Abstract
Summary paragraphDifferent cell types are determined by cell lineage-specific transcriptional programmes and by epigenetic regulation of chromatin1, 2. Yet, the functional relationships between dynamically expressed transcription factors (TFs) and chromatin changes guiding lineage specification often remain elusive3. First mammalian embryonic lineages segregate when pluripotent cells become committed to either Mesoderm and Endoderm (ME) or Neuroectoderm (NE). NE forms by default in the absence of signalling-induced ME specification4, 5, resulting from global asymmetries in chromatin state favouring NE gene programme activation as recently demonstrated6–8. In this study, we unravel the initiation of ME lineage specification by the genome-wide,de novoformation of chromatin accessibility at ME enhancers that epigenetically deflects pluripotent cells from default NE differentiation. The Tbx TFEomes, previously considered a transcriptional regulator, acts as global chromatin organizer that establishes ME lineage competence. EOMES recruits the canonical ATP-dependent chromatin remodelling complex SWI/SNF to broadly generate the chromatin- accessible ME enhancer landscape. This lineage competence is generated independently of ME gene transcription that fully depends on ME-inducing signalling pathways including Wnts and TGFβ/NODAL9. This study thus resolves the successive steps of ME lineage differentiation by globally establishing chromatin accessibility for lineage competence, followed by signal-encoded transcriptional regulation of different ME lineage-defining gene programmes.
Publisher
Cold Spring Harbor Laboratory