On the way to reprogramming cells to pluripotency using cell-free extracts.

The functional reprogramming of a differentiated cell to pluripotency may present beneficial applications in regenerative medicine. Somatic cell nuclear transfer may offer this possibility, but technical hurdles and ethical guidelines currently prevent application of this technology in several countries. As a result, alternative approaches are being developed for altering cell fate. Recent non-nuclear transfer-based approaches for reprogramming somatic cells are discussed as well as ways to enhance their differentiation potential. These approaches include the fusion of differentiated cells with embryonic stem cells and the use of extract from pluripotent cells to reprogramme differentiated cells into multipotent or pluripotent cells.

Epigenetic reprogramming of nuclei using cell extracts.

Recent evidence indicates that nuclear and cytoplasmic extracts from undifferentiated cells can reprogram gene expression and promote pluripotency in otherwise more developmentally restricted cell types. Notably, extracts of embryonal carcinoma cells or embryonic stem cells have been shown to elicit a shift in the transcriptional program of target cells to upregulate embryonic stem cell genes, downregulate somatic cell-specific markers, and epigenetically modify histones. Reprogrammed kidney epithelial cells acquire a potential for differentiation toward ectodermal and mesodermal lineages. Cell extract-mediated nuclear reprogramming may constitute an attractive alternative to reprogramming somatic cells by cell fusion or nuclear transfer. This review highlights recent observations leading to the concept that extracts derived from pluripotent cells contain regulatory components capable of reprogramming somatic nuclear function. Limitations of current extract-based reprogramming approaches are also addressed.

Induction of dedifferentiation, genomewide transcriptional programming, and epigenetic reprogramming by extracts of carcinoma and embryonic stem cells.

Functional reprogramming of a differentiated cell toward pluripotency may have long-term applications in regenerative medicine. We report the induction of dedifferentiation, associated with genomewide programming of gene expression and epigenetic reprogramming of an embryonic gene, in epithelial 293T cells treated with an extract of undifferentiated human NCCIT carcinoma cells. 293T cells exposed for 1 h to extract of NCCIT cells, but not of 293T or Jurkat T-cells, form defined colonies that are maintained for at least 23 passages in culture. Microarray and quantitative analyses of gene expression reveal that the transition from a 293T to a pluripotent cell phenotype involves a dynamic up-regulation of hundreds of NCCIT genes, concomitant with down-regulation of 293T genes and of indicators of differentiation such as A-type lamins. Up-regulated genes encompass embryonic and stem cell markers, including OCT4, SOX2, NANOG, and Oct4-responsive genes. OCT4 activation is associated with DNA demethylation in the OCT4 promoter and nuclear targeting of Oct4 protein. In fibroblasts exposed to extract of mouse embryonic stem cells, Oct4 activation is biphasic and RNA-PolII dependent, with the first transient rise of Oct4 up-regulation being necessary for the second, long-term activation of Oct4. Genes characteristic of multilineage differentiation potential are also up-regulated in NCCIT extract-treated cells, suggesting the establishment of "multilineage priming." Retinoic acid triggers Oct4 down-regulation, de novo activation of A-type lamins, and nestin. Furthermore, the cells can be induced to differentiate toward neurogenic, adipogenic, osteogenic, and endothelial lineages. The data provide a proof-of-concept that an extract of undifferentiated carcinoma cells can elicit differentiation plasticity in an otherwise more developmentally restricted cell type.

Long-term in vitro, cell-type-specific genome-wide reprogramming of gene expression.

We demonstrate a cell extract-based, genome-wide and heritable reprogramming of gene expression in vitro. Kidney epithelial 293T cells have previously been shown to take on T cell properties following a brief treatment with an extract of Jurkat T cells. We show here that 293T cells exposed for 1 h to a Jurkat cell extract undergo genome-wide, target cell-type-specific and long-lasting transcriptional changes. Microarray analyses indicate that on any given week after extract treatment, approximately 2500 genes are upregulated >3-fold, of which approximately 900 are also expressed in Jurkat cells. Concomitantly, approximately 1500 genes are downregulated or repressed, of which approximately 500 are also downregulated in Jurkat cells. Gene expression changes persist for over 30 passages ( approximately 80 population doublings) in culture. Target cell-type specificity of these changes is shown by the lack of activation or repression of Jurkat-specific genes by extracts of 293T cells or carcinoma cells. Quantitative RT-PCR analysis confirms the long-term transcriptional activation of genes involved in key T cell functions. Additionally, growth of cells in suspended aggregates, expression of CD3 and CD28 T cell surface markers, and interleukin-2 secretion by 293T cells treated with extract of adult peripheral blood T cells illustrate a functional nuclear reprogramming. Therefore, target cell-type-specific and heritable changes in gene expression, and alterations in cell function, can be promoted by extracts derived from transformed cells as well as from adult primary cells.