Project description:Histone modifications regulate gene expression and development. To address how they are reprogrammed in human early development, we investigated key histone marks in human oocytes and early embryos. Unlike that in mouse, the permissive mark H3K4me3 largely exhibits canonical patterns at promoters in human oocytes. After fertilization, pre-zygotic genome activation (ZGA) embryos acquire permissive chromatin and widespread H3K4me3 in CpG-rich regulatory regions. By contrast, the repressive mark H3K27me3 undergoes global depletion. CpG-rich regulatory regions then resolve to either active or repressed states upon ZGA, followed by subsequent restoration of H3K27me3 at developmental genes. Finally, through combining chromatin and transcriptome maps, we revealed transcription circuitry and asymmetric H3K27me3 patterning during early lineage specification. Collectively, our data unveil a priming phase connecting human parental-to-zygotic epigenetic transition.

Project description:The maternal to zygotic transition (MZT) involves the transfer of genome regulation from the oocyte to the embryo and is essential for the formation of totipotent embryos. However, regulatory mechanisms are still poorly understood despite recent progress in mapping the dynamics in RNA transcripts and DNA methylation1-9. Previous studies suggest that dynamic histone modifications may play important roles in MZT10-12, however direct measurements of chromatin states has been hindered by technical difficulties in profiling histone modifications from small quantities of cells. We have developed a micro-scale chromatin immunoprecipitation and sequencing (μChIP-seq) method and used it to profile histone H3 lysine methylation (H3K4me3) and acetylation (H3K27ac) genome-wide in the mouse oocyte, 2- cell and 8-cell stage embryo. Strikingly, we show that ~22% of the oocyte genome is associated with broad H3K4me3 domains that are anti-correlated with DNA methylation. Most H3K4me3 signal is rapidly lost and constricted to TSS regions in 2-cell embryos, concomitant with the onset of major zygotic genome activation (ZGA). We provide evidence that these broad H3K4me3 domains are established by Mll2 and actively removed by Kdm5a and Kdm5b, and likely play instrumental roles in MZT by defining regions of DNA demethylation in oocytes and the 2-cell embryo. Furthermore, broad H3K4me3 domains specify H3K27ac patterns in the early embryo and ZGA genes are generally related to broad H3K4me3 domains, suggesting a fundamental role in MZT. Our results provide insights into how the developmental program can be set up in the oocyte and transferred to the zygotic genome.

Project description:The oocyte-to-embryo transition converts terminally differentiated gametes into a totipotent embryo. Fertilized embryos undergo the resetting of the transcriptional program as the zygotic genome is activated from a silenced state started from the late-stage oocyte. How transcriptome, translatome, and proteome interplay in this critical developmental window remains poorly understood. Utilizing a highly sensitive mass spectrometry, we obtained high-quality proteome landscapes including nearly 6,000 genes spanning 10 stages, from the mouse full-grown oocyte (FGO) to blastocyst, using 100 oocytes/embryos at each stage. By integrative analysis with corresponding transcriptomes and translatomes, we found transcription and translation levels can not reflect protein abundance in most cases. From FGOs to the 4-cell embryos, the proteomes are predominated by FGO-produced proteins, while the transcriptome and the translatome are much more dynamic. FGO-originated proteins frequently persist in embryos after the corresponding transcripts are already downregulated or decayed. Improved concordance between protein and RNA is observed for genes starting translation only upon meiotic resumption or transcribed only in embryos, although the detected protein dynamics often lag behind transcription and translation. Concordance between protein and transcription/translation is associated with protein half-lives. Finally, a kinetic model well predicts protein dynamics when incorporating both the initial protein abundance in FGO and translation kinetics across developmental stages. In sum, our study reveals multilayer control of gene expression during oocyte maturation and embryogenesis.

Project description:Conservation and species specificity are both unveiled in the reprogramming process of epigenetic modifications in early embryos. Pig is important agricultural livestock that closely related to human life and understanding the mechanisms of epigenetic reprogramming in porcine embryos could be assistive to the pig breeding industry and also informative to human embryo research. Nevertheless, current knowledge of epigenetic reprogramming in porcine embryos is elusive. We profile H3K4me3, H3K27me3, and H3K27ac modifications in porcine oocytes and preimplant embryos. Our data reveal the existence of unusual broad H3K4me3 domains not only in oocytes but also expanded in pre-ZGA embryos and demonstrates the extensive transitions of unusual broad H3K4me3 domains and their roles during embryogenesis. Notably, broad H3K27me3 and H3K27ac enriched domains are found to be preferably colocalized in these broad H3K4me3 domains when comparing to it in mice and human. By knocking down KDM5B in pig embryos, cleavage and developments were disrupted as demonstrated in mouse.

