on the genetic and epigenetic stability and the phenotypic characteristics of hPSCs. In extensive experiments in hEScs involving over 100 continuous passages, , we observed that both enzymatic passaging and feeder-free culture were associated with genetic instability, higher cell proliferation, and persistence of OCT4-positive cells in teratomas, with enzymatic passaging having the stronger effect. In all combinations of culture conditions except for mechanical passaging on feeder layers, we noted recurrent deletions in the genomic region containing the tumor suppressor gene TP53, which was associated with decreased mRNA expression of TP53, as well as alterations in the expression of several downstream genes consistent with a decrease in the activity of the TP53 pathway. Among the hESC cultures, we also observedculture-dependent variations in global gene expression and DNA methylation. Verification of the negative effects of enzymatic passaging and feeder-free conditions was performed in hiPSC cultures. Our results highlight the need for careful assessment of effects of culture conditions on cells intended for clinical therapies. Three independent hiPSC clones reprogrammed from human fetal dermal fibroblasts: HDF51iPS1, HDF51iPS7, and HDF51iPS11.

Project description:The self-renewal and differentiation capacities of human pluripotent stem cells (hPSCs) make them good sources of cells for cell transplantation therapy, drug development, and studies of cellular differentiation and development. However, the large numbers of cells necessary for many of these applications require extensive expansion of hPSC cultures, a process that has been associated with genetic and epigenetic alterations. We have performed a combinatorial study on both hESCs and hiPSCs to compare the effects of enzymatic vs. mechanical passaging, and feeder-free vs. mouse embryonic fibroblast feeder substrate, to on the genetic and epigenetic stability and the phenotypic characteristics of hPSCs. In extensive experiments in hEScs involving over 100 continuous passages, , we observed that both enzymatic passaging and feeder-free culture were associated with genetic instability, higher cell proliferation, and persistence of OCT4-positive cells in teratomas, with enzymatic passaging having the stronger effect. In all combinations of culture conditions except for mechanical passaging on feeder layers, we noted recurrent deletions in the genomic region containing the tumor suppressor gene TP53, which was associated with decreased mRNA expression of TP53, as well as alterations in the expression of several downstream genes consistent with a decrease in the activity of the TP53 pathway. Among the hESC cultures, we also observedculture-dependent variations in global gene expression and DNA methylation. Verification of the negative effects of enzymatic passaging and feeder-free conditions was performed in hiPSC cultures. Our results highlight the need for careful assessment of effects of culture conditions on cells intended for clinical therapies.

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:While feeder-free generation of clinical grade iPSC-derived CD8 T cells has been achieved, differentiation of iPSC-derived CD4sp and regulatory T cells requires mouse stromal cells in an artificial thymic organoid. We developed a serum- and feeder-free differentiation process suitable for large-scale production and used scRNAseq to study the cell identity of the iPSC-derived cells and compared their transcriptional profile to primary human cells.

Project description:The objective of this study was to reprogram peripheral blood-derived late-endothelial progenitor cells (EPCs) to a pluripotent state under feeder-free and defined culture conditions. Late-EPCs were retrovirally-transduced with OCT4, SOX2, KLF4, c-MYC, and iPSC colonies were derived in feeder-free and defined media conditions. EPC-iPSCs expressed pluripotent markers, were capable of differentiating to cells from all three germ-layers, and retained a normal karyotype. Transcriptome analyses demonstrated that EPC-iPSCs exhibit a global gene expression profile similar to human embryonic stem cells (hESCs). We have generated iPSCs from late-EPCs under feeder-free conditions. Thus, peripheral blood-derived late-outgrowth EPCs represent an alternative cell source for generating iPSCs.