Project description:Pou5f3, SoxB1 and Nanog remodel chromatin on High Nucleosome Affinity Regions at Zygotic Genome Activation.

Project description:We applied time-series SE50bp RNA-seq with 35M reads per sample in wild-type, MZsox19b, MZspg, and double MZspgsox19b mutants in zebrafish embryos to understand the role of Pou5f3 and Sox19b during zebrafish zygotic genome activation. In total we sequenced 4 biological replicates (rep1-4) for WT time curve and 2 biological replicates (rep1-2) for each mutant. WT rep5 are technical replicates for WT rep1, while MZsox19b rep3 and MZspg rep3 are techical replicates for MZsox19b rep1 and MZspg rep1, respectively.

Project description:Upon fertilization, maternal factors direct development in a transcriptionally silent embryo. At the maternal-to-zygotic transition (MZT), a universal step in animal development, unknown maternal factors trigger zygotic genome activation (ZGA). In zebrafish, ZGA is required for gastrulation and clearance of maternal mRNAs, which is achieved in part by the conserved microRNA miR-430. However, the precise factors that activate the zygotic program remain largely unknown. Here we show that Nanog, Pou5f1 and SoxB1 are required for genome activation in zebrafish. We identified several hundred genes directly activated by maternal factors, thus constituting the first wave of zygotic transcription in zebrafish. Ribosome profiling in the pre-MZT embryo revealed that nanog, sox19b and pou5f1 are the most highly translated transcription factor mRNAs. Combined loss of function for Nanog, SoxB1 and Pou5f1 resulted in developmental arrest prior to gastrulation, and a failure to activate >75% of zygotic genes. Furthermore, we found that Nanog binds the miR-430 locus and together with Pou5f1 and SoxB1 initiate miR-430 expression and activity. Our results demonstrate that maternal Nanog, Pou5f1 and SoxB1 are required to initiate the zygotic developmental program and in turn trigger the clearance of the maternal program by activating miR-430 expression. Wild type and loss-of-function total mRNA sequencing of embryonic transcriptomes pre- and post-MZT; ribosome profiling pre-MZT

Project description:To understand the role of Pou5f3, Sox19b and Nanog during zebrafish zygotic genome activation, RNA-seq time-series for single, double and triple maternal-zygotic (MZ) zebrafish mutants for Pou5f3, Nanog, Sox19b, as well as the wild-type.

Project description:Upon fertilization, maternal factors direct development in a transcriptionally silent embryo. At the maternal-to-zygotic transition (MZT), a universal step in animal development, unknown maternal factors trigger zygotic genome activation (ZGA). In zebrafish, ZGA is required for gastrulation and clearance of maternal mRNAs, which is achieved in part by the conserved microRNA miR-430. However, the precise factors that activate the zygotic program remain largely unknown. Here we show that Nanog, Pou5f1 and SoxB1 are required for genome activation in zebrafish. We identified several hundred genes directly activated by maternal factors, thus constituting the first wave of zygotic transcription in zebrafish. Ribosome profiling in the pre-MZT embryo revealed that nanog, sox19b and pou5f1 are the most highly translated transcription factor mRNAs. Combined loss of function for Nanog, SoxB1 and Pou5f1 resulted in developmental arrest prior to gastrulation, and a failure to activate >75% of zygotic genes. Furthermore, we found that Nanog binds the miR-430 locus and together with Pou5f1 and SoxB1 initiate miR-430 expression and activity. Our results demonstrate that maternal Nanog, Pou5f1 and SoxB1 are required to initiate the zygotic developmental program and in turn trigger the clearance of the maternal program by activating miR-430 expression.

Project description:Upon fertilization, maternal factors direct development in a transcriptionally silent embryo. At the maternal-to-zygotic transition (MZT), a universal step in animal development, unknown maternal factors trigger zygotic genome activation (ZGA). In zebrafish, ZGA is required for gastrulation and clearance of maternal mRNAs, which is achieved in part by the conserved microRNA miR-430. However, the precise factors that activate the zygotic program remain largely unknown. Here we show that Nanog, Pou5f1 and SoxB1 are required for genome activation in zebrafish. We identified several hundred genes directly activated by maternal factors, thus constituting the first wave of zygotic transcription in zebrafish. Ribosome profiling in the pre-MZT embryo revealed that nanog, sox19b and pou5f1 are the most highly translated transcription factor mRNAs. Combined loss of function for Nanog, SoxB1 and Pou5f1 resulted in developmental arrest prior to gastrulation, and a failure to activate >75% of zygotic genes. Furthermore, we found that Nanog binds the miR-430 locus and together with Pou5f1 and SoxB1 initiate miR-430 expression and activity. Our results demonstrate that maternal Nanog, Pou5f1 and SoxB1 are required to initiate the zygotic developmental program and in turn trigger the clearance of the maternal program by activating miR-430 expression.