Project description:Reprogramming of histone modification regulates gene expression and mammal preimplantation development. Trimethylation of lysine 4 on histone 3 (H3K4me3) has unique landscape in mouse oocytes and early embryos. However, the dynamics and function of H3K4me3 in livestock embryos remain unclear. To address how it is reprogrammed in domestic animals, we profiled changes of H3K4me3 during bovine early embryo development. Notably, the overall signal of H3K4me3 decreased during embryonic genome activation (EGA). By utilizing ultra-low-input native ChIP-seq (ULI-NChIP-seq) technology, we observed widespread broad H3K4me3 domains in oocytes and embryos. The signal of broad H3K4me3 began to decrease after fertilization and was lowest after EGA. Along with the removal of broad H3K4me3, deposition of H3K4me3 at promoter regions enhanced gradually. Besides, the transcriptional activity and signal of promoter H3K4me3 showed positive correlation after the erasure of broad H3K4me3 at 16-cell stage. Moreover, knocking down of demethylases KDM5A, KDM5B and KDM5C caused EGA delay and blastocyst formation failure. RNA-seq analysis revealed 47.8% down-regulated genes in knockdown embryos at 8/16-cell stage were EGA genes, and 63.1% of up-regulated genes were maternal transcripts. Particularly, the positive correlation between transcriptional activity and promoter H3K4me3 during EGA was restrained when knocking down of KDM5A, KDM5B and KDM5C. Overall, our work initiatively mapped the genomic reprogramming of H3K4me3 during bovine preimplantation development, and KDM5A/B/C played roles in modulating oocyte-to-embryonic transition (OET) through timely erasure of broad H3K4me3 domains far away from promoters.

Project description:Reprogramming of histone modification regulates gene expression and mammal preimplantation development. Trimethylation of lysine 4 on histone 3 (H3K4me3) has unique landscape in mouse oocytes and early embryos. However, the dynamics and function of H3K4me3 in livestock embryos remain unclear. To address how it is reprogrammed in domestic animals, we profiled changes of H3K4me3 during bovine early embryo development. Notably, the overall signal of H3K4me3 decreased during embryonic genome activation (EGA). By utilizing ultra-low-input native ChIP-seq (ULI-NChIP-seq) technology, we observed widespread broad H3K4me3 domains in oocytes and embryos. The signal of broad H3K4me3 began to decrease after fertilization and was lowest after EGA. Along with the removal of broad H3K4me3, deposition of H3K4me3 at promoter regions enhanced gradually. Besides, the transcriptional activity and signal of promoter H3K4me3 showed positive correlation after the erasure of broad H3K4me3 at 16-cell stage. Moreover, knocking down of demethylases KDM5A, KDM5B and KDM5C caused EGA delay and blastocyst formation failure. RNA-seq analysis revealed 47.8% down-regulated genes in knockdown embryos at 8/16-cell stage were EGA genes, and 63.1% of up-regulated genes were maternal transcripts. Particularly, the positive correlation between transcriptional activity and promoter H3K4me3 during EGA was restrained when knocking down of KDM5A, KDM5B and KDM5C. Overall, our work initiatively mapped the genomic reprogramming of H3K4me3 during bovine preimplantation development, and KDM5A/B/C played roles in modulating oocyte-to-embryonic transition (OET) through timely erasure of broad H3K4me3 domains far away from promoters.

Project description:Multicellular organism requires concise gene regulation during ontogeny and epigenetic modifications, such as DNA methylation and histone modification, facilitate the concise regulation. The conservative reprogramming patterns of DNA methylation in vertebrates have been well described but knowledge of how histone modifications are passed on to zygote from gametes are limited and conservations of histone modifications are not clear.We profiled H3K4me3/H3K27me3 modifications in gametes and early embryos in zebrafish and find out that patterns in gene promoter regions have been largely set to either bivalent or active states in gametes and then passed on to zygote. Bivalent states are partially maintained and active states are restored to match sperm’s pattern. But repressive H3K27me3 modifications as well as stage specific modifications in promoter regions are discarded. Prior to zygotic genome activation, patterns of genes that initialize ZGA have been converted to non-repressive states to coordinate gene expression. Histone modification in hyper methylated promoter peaks are erased independent of DNA methylome reprogramming. Comparative analysis revealed that functions of bivalent and active genes passed on from gametes are conserved in vertebrates and gene age preferences by bivalent and active histone modifications are also confirmed in vertebrates.

