Project description:global gene expression were compared among human blood iPSC, human fibroblas iPSC, human embryonic stem cells, human bone marrow MNC and human forskin fibroblast Reprogramming blood cells to induced pluripotent stem cells (iPSCs) provides a novel tool for modeling blood diseases in vitro. we demonstrated that iPSCs free of transgene and vector sequences could be efficiently generated from human bone marrow and cord blood mononuclear cells using non-integrating episomal vectors. The reprogramming described here is up to 100 times more efficient, occurs 1 to 3 weeks faster as compared to the reprogramming of fibroblasts, and does not require isolation of progenitors or multiple rounds of transfection. This approach provides an opportunity to explore banked normal and diseased cord blood and bone marrow samples without the limitations associated with virus-based methods.

Project description:global gene expression were compared among human blood iPSC, human fibroblas iPSC, human embryonic stem cells, human bone marrow MNC and human forskin fibroblast Reprogramming blood cells to induced pluripotent stem cells (iPSCs) provides a novel tool for modeling blood diseases in vitro. we demonstrated that iPSCs free of transgene and vector sequences could be efficiently generated from human bone marrow and cord blood mononuclear cells using non-integrating episomal vectors. The reprogramming described here is up to 100 times more efficient, occurs 1 to 3 weeks faster as compared to the reprogramming of fibroblasts, and does not require isolation of progenitors or multiple rounds of transfection. This approach provides an opportunity to explore banked normal and diseased cord blood and bone marrow samples without the limitations associated with virus-based methods. Compare the global gene expression of iPSs from different sources, ESCs and Somatic cells

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Project description:Reprogramming of somatic cells provides potential for the generation of specific cell types, which could be a key step in the study and treatment of human diseases. In vitro reprogramming of somatic cells into a pluripotent embryonic stem (ES) cellM-bM-^@M-^Slike state has been reported by retroviral transduction of murine fibroblasts using four embryonic transcription factors or through cell fusion of somatic and pluripotent stem cells. The generation of reprogrammed pluripotent cells using a somatic cell donor source such as bone marrow (BM) or peripheral blood is of particular therapeutic interest because of the relative ease of harvesting these cell types. Here we show that mouse adult BM mononuclear cellsM-oM-<M-^HBM MNCsM-oM-<M-^Iare competent as donor cells and can be reprogrammed into pluripotent ES cell-like cells. We isolated BM MNCs and embryonic fibroblasts (MEFs) from Oct4-EGFP transgenic mice, fused them with ES cells and infected them with retroviruses expressing Oct4, Sox2, Klf4, and c-Myc. Fused BM cells formed more ES-like colonies than did MEFs. Infected BM cells gave rise to iPS cells, although transduction efficiencies were not high. It was more efficient to pick up iPS colonies as compared with MEFs. BM-derived iPS (BM iPS) cells expressed embryonic stem cell markers, formed teratomas, and contributed to chimera mice with germline development. Clonal analysis revealed that BM iPS clones had diversity, although some clones were found to be genetically identical with different phenotypes. Here we demonstrate, for the first time, the induction of pluripotent cells directly from hematopoietic tissue. Gene expression profiling was performed in mouse BMMNCs, ES and BMMNC derived iPS cell lines.

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