ZBTB7A regulates primed-to-naïve transition of pluripotent stem cells via recognition of the PNT-associated sequence by zinc fingers 1-2 and recognition of γ-globin -200 gene element by zinc fingers 1-4.

ZBTB7A, a transcription factor containing a tandem array of four Cys2-His2 zinc fingers (ZFs), is vital for multiple physiological events through directional binding to different genomic loci. Our previously determined crystal structure of ZBTB7A in complex with a GCCCCTTCCCC sequence revealed that all four ZFs (ZF1-4) are involved in binding to γ-globin -200 gene element to repress fetal haemoglobin expression. Recently, it has been reported that ZBTB7A drives primed-to-naïve transition (PNT) of pluripotent stem cells through binding to a 12-bp consensus sequence ([AAGGACCCAGAT], referred to as PNT-associated sequence). Here, we report a crystal structure of ZBTB7A ZF1-3 in complex with the PNT-associated sequence. The structure shows that ZF1 and ZF2 primarily contribute to recognizing the GACCC core sequence mimicking the half part (GCCCC) of γ-globin -200 gene element via specific hydrogen bonding and van der Waals contacts. The mutations of key residues in ZF1-2 remarkably reduce their binding affinities for the PNT-associated sequence in vitro and cannot restore epiblast stem cells to the naïve pluripotent state in vivo. Collectively, our studies demonstrate that ZBTB7A mainly employs its ZF1-2 to recognize the PNT-associated sequence but recognizes γ-globin -200 gene element via ZF1-4, providing insights into the molecular mechanism for the diversity of ZBTB7A's genomic localization.

BMP4 drives primed to naïve transition through PGC-like state.

Multiple pluripotent states have been described in mouse and human stem cells. Here, we apply single-cell RNA-seq to a newly established BMP4 induced mouse primed to naïve transition (BiPNT) system and show that the reset is not a direct reversal of cell fate but goes through a primordial germ cell-like cells (PGCLCs) state. We first show that epiblast stem cells bifurcate into c-Kit+ naïve and c-Kit- trophoblast-like cells, among which, the naïve branch undergoes further transition through a PGCLCs intermediate capable of spermatogenesis in vivo. Mechanistically, we show that DOT1L inhibition permits the transition from primed pluripotency to PGCLCs in part by facilitating the loss of H3K79me2 from Gata3/6. In addition, Prdm1/Blimp1 is required for PGCLCs and naïve cells, while Gata2 inhibits PGC-like state by promoting trophoblast-like fate. Our work not only reveals an alternative route for primed to naïve transition, but also gains insight into germ cell development.

BMP4 resets mouse epiblast stem cells to naive pluripotency through ZBTB7A/B-mediated chromatin remodelling.

BMP4 regulates a plethora of developmental processes, including the dorsal-ventral axis and neural patterning. Here, we report that BMP4 reconfigures the nuclear architecture during the primed-to-naive transition (PNT). We first established a BMP4-driven PNT and show that BMP4 orchestrates the chromatin accessibility dynamics during PNT. Among the loci opened early by BMP4, we identified Zbtb7a and Zbtb7b (Zbtb7a/b) as targets that drive PNT. ZBTB7A/B in turn facilitate the opening of naive pluripotent chromatin loci and the activation of nearby genes. Mechanistically, ZBTB7A not only binds to chromatin loci near to the genes that are activated, but also strategically occupies those that are silenced, consistent with a role of BMP4 in both activating and suppressing gene expression during PNT at the chromatin level. Our results reveal a previously unknown function of BMP4 in regulating nuclear architecture and link its targets ZBTB7A/B to chromatin remodelling and pluripotent fate control.