Project description:Early embryos undergo extensive epigenetic reprogramming to achieve gamete-to-embryo transition, which involves the loading and removal of histone variant H2A.Z on chromatin. Although the H2A.Z landscapes in sperm have been investigated, its dynamics during early development remain unrevealed. Here, by using ultra-low-input native chromatin immunoprecipitation and sequencing (ULI-NChIP-seq), we map the genome-wide distribution of H2A.Z in mouse oocytes and early embryos. We find that paternal H2A.Z is removed upon fertilization, followed by unbiased accumulation on parental genomes during zygotic genome activation (ZGA). More importantly, H2A.Z exhibits hierarchical accumulation as different peak types at promoters. We identify that double H2A.Z peaks co-localizes with H3K4me3 and facilitates transcriptional activation, bivalent markers (H3K4me3+H3K27me3) prefer to occupy single H2A.Z peak and inhibits developmental gene expression, while promoters with no H2A.Z accumulation exhibit gene silencing in early embryos. Remarkably, H2A.Z depletion changes the enrichments of histone modifications and RNA polymerase II (Pol II) binding at promoters, resulting in abnormal gene expression and developmental arrest during lineage commitment. Hence, H2A.Z plays dual roles in regulating the epigenomes required for proper gene expression during preimplantation development.

Project description:Early embryos undergo extensive epigenetic reprogramming to achieve gamete-to-embryo transition, which involves the loading and removal of histone variant H2A.Z on chromatin. Although the H2A.Z landscapes in sperm have been investigated, its dynamics during early development remain unrevealed. Here, by using ultra-low-input native chromatin immunoprecipitation and sequencing (ULI-NChIP-seq), we map the genome-wide distribution of H2A.Z in mouse oocytes and early embryos. We find that paternal H2A.Z is removed upon fertilization, followed by unbiased accumulation on parental genomes during zygotic genome activation (ZGA). More importantly, H2A.Z exhibits hierarchical accumulation as different peak types at promoters. We identify that double H2A.Z peaks co-localizes with H3K4me3 and facilitates transcriptional activation, bivalent markers (H3K4me3+H3K27me3) prefer to occupy single H2A.Z peak and inhibits developmental gene expression, while promoters with no H2A.Z accumulation exhibit gene silencing in early embryos. Remarkably, H2A.Z depletion changes the enrichments of histone modifications and RNA polymerase II (Pol II) binding at promoters, resulting in abnormal gene expression and developmental arrest during lineage commitment. Hence, H2A.Z plays dual roles in regulating the epigenomes required for proper gene expression during preimplantation development.

Project description:Upon fertilization, drastic chromatin reorganization occurs during human preimplantation development. However, the global chromatin landscape and its molecular dynamics in this period remain largely unexplored. Deciphering such process is crucial for understanding both early human development and in vitro fertilization. Here, we investigated genome-wide chromatin accessibility in human preimplantation embryos by employing an improved ATAC-seq that uses as few as 20 cells. We found widespread accessible chromatin in early human embryos that overlaps extensively with putative cis-regulatory sequences and transposable elements. Integrative analyses showed both conservation and divergence in regulatory circuitry between human and mouse early development, and between naïve human pluripotency in vivo and human embryonic stem cells. Surprisingly, we also found widespread open chromatin at the 2-cell stage despite its minimal transcription activities. Such accessible chromatin loci are readily found at CpG-rich promoters. Unexpectedly, many others are located in distal regions enriched for transcription factor binding sites and overlap with partially methylated domains (PMDs) in human oocytes. A large portion of these regions then rapidly become inaccessible upon zygotic genome activation (ZGA). Importantly, such drastic transition of chromatin accessibility during ZGA is well conserved in mouse embryos. Furthermore, it strongly correlates with the reprogramming of non-canonical H3K4me3 (ncH3K4me3), a form of histone mark that is uniquely present in oocytes and pre-ZGA embryos and contributes to genome silencing. Finally, both the reprogramming of chromatin accessibility and ncH3K4me3 during ZGA is completely blocked upon transcription inhibition, indicating a critical role of zygotic transcription in shaping early epigenomes. Together, these data revealed conserved chromatin state transition during ZGA in human and mouse early development.