Abstract
Epigenetic regulation of chromatin structure is strongly influenced by histone variants and post-translational modifications. The conserved histone variant H2A.Z has been functionally linked to the pioneer factors Sox2 and Oct4, which open chromatin and activate cell fate-specific transcriptional programs. However, the molecular basis of this interaction is not well understood. Here, we combine biochemistry, NMR spectroscopy, and molecular dynamics (MD) simulations to investigate how H2A.Z nucleosome dynamics influence pioneer factor binding. We find that H2A.Z enhances Sox2 and Oct4 association at distinct positions within 601 nucleosomes, correlating with increased DNA accessibility and altered H3 N-terminal tail dynamics. We show that the H3 tail competes with Sox2 for DNA binding and is more efficiently displaced with H2A.Z, while also allowing for unique Sox2-H3 tail interactions. MD simulations reveal that H2A.Z promotes DNA unwrapping, increases inter-gyre spacing, and enhances H3 tail flexibility, while simultaneously reducing contacts with DNA and with the H2A.Z C-terminal tail. This destabilizing effect is DNA-sequence dependent and prominent in the less stable Lin28B nucleosome, which Sox2 appears to substantially reshape. Together, our results suggest that H2A.Z promotes pioneer factor binding by increasing DNA accessibility and reducing histone tail competition, with broad implications for epigenetic regulation and chromatin recognition.