Project description:Establishment of stably expandable induced myogenic stem cells by defined factors

Project description:Direct Conversion of Fibroblasts into Oligodendrocyte Progenitor Cells

Project description:Direct Reprogramming of Fibroblasts into Neural Stem Cells by Defined Factors

Project description:Recent advances in direct reprogramming using cell type-specific transcription factors provide an unprecedented opportunity for rapid generation of desired human cell types from easily accessible tissues. However, due to the diversity of conversion factors that facilitate the process, an arduous screening step is inevitable to find the appropriate combination(s). Here, we show that under chemically defined conditions minimal pluripotency factors are sufficient to directly reprogram human fibroblasts into stably self-renewing neural progenitor/stem cells (NSCs), but without passing through a pluripotent intermediate stage. These NSCs can be expanded and propagated in vitro without losing their potential to differentiate into various neuronal subtypes and glia. Our direct reprogramming strategy represents a simple and advanced paradigm of direct conversion that will provide an unlimited source of human neural cells for cell therapy, disease modeling, and drug screening. We used microarray to compare the global gene expression pattern between human fibroblasts and human neural epitheliums from human ESCs or directly from fibroblasts. We cultured cells and harvested them and then extracted total RNA for microarray.

Project description:Generation of neural crest cells by direct lineage conversion

Project description:Direct conversion of mouse fibroblasts into cholangiocyte progenitor cells

Project description:Recent advances in direct reprogramming using cell type-specific transcription factors provide an unprecedented opportunity for rapid generation of desired human cell types from easily accessible tissues. However, due to the diversity of conversion factors that facilitate the process, an arduous screening step is inevitable to find the appropriate combination(s). Here, we show that under chemically defined conditions minimal pluripotency factors are sufficient to directly reprogram human fibroblasts into stably self-renewing neural progenitor/stem cells (NSCs), but without passing through a pluripotent intermediate stage. These NSCs can be expanded and propagated in vitro without losing their potential to differentiate into various neuronal subtypes and glia. Our direct reprogramming strategy represents a simple and advanced paradigm of direct conversion that will provide an unlimited source of human neural cells for cell therapy, disease modeling, and drug screening. We used microarray to compare the global gene expression pattern between human fibroblasts and human neural epitheliums from human ESCs or directly from fibroblasts.

Project description:Recent advances have suggested that direct induction of neural stem cells could provide an alternative to derivation from somatic tissues or pluripotent cells. Here we show direct derivation of stably expandable NS cells from mouse fibroblasts through a curtailed version of reprogramming to pluripotency. By constitutively inducing Sox2, Klf4, and c-Myc while strictly limiting Oct4 activity to the initial phase of reprogramming, we generated neurosphere-like colonies that could be expanded for more than 50 passages and do not depend on sustained expression of the reprogramming factors. These induced NS (iNS) cells uniformly display morphological and molecular features of NS cells such as the expression of Nestin, Pax6, and Olig2 and have a similar genome-wide transcriptional profile to brain-derived NSCs. iNS cells can differentiate into neurons, astrocytes and oligodendrocytes in vitro and in vivo. Our results demonstrate that functional neural stem cells can be generated from somatic cells by factor-driven induction. mRNA extracted from Murine Embryonic Fibroblasts (MEF), murine Embryonic Stem Cell (ES), murine Neuronal Stem Cell (NS) and three murine induces Neuronal Stem Cell clones 2, 3 and 5 (iNS2, iNS3, iNS5) has been hybridized on Illumina MouseWG6 V2 arrays for genome wide expression analysis. Samples were run at least as triple, MEF, iNS3, iNS5 as quadruple technical replicates. Differential gene expression analysis has been performed on the grouped expression data with the Murine Embryonic Fibroblasts group as the reference.

Project description:Direct Conversion of Trophoblast Stem Cells into Pluripotent Stem Cells by Oct4

Project description:Conversion of Fibroblasts into Functional Trophoblast Stem-like Cells