Geminin is required for the maintenance of pluripotency.

Golnaz A Tabrizi,Kerstin Böse,Michael Kessel,Yvonne Reimann

doi:10.1371/journal.pone.0073826

Golnaz A Tabrizi, Kerstin Böse + Show 2 more

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https://doi.org/10.1371/journal.pone.0073826

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Journal: PloS one	Publication Date: Sep 19, 2013
Citations: 16	License type: CC BY 4.0

Affiliation: Max Planck Institute for Biophysical Chemistry

Abstract

Pluripotency requires the expression of the three core transcriptions factors Oct4, Sox2 and Nanog, as well as further, complementary proteins. The geminin protein is part of this network, and was shown to play a role in the regulation of DNA replication, the control of the cell cycle, and the acquisition of neural fate. It is highly expressed in the early embryo, in particular the epiblast and the early neural ectoderm, and also in pluripotent embryonic stem cells. The genetic inactivation of geminin resulted in lethality after the first few cell divisions, and thus prohibited the outgrowth of pluripotent cells. We established embryonic stem cells allowing the deletion of the geminin gene by induction of of Cre-recombinase with tamoxifen. Here, we show that geminin deficiency quickly leads to a loss of pluripotency, and to differentiation into the mesendodermal direction with high Oct4/low Sox2 levels. Simultaneous loss of geminin and induction of the neural lineage resulted in immediate apoptosis. These results suggested that in early development geminin functions via the co-expressed Sox2 gene. We found that the stem cell enhancer SRR2 of Sox2 is occupied by the activating esBAF complex in the presence of geminin, but becomes epigenetically repressed in its absence by the Polycomb repressive complex PRC2. The importance of geminin for Sox2 expression also explains the absolute requirement for geminin during the induction of pluripotency by OSKM viruses. In summary, geminin is required for Sox2 expression, and thus for the maintenance of totipotency, pluripotency and the early neural lineage.

Highlights

The developmental potential of cells in early mouse embryogenesis becomes systematically restricted, going down from toti, to pluri, multi- and unipotency
Geminin protein is highly expressed in embryonic stem cells and neuroectodermal progenitors We examined the geminin levels in wild type mouse ESCs and their differentiating progenies
Whole cell lysate protein analysis showed that undifferentiated ESCs expressed geminin strongly, and the levels decreased during differentiation under standard conditions involving the formation of embryoid bodies (Fig. 1A)

Summary

Introduction

The developmental potential of cells in early mouse embryogenesis becomes systematically restricted, going down from toti-, to pluri-, multi- and unipotency. The pluripotent mouse embryonic stem cells (ESCs) resemble the ICM of the early blastocyst in terms of expression of core pluripotency gene network, such as Oct, Sox and Nanog. These key transcription factors maintain the expression of each other and other pluripotency genes, through a crosstalk with chromatin remodeling complexes, governing the pluripotent state of the ES cells [1]. The interplay between Oct and Sox is a key regulatory mechanism in the establishment of the pluripotency and fate allocation [2] Their expression diverges when either the neural/ non-neural ectodermal, or the mesendodermal lineage is established at the onset of gastrulation. While Oct expression in the absence of Sox is crucial for acquisition of the mesendodermal fate, early neurogenic fate requires the presence of Sox in the absence of Oct4 [3]

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