Project description:Human induced pluripotent stem (iPS) cells are remarkably similar to embryonic stem (ES) cells, but recent reports indicate that there may be important differences between them. We carried out a systematic comparison of human iPS cells generated from hepatocytes (representative of endoderm), skin fibroblasts (mesoderm) and melanocytes (ectoderm). All low-passage iPS cells analysed retain a transcriptional memory of the original cells. The persistent expression of somatic genes can be partially explained by incomplete promoter DNA methylation. This epigenetic mechanism underlies a robust form of memory that can be found in iPS cells generated by multiple laboratories using different methods, including RNA transfection. Incompletely silenced genes tend to be isolated from other genes that are repressed during reprogramming, indicating that recruitment of the silencing machinery may be inefficient at isolated genes. Knockdown of the incompletely reprogrammed gene C9orf64 (chromosome 9 open reading frame 64) reduces the efficiency of human iPS cell generation, indicating that somatic memory genes may be functionally relevant during reprogramming. iPS cells were produced from melanocytes, fibroblasts, and hepatocytes, representing the three germ layers. Expression levels were profiled in the differentiated cells and their matched iPS cells, as well as 3 human ES cell lines (H1, H7 and H9) and their embroid bodies.

Project description:Human induced pluripotent stem (iPS) cells are remarkably similar to embryonic stem (ES) cells, but recent reports indicate that there may be important differences between them. We carried out a systematic comparison of human iPS cells generated from hepatocytes (representative of endoderm), skin fibroblasts (mesoderm) and melanocytes (ectoderm). All low-passage iPS cells analysed retain a transcriptional memory of the original cells. The persistent expression of somatic genes can be partially explained by incomplete promoter DNA methylation. This epigenetic mechanism underlies a robust form of memory that can be found in iPS cells generated by multiple laboratories using different methods, including RNA transfection. Incompletely silenced genes tend to be isolated from other genes that are repressed during reprogramming, indicating that recruitment of the silencing machinery may be inefficient at isolated genes. Knockdown of the incompletely reprogrammed gene C9orf64 (chromosome 9 open reading frame 64) reduces the efficiency of human iPS cell generation, indicating that somatic memory genes may be functionally relevant during reprogramming.

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Project description:Several studies have discussed the possibility that donor cell type may influence the epigenetics and differentiation potential of iPSCs, but it remains unclear whether iPS cells derived from different tissue sources reserve their epigenetic memory. Here, we clarify that iPSCs obtained from different tissues exhibit specific epigenetic patterns. We determined the DNA methylation profiles of 12 human cell lines, including 3 adult fibroblast cell-derived iPSC lines, 2 peripheral blood-derived mononuclear cell(PBMC)-derived iPSC lines, 2 amniotic cell-derived iPSC lines and the 5 corresponding parent cell lines. We found that the catalog of tissue-specific DNA methylation was preserved in the iPSC line as epigenetic memory during reprogramming.

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Project description: Not available