Project description:Mammalian zygotic genome activation (ZGA) following fertilization refers to the process that results in transcriptional awakening of the embryonic genome at two-cell (2C) stage in mice or 4-8 cell stage in human. ZGA confers to the mouse 2C embryo a unique transcriptional profile characterized by transient up-regulation of many totipotency-related genes and MERVL transposons. Intriguingly, many ZGA-related totipotent genes are duplicated and clustered in the genome during evolution, including Dux cluster, OBOX and Zscan4 family members in mice. Yet, the contribution and biological significance of the totipotency-related gene duplication events during evolution in totipotency acquisition remain poorly understood. Here, we focus on Dux cluster, the master regulator of ZGA that is necessary and sufficient for the emergence of 2C-like cells (2CLCs) and activation of target totipotent genes in mouse embryonic stem cells (ESCs). By reducing Dux gene copy number from 31 to 0 or 1 with CRISPR-Cas9 technology, we generated Dux-KO and Dux (n=1) ES cell lines, respectively. We found that the totipotent gene transcriptional profile could not be fully activated in Dux (n=1) mESCs compared to wild type (WT) mESCs after treatment with DNMT1 protein degrader, mimicking the DNA demethylation process during early embryo development. These data demonstrate that Dux cluster duplication is essential for fully activation of totipotency-related genes, ensuring ZGA and totipotency acquisition.

Project description:In mammalian embryos, Dux transcription factors (TF) drive a cleavage stage-specific transcriptional burst associated with zygotic genome activation (ZGA) during which hundreds of genes and endogenous retroviral (ERV) elements are transiently expressed. In mice, ZGA begins in late 1-cell (1C) embryos and is shut down within hours at the late 2-cell (2C) to 4-cell (4C) stage. While this transition is accompanied by the loss of totipotency, it is not clear whether shutdown of Dux-induced ZGA is required for this process and how ZGA is terminated. Here, we reveal an essential negative feedback axis by which the Dux family member Duxbl terminates Dux-induced ZGA from the mid 2C stage onward by direct suppression of genomic Dux target loci. Consequently, Duxbl inactivation results in sustained expression of Dux-induced ZGA leading to 4C arrest. Our study reveals the Dux/Duxbl axis that determines the timing of totipotency exit enabling the very first divergence of cell fates.

Project description:In mammalian embryos, Dux transcription factors (TF) drive a cleavage stage-specific transcriptional burst associated with zygotic genome activation (ZGA) during which hundreds of genes and endogenous retroviral (ERV) elements are transiently expressed. In mice, ZGA begins in late 1-cell (1C) embryos and is shut down within hours at the late 2-cell (2C) to 4-cell (4C) stage. While this transition is accompanied by the loss of totipotency, it is not clear whether shutdown of Dux-induced ZGA is required for this process and how ZGA is terminated. Here, we reveal an essential negative feedback axis by which the Dux family member Duxbl terminates Dux-induced ZGA from the mid 2C stage onward by direct suppression of genomic Dux target loci. Consequently, Duxbl inactivation results in sustained expression of Dux-induced ZGA leading to 4C arrest. Our study reveals the Dux/Duxbl axis that determines the timing of totipotency exit enabling the very first divergence of cell fates.

Project description:In mammalian embryos, Dux transcription factors (TF) drive a cleavage stage-specific transcriptional burst associated with zygotic genome activation (ZGA) during which hundreds of genes and endogenous retroviral (ERV) elements are transiently expressed. In mice, ZGA begins in late 1-cell (1C) embryos and is shut down within hours at the late 2-cell (2C) to 4-cell (4C) stage. While this transition is accompanied by the loss of totipotency, it is not clear whether shutdown of Dux-induced ZGA is required for this process and how ZGA is terminated. Here, we reveal an essential negative feedback axis by which the Dux family member Duxbl terminates Dux-induced ZGA from the mid 2C stage onward by direct suppression of genomic Dux target loci. Consequently, Duxbl inactivation results in sustained expression of Dux-induced ZGA leading to 4C arrest. Our study reveals the Dux/Duxbl axis that determines the timing of totipotency exit enabling the very first divergence of cell fates.

