Project description:Proteogenomic Reprogramming to a Functional Human Blastomere-like Stem Cell State via a PARP-DUX4 Regulatory Axis; Zimmerlin et al, 2024. PARP1 (ARTD1) and Tankyrases (TNKS1/TNKS2; PARP5a/5b) are poly-ADP-ribose polymerases (PARPs) with catalytic and non-catalytic functions that regulate both the genome and proteome during zygotic genome activation (ZGA), totipotent, and pluripotent embryonic stages. Here, we show that primed, conventional human pluripotent stem cells (hPSC) cultured continuously under non-specific TNKS1/TNKS2/PARP1-inhibited chemical naïve reversion conditions underwent epigenetic reprogramming to clonal blastomere-like stem cells. TIRN stem cells concurrently expressed hundreds of gene targets of the ZGA-priming pioneer factor DUX4, as well as a panoply of four-cell (4C)-specific (e.g., TPRXL, HOX clusters), eight-cell (8C)-specific (e.g., DUXA, GSC, GATA6), primitive endoderm-specific (e.g., GATA4, SOX17), trophectoderm-specific (e.g., CDX2, TFAP2C), and naïve epiblast-specific (e.g., DNMT3L, NANOG, POU5F1(OCT4)) factors; all in a hybrid, combinatorial single-cell manner. Mapping of proteomic and single-cell expressions of TIRN cells against human preimplantation embryo references identified them as relatively homogenous 4C-8C stage populations. The bulk RNA-seq and proteomics analyses of TIRN cells (+/- iDUX4) revealed acquisition of pre-lineage embryonic transcriptional programs. To determine if TIRN +/- iDUX4 cells were mixed populations or clonal blastomere-like cells, single cell (sc)RNA-seq was performed to investigate transcriptional heterogeneity at a single cell level. Overall, single, unmodified TIRN cells shared high transcriptional identity with single TIRN+iDUX4 cells, and single primed hPSC and TIRN +/- iDUX4 cells expressed comparable and uniformly homogenous levels of core pluripotency factors (e.g., NANOG, POU5F1 (OCT4), SOX2, KLF4, CMYC). However, single TIRN and TIRN+iDUX4 populations homogenously co-expressed not only higher levels of naïve ICM-specific genes (e.g., DNMT3L, SP5, ERVH48-1, GDF3, and IFITM1) (Park et al., 2020; Zimmerlin et al., 2016), but also hundreds of diverse and antagonistic lineage-specifying genes (e.g., HOX-PRD, T-BOX, FOX, GATA families) that are co-expressed simultaneously only during 4C-to-morula human embryonic stages (Petropoulos et al., 2016; Zou et al., 2022). Transcript levels of 4C-specific (i.e., TPRXL, HOXA1, EBF2), 8C-specific (i.e., GATA6, FOXB1), trophectoderm lineage-specific (i.e., CDX2, TFAP2C), and endoderm lineage-specific (i.e., GATA4, SOX17) pioneer factors were co-expressed in the same single cell populations; with expressions that were further augmented following iDUX4 activation.

Project description:Proteogenomic Reprogramming to a Functional Human Blastomere-like Stem Cell State via a PARP-DUX4 Regulatory Axis; Zimmerlin et al, 2024. PARP1 (ARTD1) and Tankyrases (TNKS1/TNKS2; PARP5a/5b) are poly-ADP-ribose polymerases (PARPs) with catalytic and non-catalytic functions that regulate both the genome and proteome during zygotic genome activation (ZGA), totipotent, and pluripotent embryonic stages. Here, we show that primed, conventional human pluripotent stem cells (hPSC) cultured continuously under non-specific TNKS1/TNKS2/PARP1-inhibited chemical naïve reversion conditions underwent epigenetic reprogramming to clonal blastomere-like stem cells. TIRN stem cells concurrently expressed hundreds of gene targets of the ZGA-priming pioneer factor DUX4, as well as a panoply of four-cell (4C)-specific (e.g., TPRXL, HOX clusters), eight-cell (8C)-specific (e.g., DUXA, GSC, GATA6), primitive endoderm-specific (e.g., GATA4, SOX17), trophectoderm-specific (e.g., CDX2, TFAP2C), and naïve epiblast-specific (e.g., DNMT3L, NANOG, POU5F1(OCT4)) factors; all in a hybrid, combinatorial single-cell manner. Mapping of proteomic and single-cell expressions of TIRN cells against human preimplantation embryo references identified them as relatively homogenous 4C-8C stage populations. The bulk RNA-seq and proteomics analyses of TIRN cells (+/- iDUX4) revealed acquisition of pre-lineage embryonic transcriptional programs. To determine if TIRN +/- iDUX4 cells were mixed populations or clonal blastomere-like cells, single cell (sc)RNA-seq was performed to investigate transcriptional heterogeneity at a single cell level. Overall, single, unmodified TIRN cells shared high transcriptional identity with single TIRN+iDUX4 cells, and single primed hPSC and TIRN +/- iDUX4 cells expressed comparable and uniformly homogenous levels of core pluripotency factors (e.g., NANOG, POU5F1 (OCT4), SOX2, KLF4, CMYC). However, single TIRN and TIRN+iDUX4 populations homogenously co-expressed not only higher levels of naïve ICM-specific genes (e.g., DNMT3L, SP5, ERVH48-1, GDF3, and IFITM1) (Park et al., 2020; Zimmerlin et al., 2016), but also hundreds of diverse and antagonistic lineage-specifying genes (e.g., HOX-PRD, T-BOX, FOX, GATA families) that are co-expressed simultaneously only during 4C-to-morula human embryonic stages (Petropoulos et al., 2016; Zou et al., 2022). Transcript levels of 4C-specific (i.e., TPRXL, HOXA1, EBF2), 8C-specific (i.e., GATA6, FOXB1), trophectoderm lineage-specific (i.e., CDX2, TFAP2C), and endoderm lineage-specific (i.e., GATA4, SOX17) pioneer factors were co-expressed in the same single cell populations; with expressions that were further augmented following iDUX4 activation.

