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Reprogramming cell fates: insights from combinatorial approaches
Author(s) -
Pereira CarlosFilipe,
Lemischka Ihor R.,
Moore Kateri
Publication year - 2012
Publication title -
annals of the new york academy of sciences
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.712
H-Index - 248
eISSN - 1749-6632
pISSN - 0077-8923
DOI - 10.1111/j.1749-6632.2012.06508.x
Subject(s) - reprogramming , cell potency , somatic cell , biology , cell type , transcription factor , totipotent , cellular differentiation , microbiology and biotechnology , cell , stem cell , computational biology , somatic cell nuclear transfer , epigenetics , cell fusion , genetics , adult stem cell , gene , embryo , blastocyst , embryogenesis
Epigenetic reprogramming can be achieved in different ways, including nuclear transfer, cell fusion, or the expression of transcription factors (TFs). Combinatorial overexpression provides an opportunity to define the minimal core network of TFs that instructs specific cell fates. This approach has been employed to induce mouse and human pluripotency and differentiated cell types from cells that can be also as distant as cells from different germ layers. This suggests the possibility that any specific cell type may be directly converted into another if the appropriate reprogramming TF core is determined. Herein, we review the factors used for reprogramming multiple cell identities and raise the question of whether there is a common underlying blueprint for reprogramming factors. In addition to the generation of human cell types of interest for cell‐replacement therapies, we propose that the TF‐mediated conversion of differentiated cell types, especially somatic stem cells, will have an impact on our understanding of their biological development.