Project description:How maternal factors in oocytes trigger zygotic genome activation (ZGA) is a long-standing question in developmental biology. Recent studies in 2-cell like embryonic stem cells (2C-like cells) implicate that the DUX family transcription factors are key regulators of ZGA in placental mammals. To characterize the role of DUX in ZGA, we generated Dux cluster knockout (KO) mouse lines. Unexpectedly, we found both Dux zygotic KO (Z-KO) and maternal/zygotic KO (MZ-KO) embryos can survive to adulthood despite showing reduced developmental potential. Furthermore, transcriptome profiling of the MZ-KO embryos revealed that loss of DUX has minimal effect on ZGA and most DUX targets in 2C-like cells are normally activated in MZ-KO embryos. Thus, contrary to the key function in inducing 2C-like cells, our data indicate that DUX only has a minor role in ZGA and loss of DUX is compatible with mouse development.

Project description:After fertilization of the transcriptionally silent oocyte, expression from both parental chromosomes is launched through so-called zygotic genome activation (ZGA), occurring in the mouse at the 2-cell (2C) stage. Amongst the first elements to be transcribed are the Dux gene, the product of which secondarily induces a wide array of ZGA genes, and a subset of evolutionary recent LINE-1 retrotransposons, which regulate chromatin accessibility in the early embryo. The maternally-inherited factors that activate Dux and LINE-1 transcription have so far remained unknown. Mouse embryonic stem cells (mESCs) recapitulate some aspects of ZGA in culture, owing to their ability to cycle through a 2C-like stage where Dux, its target genes and LINE-1 integrants are expressed. Here we identify the paralog proteins DPPA2 and DPPA4 as necessary for activation of Dux and LINE-1 expression in mESCs. Since their encoding RNAs are maternally transmitted to the zygote, it is likely that these factors are important upstream mediators of murine ZGA.

Project description:After fertilization of the transcriptionally silent oocyte, expression from both parental chromosomes is launched through so-called zygotic genome activation (ZGA), occurring in the mouse at the 2-cell (2C) stage. Amongst the first elements to be transcribed are the Dux gene, the product of which secondarily induces a wide array of ZGA genes, and a subset of evolutionary recent LINE-1 retrotransposons, which regulate chromatin accessibility in the early embryo. The maternally-inherited factors that activate Dux and LINE-1 transcription have so far remained unknown. Mouse embryonic stem cells (mESCs) recapitulate some aspects of ZGA in culture, owing to their ability to cycle through a 2C-like stage where Dux, its target genes and LINE-1 integrants are expressed. Here we identify the paralog proteins DPPA2 and DPPA4 as necessary for activation of Dux and LINE-1 expression in mESCs. Since their encoding RNAs are maternally transmitted to the zygote, it is likely that these factors are important upstream mediators of murine ZGA.

Project description:The molecular regulation of zygotic genome activation (ZGA) in mammals remains poorly understood. Primed mouse embryonic stem cells contain a rare subset of “2C-like” cells that are epigenetically and transcriptionally similar to the two cell embryo and thus represent an ideal system for studying ZGA transcription regulation. Recently, the transcription factor Dux, expressed exclusively in the minor wave of ZGA, was described to activate many downstream ZGA transcripts. However, it remains unknown what upstream maternal factors initiate ZGA either in a Dux dependent or independent manner. Here we performed a candidate-based overexpression screen, identifying, amongst others, Developmental Pluripotency Associated 2 (Dppa2) and 4 (Dppa4) as positive regulators of 2C-like cells and ZGA transcription. In the germ line, promoter DNA demethylation coincides with upregulation of Dppa2 and Dppa4 which remain expressed until E7.5 when their promoters are remethylated. Furthermore, Dppa2 and Dppa4 are also expressed during iPSC reprogramming at the time 2C-like ZGA transcription transiently peaks. Through a combination of overexpression, knockdown, knockout and rescue experiments, together with transcriptional analyses, we show that Dppa2 and Dppa4 directly regulate the 2C-like cell population and associated transcripts, including Dux and the Zscan4 cluster. Importantly, we tease apart the molecular hierarchy in which the 2C-like transcriptional program is initiated and stabilised. Dppa2 and Dppa4 require Dux to initiate 2C-like ZGA transcription, suggesting they act upstream by directly regulating Dux. Supporting this, ChIP-seq analysis revealed Dppa2 and Dppa4 bind to the Dux promoter and gene body and drive its expression. Zscan4c is also able to induce 2C-like cells in wild type cells, but, in contrast to Dux, can no longer do so in Dppa2/4 double knockout cells, suggesting it may act to stabilise rather than drive the transcriptional network. Our findings suggest a model in which Dppa2/4 binding to the Dux promoter leads to Dux upregulation and activation of the 2C-like transcriptional program which is subsequently reinforced by Zscan4c.