Project description:Zygotic genome activation (ZGA) marks the beginning of the embryonic program for a totipotent embryo, which gives rise to inner cell mass (ICM), where pluripotent epiblast arises, and extraembryonic trophectoderm. While much has been learned about pluripotency regulation, how ZGA is connected to the first lineage segregation in early embryos remains elusive. Here, we investigated the role of nuclear receptor transcription factors (NR TFs), whose motifs are highly enriched in accessible chromatin at the 2-cell (2C) to 8-cell (8C) stages after ZGA. We found NR5A2, an NR TF highly induced upon ZGA, is required for early development. Genome-wide chromatin binding in 2C and 8C embryos showed NR5A2 bound cis-regulatory elements which strongly enrich B1 elements where its motif is embedded. RNA-seq showed while the zygotic genome was largely activated at the 2C stage, 4-8C-specific gene activation was substantially impaired in Nr5a2 KD embryos. At the 8C stage, NR5A2 preferentially regulated its targets including a subset of early ICM genes. Consistently, NR5A2 was required for opening 8C-specific binding sites. Interestingly, while NR5A2’s 2C-binding sites are largely closed in blastocyst, 8C-specific binding sites tend to stay open and are bound by master pluripotency TFs (NANOG, SOX2, and OCT4) in blastocyst or ESC. Further analyses showed NR5A2 regulates early ICM genes at the 8C stage, master pluripotency TFs regulate both early and late ICM genes at later stages. Taken together, these data identify NR5A2 as a key regulator in totipotent embryos that connects ZGA to the first lineage segregation in early mouse development.

Project description:After fertilization, zygotic genome activation (ZGA) enables the conversion of two terminally differentiated gametes to a totipotent embryo. Zygotes further give rise to the pluripotent embryonic lineages and extraembryonic trophectoderm after the first lineage commitment. While much is learned for pluripotency regulation, how ZGA is connected to the pluripotency commitment in early embryos remains unclear. Here, we investigated the role of nuclear receptor (NR) family TFs in mouse pre-implantation embryos, whose motifs are highly enriched in accessible chromatin at the 2-cell (2C) to 8-cell (8C) stages. We found NR5A2 is required for the early development, as both knockdown and knockout of Nr5a2 led to morula arrest. 4-8C activated genes (mid-preimplantation activation), including key pluripotency marker genes (i.e. Nanog, Pou5f1, and Tdgf1) and trophectoderm genes (i.e. Klf5, Elf3, and Gata3). Genome-wide chromatin binding and RNA-seq analyses showed NR5A2 bound and regulated the 4-8C genes, including both ICM and TE genes in 2C and 8C embryos , indicating its roles in bipotency program. Interestingly, NR5A2 occupied sites predominantly reside in accessible B1 elements where its motif is embedded at the 2-8C stage. Taken together, these data demonstrate the role of NR5A2 as a key regulator that bridges ZGA to lineage segregation.

Project description:The transcription factor DUX4 regulates a portion of the zygotic gene activation (ZGA) program in the early embryo. Many cancers express DUX4 but it is unknown whether this generates cells similar to early embryonic stem cells. Here we identify cancer cell lines that express DUX4 and show that DUX4 is transiently expressed in a small subset of the cells. DUX4 expression activates the ZGA transcriptional program, the subsequent 8C-like program, and markers of early embryonic lineages; while suppressing steady-state and interferon-induced MHC class I expression. Although DUX4 was expressed in a small number of cells under standard culture conditions, DNA damage or changes in growth conditions dramatically increased the fraction of cells expressing DUX4 and its downstream programs. Demonstrating that the transient expression of endogenous DUX4 in cancer cells induces a metastable early embryonic stem cell program and suppresses antigen presentation has implications for cancer growth, progression, and immune evasion.

