Extensive research in the field of stem cells and developmental biology has revealed evidence of the role of hypoxia as an important factor regulating self-renewal and differentiation. However, comprehensive information about the exact hypoxia-mediated regulatory mechanism of stem cell fate during early embryonic development is still missing. Using a model of embryoid bodies (EBs) derived from murine embryonic stem cells (ESC), we here tried to encrypt the role of hypoxia-inducible factor 1α(HIF1α) in neural fate during spontaneous differentiation. EBs derived from ESC with the ablated gene for HIF1αhad abnormally increased neuronal characteristics during differentiation. An increased neural phenotype inHif1α-/-EBs was accompanied by the disruption ofβ-catenin signaling together with the increased cytoplasmic degradation ofβ-catenin. The knock-in ofHif1α, as well asβ-catenin ectopic overexpression inHif1α-/-EBs, induced a reduction in neural markers to the levels observed in wild-type EBs. Interestingly, direct interaction between HIF1αandβ-catenin was demonstrated by immunoprecipitation analysis of the nuclear fraction of wild-type EBs. Together, these results emphasize the regulatory role of HIF1αinβ-catenin stabilization during spontaneous differentiation, which seems to be a crucial mechanism for the natural inhibition of premature neural differentiation.

Department of Experimental Biology Faculty of Science Masaryk University 62500 Brno Czech Republic

Department of Experimental Biology Faculty of Science Masaryk University 62500 Brno Czech Republic Institute of Biophysics Academy of Sciences of the Czech Republic 61265 Brno Czech Republic International Clinical Research Center St Anne's University Hospital 65691 Brno Czech Republic

Institute of Biophysics Academy of Sciences of the Czech Republic 61265 Brno Czech Republic

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