Project description:The molecular regulation of zygotic genome activation (ZGA) in mammals remains poorly understood. Primed mouse embryonic stem cells contain a rare subset of “2C-like” cells that are epigenetically and transcriptionally similar to the two cell embryo and thus represent an ideal system for studying ZGA transcription regulation. Recently, the transcription factor Dux, expressed exclusively in the minor wave of ZGA, was described to activate many downstream ZGA transcripts. However, it remains unknown what upstream maternal factors initiate ZGA either in a Dux dependent or independent manner. Here we performed a candidate-based overexpression screen, identifying, amongst others, Developmental Pluripotency Associated 2 (Dppa2) and 4 (Dppa4) as positive regulators of 2C-like cells and ZGA transcription. In the germ line, promoter DNA demethylation coincides with upregulation of Dppa2 and Dppa4 which remain expressed until E7.5 when their promoters are remethylated. Furthermore, Dppa2 and Dppa4 are also expressed during iPSC reprogramming at the time 2C-like ZGA transcription transiently peaks. Through a combination of overexpression, knockdown, knockout and rescue experiments, together with transcriptional analyses, we show that Dppa2 and Dppa4 directly regulate the 2C-like cell population and associated transcripts, including Dux and the Zscan4 cluster. Importantly, we tease apart the molecular hierarchy in which the 2C-like transcriptional program is initiated and stabilised. Dppa2 and Dppa4 require Dux to initiate 2C-like ZGA transcription, suggesting they act upstream by directly regulating Dux. Supporting this, ChIP-seq analysis revealed Dppa2 and Dppa4 bind to the Dux promoter and gene body and drive its expression. Zscan4c is also able to induce 2C-like cells in wild type cells, but, in contrast to Dux, can no longer do so in Dppa2/4 double knockout cells, suggesting it may act to stabilise rather than drive the transcriptional network. Our findings suggest a model in which Dppa2/4 binding to the Dux promoter leads to Dux upregulation and activation of the 2C-like transcriptional program which is subsequently reinforced by Zscan4c.

Project description:The molecular regulation of zygotic genome activation (ZGA) in mammals remains poorly understood. Primed mouse embryonic stem cells contain a rare subset of “2C-like” cells that are epigenetically and transcriptionally similar to the two cell embryo and thus represent an ideal system for studying ZGA transcription regulation. Recently, the transcription factor Dux, expressed exclusively in the minor wave of ZGA, was described to activate many downstream ZGA transcripts. However, it remains unknown what upstream maternal factors initiate ZGA either in a Dux dependent or independent manner. Here we performed a candidate-based overexpression screen, identifying, amongst others, Developmental Pluripotency Associated 2 (Dppa2) and 4 (Dppa4) as positive regulators of 2C-like cells and ZGA transcription. In the germ line, promoter DNA demethylation coincides with upregulation of Dppa2 and Dppa4 which remain expressed until E7.5 when their promoters are remethylated. Furthermore, Dppa2 and Dppa4 are also expressed during iPSC reprogramming at the time 2C-like ZGA transcription transiently peaks. Through a combination of overexpression, knockdown, knockout and rescue experiments, together with transcriptional analyses, we show that Dppa2 and Dppa4 directly regulate the 2C-like cell population and associated transcripts, including Dux and the Zscan4 cluster. Importantly, we tease apart the molecular hierarchy in which the 2C-like transcriptional program is initiated and stabilised. Dppa2 and Dppa4 require Dux to initiate 2C-like ZGA transcription, suggesting they act upstream by directly regulating Dux. Supporting this, ChIP-seq analysis revealed Dppa2 and Dppa4 bind to the Dux promoter and gene body and drive its expression. Zscan4c is also able to induce 2C-like cells in wild type cells, but, in contrast to Dux, can no longer do so in Dppa2/4 double knockout cells, suggesting it may act to stabilise rather than drive the transcriptional network. Our findings suggest a model in which Dppa2/4 binding to the Dux promoter leads to Dux upregulation and activation of the 2C-like transcriptional program which is subsequently reinforced by Zscan4c.