Project description:This SuperSeries is composed of the SubSeries listed below.

Project description:Early mammalian development is accompanied by a profound global remodeling of chromatin-based regulation. The Zdbf2 locus provides a valuable model to uncover the effect of dynamic chromatin transition, as it is polycomb silenced in embryonic stem cells (ESCs) and only becomes activated after Long isoform of Zdbf2 (Liz) transcription-dependent de novo DNA methylation during differentiation. Here we show that four enhancers contribute to the Liz-to-Zdbf2 promoter switch, concomitantly with dynamic changes in chromatin architecture. CTCF plays a key role in partitioning the locus in ESCs, when Liz is active and Zdbf2 is silenced. The partition is relieved when Zdbf2 becomes DNA methylated and active. Mutant ESCs that lack the partition fail to properly activate Zdbf2. Notably, the CTCF-based regulation occurs independently of the polycomb and DNA methylation pathways, suggesting a multi-layered regulatory framework that ensures proper epigenetic programming of a developmentally important gene.

Project description:Early mammalian development is accompanied by a profound global remodeling of chromatin-based regulation. The Zdbf2 locus provides a valuable model to uncover the effect of dynamic chromatin transition, as it is polycomb silenced in embryonic stem cells (ESCs) and only becomes activated after Long isoform of Zdbf2 (Liz) transcription-dependent de novo DNA methylation during differentiation. Here we show that four enhancers contribute to the Liz-to-Zdbf2 promoter switch, concomitantly with dynamic changes in chromatin architecture. CTCF plays a key role in partitioning the locus in ESCs, when Liz is active and Zdbf2 is silenced. The partition is relieved when Zdbf2 becomes DNA methylated and active. Mutant ESCs that lack the partition fail to properly activate Zdbf2. Notably, the CTCF-based regulation occurs independently of the polycomb and DNA methylation pathways, suggesting a multi-layered regulatory framework that ensures proper epigenetic programming of a developmentally important gene.

Project description:Early mammalian development is accompanied by a profound global remodeling of chromatin-based regulation. The Zdbf2 locus provides a valuable model to uncover the effect of dynamic chromatin transition, as it is polycomb silenced in embryonic stem cells (ESCs) and only becomes activated after Long isoform of Zdbf2 (Liz) transcription-dependent de novo DNA methylation during differentiation. Here we show that four enhancers contribute to the Liz-to-Zdbf2 promoter switch, concomitantly with dynamic changes in chromatin architecture. CTCF plays a key role in partitioning the locus in ESCs, when Liz is active and Zdbf2 is silenced. The partition is relieved when Zdbf2 becomes DNA methylated and active. Mutant ESCs that lack the partition fail to properly activate Zdbf2. Notably, the CTCF-based regulation occurs independently of the polycomb and DNA methylation pathways, suggesting a multi-layered regulatory framework that ensures proper epigenetic programming of a developmentally important gene.

Project description:Early mammalian development is accompanied by a profound global remodeling of chromatin-based regulation. The Zdbf2 locus provides a valuable model to uncover the effect of dynamic chromatin transition, as it is polycomb silenced in embryonic stem cells (ESCs) and only becomes activated after Long isoform of Zdbf2 (Liz) transcription-dependent de novo DNA methylation during differentiation. Here we show that four enhancers contribute to the Liz-to-Zdbf2 promoter switch, concomitantly with dynamic changes in chromatin architecture. CTCF plays a key role in partitioning the locus in ESCs, when Liz is active and Zdbf2 is silenced. The partition is relieved when Zdbf2 becomes DNA methylated and active. Mutant ESCs that lack the partition fail to properly activate Zdbf2. Notably, the CTCF-based regulation occurs independently of the polycomb and DNA methylation pathways, suggesting a multi-layered regulatory framework that ensures proper epigenetic programming of a developmentally important gene.

