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Resetting the Epigenome beyond Pluripotency in the Germline

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1 Resetting the Epigenome beyond Pluripotency in the Germline
Katsuhiko Hayashi, M. Azim Surani  Cell Stem Cell  Volume 4, Issue 6, Pages (June 2009) DOI: /j.stem Copyright © 2009 Elsevier Inc. Terms and Conditions

2 Figure 1 Stepwise Differentiation and Reprogramming during Mouse Development A totipotent zygote develops into a blastocyst, followed by differentiation into ICM/PEct and trophectoderm (TE). ICM/PEct are pluripotent cells but no longer totipotent. After implantation, ICM/PEct differentiates into the epiblast, coupled with random X inactivation, a hallmark of the epigenetic state of this population. During gastrulation, epiblast cells give rise to both germ cells and somatic cells. Whereas somatic cells undergo further differentiation, PGCs revert to a state that resembles the ICM/PEct population, with the exception that they are unipotent. Further epigenetic reprogramming events take place in germ cells, including genome-wide DNA demethylation and remodeling of retrotransposon-linked genes. Cell Stem Cell 2009 4, DOI: ( /j.stem ) Copyright © 2009 Elsevier Inc. Terms and Conditions

3 Figure 2 Impact of PGC-Mediate Epigenetic Reprogramming on Pluripotent Stem Cells (A) Mouse ESCs (top) derived from ICM/PEct exhibit an epigenetic status similar to mouse EG cells because PGC-mediate reprogramming has the potential to erase epigenetic memory of epiblast. It is proposed that derivation of PGCs from EpiSCs may similarly erase the epigenetic memory of the latter. Human ESCs (bottom) may lack the ICM/PEct reprogramming event observed in the mouse ICM/PEct, making hESCs more like the EpiESCs. However, epigenetic reprogramming in human germ cells renders them responsive to LIF-STAT3 signaling and, therefore, similar to mouse ES/EG cells, which suggests equivalent resetting of the epigenome in the mouse and human germline. (B) Experimentally generated pluripotent stem cells may exhibit defects in their potential for terminal differentiation and, thus, may not be capable of development to term in tetraploid host blastocysts. These limitations may result from the presence of epigenetic defects retained during an incomplete reprogramming process. Epigenetic defects encountered in experimentally generated pluripotent cells may be corrected upon their transmission through the germline (top). Cell Stem Cell 2009 4, DOI: ( /j.stem ) Copyright © 2009 Elsevier Inc. Terms and Conditions

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