Project description:In human embryos, major zygotic genome activation (ZGA) initiates at the eight-cell (8C) stage. Abnormal ZGA leads to developmental defects and even contributes to the failure of human blastocyst formation or implantation. However, little is known about the mechanisms regulating human ZGA, because of many challenges and constraints on research on human embryos. Here we report one type of rare 8C-like cells (8CLCs) that are discovered specifically from human preimplantation epiblast-like stem cells (prEpiSCs) and naïve embryonic stem cells. 8CLCs express a list of human ZGA genes and their transcriptome closely resemble that of the human 8C embryo. An 8C-specific reporter is further developed to isolate 8CLCs from prEpiSCs and optimize the chemical-based culture condition that increases and maintains the 8CLC population. Functionally, 8CLCs can spontaneously form blastocyst-like structures. The discovery and maintenance of 8CLCs provides an opportunity to model human ZGA and recapitulate early human development.

Project description:In human embryos, major zygotic genome activation (ZGA) initiates at the eight-cell (8C) stage. Abnormal ZGA leads to developmental defects and even contributes to the failure of human blastocyst formation or implantation. However, little is known about the mechanisms regulating human ZGA, because of many challenges and constraints on research on human embryos. Here we report one type of rare 8C-like cells (8CLCs) that are discovered specifically from human preimplantation epiblast-like stem cells (prEpiSCs) and naïve embryonic stem cells. 8CLCs express a list of human ZGA genes and their transcriptome closely resemble that of the human 8C embryo. An 8C-specific reporter is further developed to isolate 8CLCs from prEpiSCs and optimize the chemical-based culture condition that increases and maintains the 8CLC population. Functionally, 8CLCs can spontaneously form blastocyst-like structures. The discovery and maintenance of 8CLCs provides an opportunity to model human ZGA and recapitulate early human development.

Project description:In human embryos, major zygotic genome activation (ZGA) initiates at the eight-cell (8C) stage. Abnormal ZGA leads to developmental defects and even contributes to the failure of human blastocyst formation or implantation. However, little is known about the mechanisms regulating human ZGA, because of many challenges and constraints on research on human embryos. Here we report one type of rare 8C-like cells (8CLCs) that are discovered specifically from human preimplantation epiblast-like stem cells (prEpiSCs) and naïve embryonic stem cells. 8CLCs express a list of human ZGA genes and their transcriptome closely resemble that of the human 8C embryo. An 8C-specific reporter is further developed to isolate 8CLCs from prEpiSCs and optimize the chemical-based culture condition that increases and maintains the 8CLC population. Functionally, 8CLCs can spontaneously form blastocyst-like structures. The discovery and maintenance of 8CLCs provides an opportunity to model human ZGA and recapitulate early human development.

Project description:To investigate whether rat adult hepatocytes would exhibit different characteristics dependent on their ploidy statuses, we compared the transcriptome profile of 2c, 4c and 8c hepatocytes by mRNA microarray.

Project description:Upon fertilization, the embryonic genome remains transcriptionally inactive until the mid-blastula transition. Zygotic genome activation (ZGA) of vertebrate embryos has been extensively studied using nucleic acid-based strategies, but proteomics data are still scarce, impeding the full mechanistic understanding of how ZGA is executed during the maternal-to-zygotic transition (MZT). Here, we performed quantitative proteomics to decipher the proteome landscape of zebrafish embryos during the MZT, quantifying nearly 5,000 proteins across four embryonic stages. The stage-specific clustering based on protein expression pattern revealed that helicases (i.e., eif4a2 and ruvbl1) facilitate pluripotency factors (i.e., nanog, pou5f3, ctcf, and hmga1) triggering ZGA in zebrafish, accompanied by the maternal product decay with P-bodies and ubiquitin dependent proteolytic pathway. Dozens of transcription factors show wave-like expression patterns during MZT, implying their diverse functions in triggering the ZGA and modulating differentiation for organ development. The combination of morpholino knockdown and quantitative proteomics demonstrated that maternal Nanog is required for proper embryogenesis by regulating 1) interactions with other pluripotency factors, 2) F-actin band formation, 3) cell cycle checkpoints and 4) maternal product degradation. This study represents the most systematic proteomics survey of developmentally regulated proteins and their expression profiles accompanying MZT in zebrafish, which is a valuable proteome resource for understanding ZGA.