Project description:Following implantation, mouse epiblast cells transit from a naive to a primed state in which they are competent for both somatic and primordial germ cell (PGC) specification. Using mouse embryonic stem cells as an in vitro model to study the transcriptional regulatory principles orchestrating peri-implantation development, here we show that the transcription factor Foxd3 is necessary for exit from naive pluripotency and progression to a primed pluripotent state. During this transition, Foxd3 acts as a repressor that dismantles a significant fraction of the naive pluripotency expression program through decommissioning of active enhancers associated with key naive pluripotency and early germline genes. Subsequently, Foxd3 needs to be silenced in primed pluripotent cells to allow re-activation of relevant genes required for proper PGC specification. Our findings therefore uncover a cycle of activation and deactivation of Foxd3 required for exit from naive pluripotency and subsequent PGC specification.

Project description:Cooperative action of a transcription factor complex containing OCT4, SOX2, NANOG, and KLF4 maintains the naive pluripotent state; however, less is known about the mechanisms that disrupt this complex, initiating exit from pluripotency. We show that, as embryonic stem cells (ESCs) exit pluripotency, KLF4 protein is exported from the nucleus causing rapid decline in Nanog and Klf4 transcription; as a result, KLF4 is the first pluripotency transcription factor removed from transcription-associated complexes during differentiation. KLF4 nuclear export requires ERK activation, and phosphorylation of KLF4 by ERK initiates interaction of KLF4 with nuclear export factor XPO1, leading to KLF4 export. Mutation of the ERK phosphorylation site in KLF4 (S132) blocks KLF4 nuclear export, the decline in Nanog, Klf4, and Sox2 mRNA, and differentiation. These findings demonstrate that relocalization of KLF4 to the cytoplasm is a critical first step in exit from the naive pluripotent state and initiation of ESC differentiation.

Project description:Dynamic enhancer partitioning instructs Zdbf2 activation during epigenetic reprogramming

Project description:The enhancer landscape of pluripotent stem cells undergoes extensive reorganization during early mammalian development. The functions and mechanisms behind such reorganization, however, are unclear. Here, we show that the transcription factor GRHL2 is necessary and sufficient to activate an epithelial subset of enhancers as naive embryonic stem cells (ESCs) transition into formative epiblast-like cells (EpiLCs). Surprisingly, many GRHL2 target genes do not change in expression during the ESC-EpiLC transition. Instead, enhancers regulating these genes in ESCs diminish in activity in EpiLCs while GRHL2-dependent alternative enhancers become activated to maintain transcription. GRHL2 therefore assumes control over a subset of the naive network via enhancer switching to maintain expression of epithelial genes upon exit from naive pluripotency. These data evoke a model where the naive pluripotency network becomes partitioned into smaller, independent networks regulated by EpiLC-specific transcription factors, thereby priming cells for lineage specification.

Project description:Transcription factor (TF)-directed enhanceosome assembly constitutes a fundamental regulatory mechanism driving spatiotemporal gene expression programs during animal development. Despite decades of study, we know little about the dynamics or order of events animating TF assembly at cis-regulatory elements in living cells and the long-range molecular "dialog" between enhancers and promoters. Here, combining genetic, genomic, and imaging approaches, we characterize a complex long-range enhancer cluster governing Krüppel-like factor 4 (Klf4) expression in naïve pluripotency. Genome editing by CRISPR/Cas9 revealed that OCT4 and SOX2 safeguard an accessible chromatin neighborhood to assist the binding of other TFs/cofactors to the enhancer. Single-molecule live-cell imaging uncovered that two naïve pluripotency TFs, STAT3 and ESRRB, interrogate chromatin in a highly dynamic manner, in which SOX2 promotes ESRRB target search and chromatin-binding dynamics through a direct protein-tethering mechanism. Together, our results support a highly dynamic yet intrinsically ordered enhanceosome assembly to maintain the finely balanced transcription program underlying naïve pluripotency.