Project description:Genetic control of pluripotent mammalian ES cells is determined by a transcriptional network, with a "central core" of transcription factors, Pou5f1, Sox2 and Nanog. Zebrafish homologues of the "core pluripotency factors" Pou5f1, SoxB1 and Nanog-like are also crucially involved in early development. However, the degree of functional similarity of the network between mammals and non-mammals is a matter of debate. To identify the components of Pou5f1-dependent transcriptional networks, we determined the genomic binding sites for Pou5f1 and Sox2 in late blastula stage zebrafish embryos using ChIP-seq. We found that Sox2 and Pou5f1 are co-binding to the regulatory regions of Sox2, Pou5f1, and Nanog-like, as well as to multiple orthologues of mammalian plutipotency network components.

Project description:Genetic control of pluripotent mammalian ES cells is determined by a transcriptional network, with a "central core" of transcription factors, Pou5f1, Sox2 and Nanog. Zebrafish homologues of the "core pluripotency factors" Pou5f1, SoxB1 and Nanog-like are also crucially involved in early development. However, the degree of functional similarity of the network between mammals and non-mammals is a matter of debate. To identify the components of Pou5f1-dependent transcriptional networks, we determined the genomic binding sites for Pou5f1 and Sox2 in late blastula stage zebrafish embryos using ChIP-seq. We found that Sox2 and Pou5f1 are co-binding to the regulatory regions of Sox2, Pou5f1, and Nanog-like, as well as to multiple orthologues of mammalian plutipotency network components. Deep sequencing was performed using the Illumina GAIIx on DNA samples obtained from Sox2 ChIP, Pou5f1-Flag ChIP and Input Control. Pou5f1 was analysed in technical duplicates to obtain higher sequencing depth.

Project description:In many organisms, early embryonic development is driven by maternally provided transcription factors until the controlled onset of transcription during zygotic genome activation (ZGA). The regulation of chromatin accessibility and its relationship to gene activity during this transition remains poorly understood. Here, we generated chromatin accessibility maps for the early stages of zebrafish development spanning genome activation and the onset of lineage specification. We find that during this period, chromatin accessibility increases at regulatory elements. This is independent of RNA pol II-mediated transcription, with the exception of the miR-430 locus. Instead, accessibility often precedes the transcription of associated genes. Loss of the maternal transcription factors pou5f3, sox19b, and nanog, which are known to be required for zebrafish ZGA, results in decreased accessibility at regulatory elements. Finally, we show that accessibility of regulatory regions, especially when established by Pou5f3, Sox19b and Nanog, is predictive for future transcription. Together, our results suggest that maternally provided transcription factors prime genes for activity during zygotic genome activation.

Project description:Pioneer transcription factors Nanog, Pou5f3 and Sox19b promote chromatin accessibility on the enhancers of the early zebrafish embryos. It is poorly understood how they act together; it is commonly assumed that they act additively or cooperatively to clear chromatin from the nucleosomes. We investigated this question by comparing chromatin accessibility (Omni ATAC-seq) in seven mutant genotypes: single, double and triple maternal-zygotic mutants by Pou5f3, Sox19b and Nanog, and the wild-type embryos. We found, that at most of the directly bound sites, either Pou or Nanog is required for chromatin accessibility; while at the minority of the sites two factors act additively. Further, on the sites, where Pou5f3 promotes chromatin accessibility, Nanog often suppresses it, and vice versa. To explain this phenomenon, we suggest a model of nucleosome-mediated competition between pioneer transcription factors: Pou5f3 and Nanog compete for the same binding motif on the DNA, but only one of the factors has a pioneer activity on this site. This entry contains only part fo the Omni-ATAC-seq experiments, the other part is in the previously released entry GSE188364.