Academic literature on the topic 'ZGA, 2C-like cell'

Zinc finger protein Zscan4 is selectively expressed in mouse two-cell (2C) embryos undergoing zygotic genome activation (ZGA) and in a rare subpopulation of embryonic stem cells with 2C-like features. Here, we show that Zscan4 specifically recognizes a subset of (CA)n microsatellites, repeat sequences prone to genomic instability. Zscan4-associated microsatellite regions are characterized by low nuclease sensitivity and high histone occupancy. In vitro, Zscan4 binds nucleosomes and protects them from disassembly upon torsional strain. Furthermore, Zscan4 depletion leads to elevated DNA damage in 2C mouse embryos in a transcription-dependent manner. Together, our results identify Zscan4 as a DNA sequence–dependent microsatellite binding factor and suggest a developmentally regulated mechanism, which protects fragile genomic regions from DNA damage at a time of embryogenesis associated with high transcriptional burden and genomic stress.

Minor splicing plays an important role in vertebrate development. Zrsr1 and Zrsr2 paralog genes have essential roles in alternative splicing, mainly participating in the recognition of minor (U12) introns. To further explore their roles during early embryo development, we produced Zrsr1mu and Zrsr2mu mutant mice, containing truncating mutations within the second zinc finger domain. Both homozygous mutant mice were viable with a normal lifespan. When we crossed a homozygous Zrsr2mu/mu female with Zrsr1mu/mu male, the double heterozygotes were non-viable, giving rise to embryos that stopped developing mainly between the 2- and 4-cell stages, just after zygotic gene activation. RNA-seq analysis of Zrsr1/2mu 2-cell embryos showed altered gene and isoform expression of thousands of genes enriched in gene ontology terms and biological pathways related to ribosome, RNA transport, spliceosome, and essential zygotic gene activation steps. Alternative splicing was analyzed, showing a significant increase in intron retention in both U2 and U12 intron-containing genes related to cell cycle and mitotic nuclear division. Remarkably, both Zrsr1 and Zrsr2 were required for the conversion of mouse-induced pluripotent stem cells into 2C-like cells. According to our results, Zrsr1 or Zrsr2 are necessary for ZGA and both are indispensable for the conversion of induced pluripotent stem cells into 2C-like cells.

ABSTRACT How maternal factors in oocytes initiate zygotic genome activation (ZGA) remains elusive in mammals, partly due to the challenge of de novo identification of key factors using scarce materials. Two-cell (2C)-like cells have been widely used as an in vitro model in order to understand mouse ZGA and totipotency because of their expression of a group of two-cell embryo-specific genes and their simplicity for genetic manipulation. Recent studies indicate that DPPA2 and DPPA4 are required for establishing the 2C-like state in mouse embryonic stem cells in a DUX-dependent manner. These results suggest that DPPA2 and DPPA4 are essential maternal factors that regulate Dux and ZGA in embryos. By analyzing maternal knockout and maternal-zygotic knockout embryos, we unexpectedly found that DPPA2 and DPPA4 are dispensable for Dux activation, ZGA and pre-implantation development. Our study suggests that 2C-like cells do not fully recapitulate two-cell embryos in terms of regulation of two-cell embryo-specific genes, and, therefore, caution should be taken when studying ZGA and totipotency using 2C-like cells as the model system.

Mouse embryonic stem cells (ESCs) contain a rare cell population of “two-cell embryonic like” cells (2CLCs) that display similar features to those found in the two-cell (2C) embryo and thus represent an in vitro model for studying the progress of zygotic genome activation (ZGA). However, the positive regulator determinants of the 2CLCs’ conversion and ZGA have not been completely elucidated. Here, we identify a new regulator promoting 2CLCs and ZGA transcripts. Through a combination of overexpression (OE), knockdown (KD), together with transcriptional analysis and methylome analysis, we find that Dppa3 regulates the 2CLC-associated transcripts, DNA methylation, and 2CLC population in ESCs. The differentially methylated regions (DMRs) analysis identified 6,920 (98.2%) hypomethylated, whilst only 129 (1.8%) hypermethylated, regions in Dppa3 OE ESCs, suggesting that Dppa3 facilitates 2CLCs reprogramming. The conversion to 2CLCs by overexpression of Dppa3 is also associated with DNA damage response. Dppa3 knockdown manifest impairs transition into the 2C-like state. Global DNA methylome and chromatin state analysis of Dppa3 OE ESCs reveal that Dppa3 facilitates the chromatin configuration to 2CLCs reversion. Our finding for the first time elucidates a novel role of Dppa3 in mediating the 2CLC conversion, and suggests that Dppa3 is a new regulator for ZGA progress.

Abstract Two-cell-like (2C-like) embryonic stem cells (ESCs) are a small group of ESCs that spontaneously express zygotic genome activation (ZGA) genes and repeats, such as Zscan4 and murine endogenous retrovirus with leucine (MERVL), and are specifically expressed in 2-cell-stage mouse embryos. Although numerous types of treatment and agents elevate the transition of ESCs to 2C-like ESCs, Dux serves as a critical factor in this transition by increasing the expression of Zscan4 and MERVL directly. However, the loss of Dux did not impair the birth of mice, suggesting that Dux may not be the primary transitioning factor in fertilized embryos. It has been reported that for 2-cell embryos derived from somatic cell nuclear transfer (SCNT) and whose expression of ZGA genes and repeats was aberrant, Dux improved the reprogramming efficiency by correcting aberrant H3K9ac modification via its C-terminal domain. We confirmed that the overexpression of full-length Dux mRNA in SCNT embryos improved the efficiency of preimplantation development (62.16% vs. 41.26% with respect to controls) and also increased the expression of Zscan4 and MERVL. Furthermore, we found that the N-terminal double homeodomains of Dux were indispensable for Dux localization and function. The intermediate region was essential for MERVL and Zscan4 activation, and the C-terminal domain was important for elevating level of H3K27ac. Mutant Dux mRNA containing N-terminal double homeodomains with the intermediate region or the C-terminal domain also improved the preimplantation development of SCNT embryos. This is the first report focusing on distinguishing functional domains of Dux in embryos derived from SCNT.

Embryonic stem cells (ESCs) are characterized by a rapid cell cycle, which leads to high replication stress (RS) in otherwise unperturbed conditions. The mechanisms that ESCs adopt to cope with their endogenous RS, however, remain to this day elusive. In our recent work we demonstrated that the activation of the checkpoint kinase ATR in response to RS leads to a broad activation of 2-cells stage specific genes in mouse ESCs. This response relies on the up-regulation of Dux, a transcription factor encoded in a macrosatellite sequence repeated in tandem. Dux is repressed by variant Polycomb repressive complex 1 (vPRC1) in unperturbed ESCs, independently from PRC2 presence. Here we demonstrate that RS causes a major rearrangement of both PRC1 and PRC2 in ESCs nuclei, resulting in a major loss of both repressive marks in correspondence to target promoters. Surprisingly, Dux undergoes an increase in vPRC1 occupancy upon RS in an ATR-dependent manner, possibly due to PRC1 involvement in the replication of highly repeated DNA sequences. More interestingly, Dux activation upon RS requires the presence of PRC2. This result is possibly due to PRC2 proved role in the processing of stalled replication forks, which are the main structure signaling RS. In agreement to this data, also the fork remodeling translocases HLTF and ZRANB3 displayed an effect in Dux activation following RS. Taken together, our results show that the up-regulation of 2-cells genes following RS not only requires ATR activation, but also downstream remodeling processes.