OTX2 controls chromatin accessibility to direct somatic versus germline differentiation.

The choice between somatic and germline fates is essential for species survival. This choice occurs in embryonic epiblast cells, as these cells are competent for both somatic and germline differentiation. The transcription factor OTX2 regulates this process, as Otx2-null epiblast-like cells (EpiLCs) form primordial germ cell-like cells (PGCLCs) with enhanced efficiency. Yet, how OTX2 achieves this function is not fully characterised. Here we show that OTX2 controls chromatin accessibility at specific chromatin loci to enable somatic differentiation. CUT&RUN for OTX2 and ATAC-seq in wild-type and Otx2-null embryonic stem cells and EpiLCs identifies regions where OTX2 binds and opens chromatin. Enforced OTX2 expression maintains accessibility at these regions and also induces opening of ~4000 somatic-associated regions in cells differentiating in the presence of PGC-inducing cytokines. Once cells have acquired germline identity, these additional regions no longer respond to OTX2 and remain closed. Our results indicate that OTX2 works in cells with dual competence for somatic and germline differentiation to increase accessibility of somatic regulatory regions and induce the somatic fate at the expense of the germline.