Project description:Understanding the mechanisms that regulate how the first cell lineages in human development are specified and maintained is of fundamental importance and has clinical implications for regenerative medicine, infertility and pregnancy loss. Decades of research in mouse models have provided valuable insights into the role of transcription factors that regulate early development, however translating these findings to human embryos has been limited by ethical, technical and biological constraints. Functional studies of key transcription factors in human embryos have been hindered by nuclease-based genome-editing approaches that often induce genotoxicity, such as aneuploidy1-3. To overcome this limitation, we applied adenine base editing (ABE8e)4,5 to efficiently and precisely target an exon splice donor site, resulting in a splicing defect and a functional knockout of the transcription factor NANOG. This work represents the first application of base editing to study a developmental regulator in human embryos. Importantly, we found this approach did not trigger genotoxicity. Loss of NANOG disrupts specification of the pluripotent epiblast and instead cells differentiate toward a yolk sac or placental-like transcriptional programme. The retention of yolk-sac progenitor cell differentiation in NANOG-edited human embryos reveals a functional compensation that is distinct from our observations in the mouse, underscoring the importance of direct investigation of human development. Altogether, our findings demonstrate an essential role for NANOG in human pluripotency and epiblast specification and highlights the utility of adenine base editing for precise functional interrogation of human development.

Project description:Understanding the mechanisms that regulate how the first cell lineages in human development are specified and maintained is of fundamental importance and has clinical implications for regenerative medicine, infertility and pregnancy loss. Decades of research in mouse models have provided valuable insights into the role of transcription factors that regulate early development, however translating these findings to human embryos has been limited by ethical, technical and biological constraints. Functional studies of key transcription factors in human embryos have been hindered by nuclease-based genome-editing approaches that often induce genotoxicity, such as aneuploidy1-3. To overcome this limitation, we applied adenine base editing (ABE8e)4,5 to efficiently and precisely target an exon splice donor site, resulting in a splicing defect and a functional knockout of the transcription factor NANOG. This work represents the first application of base editing to study a developmental regulator in human embryos. Importantly, we found this approach did not trigger genotoxicity. Loss of NANOG disrupts specification of the pluripotent epiblast and instead cells differentiate toward a yolk sac or placental-like transcriptional programme. The retention of yolk-sac progenitor cell differentiation in NANOG-edited human embryos reveals a functional compensation that is distinct from our observations in the mouse, underscoring the importance of direct investigation of human development. Altogether, our findings demonstrate an essential role for NANOG in human pluripotency and epiblast specification and highlights the utility of adenine base editing for precise functional interrogation of human development.

Project description:GW182 (Tnrc6a) is a key component of RISC (miRNA-Induced Silencing Complex) that plays a critical role in miRNA-mediated gene silencing. Here, we show that GW182 is expressed in the yolk sac endoderm, and that gene-trap disruption of GW182 leads to growth arrest of yolk sac endoderm, impaired hematopoiesis and embryonic lethality. To investigate roles of GW182 in the yolk sac endoderm, we assessed changes in mRNA expression in the yolk sac of E9.5 GW182gt/gt embryos using microarrays (Affymetrix). Yolk sac of wild type littermates and GW182gt/gt embryos at E9.5 was collected for total RNA isolation using Trizol (Invitrogen). RNAs were purified according to the manufacturer’s protocol before subjected to Mouse Gene 1.0 ST Whole Genome Array (Affymetrix) for mRNA expression profiling. Experiments were performed in triplicate. Differentially expressed mRNAs were identified using a two-sample t-test (P<0.05 considered significant).

Project description:The human definitive yolk sac is an important organ supporting the early developing embryo through nutrient supply and by facilitating the establishment of the embryonic circulatory system. However, the molecular and cellular biology of the human yolk sac remains largely obscure due to the lack of suitable in vitro models. Here, we show that human induced pluripotent stem cells (hiPSCs) co-cultured with various types of stromal cells as spheroids self-organize into yolk sac-like organoids without the addition of exogenous factors. Yolk sac-like organoids recapitulated a yolk sac specific cellular complement and structures as well as the functional ability to generate definitive hematopoietic progenitor cells (HPCs). Furthermore, sequential hemato-vascular ontogenesis could be observed during organoid formation. Notably, our organoid system can be performed in a scalable, autologous, and xeno-free condition, thereby providing an important model of human definitive yolk sac development and allows for efficient bulk generation of hiPSC-derived HPCs.

Project description:GW182 (Tnrc6a) is a key component of RISC (miRNA-Induced Silencing Complex) that plays a critical role in miRNA-mediated gene silencing. Here, we show that GW182 is expressed in the yolk sac endoderm, and that gene-trap disruption of GW182 leads to growth arrest of yolk sac endoderm, impaired hematopoiesis and embryonic lethality. To investigate roles of GW182 in the yolk sac endoderm, we assessed changes in mRNA expression in the yolk sac of E9.5 GW182gt/gt embryos using microarrays (Affymetrix).

Project description:Colibacillosis caused by avian pathogenic Escherichia coli (APEC) is a major disease syndrome in poultry with the yolk sac infection recognized as a leading factor contributing to embryonic mortality. Yolk sac is the initial site of infection, however its contribution in embryonic mortality at molecular level has remained unexplored. To address this critical gap, we conducted RNA sequencing (RNA-seq) to analyze the comprehensive in vivo transcriptomic profiles of yolk sac and embryonic liver from APEC-infected embryos, comparing dead embryos with those that survived and mock-infected controls, to uncover key differences in host responses in multiple scenarios. Our results revealed that dead embryos displayed significant pro-inflammatory cytokine activity and cellular senescence, disrupted lipid and energy metabolism, and compromised antioxidative defenses, particularly in the yolk sac. In contrast, surviving embryos exhibited a regulated inflammatory response, enhanced mitochondrial activity, robust antioxidative responses and tissue repair mechanisms, which likely underpinned its resilience. Notably, yolk sac showed positive correlation (r = 0.531) with the embryonic liver, but demonstrated more severe inflammation and metabolic dysregulation, thereby highlighting its heightened vulnerability. Furthermore, reactive oxygen species (ROS) levels, the balance of the inflammatory response, and yolk sac integrity are crucial determinants of embryonic survival, with mitochondrial dysfunction serving as a key regulator of host immune and metabolic adaptation. The insights provide a deeper understanding of the previously overlooked role of yolk sac compared to liver during APEC infection, offering potential avenues for improving host resilience and mitigating economic losses in poultry.

Project description:CIRHIN is a transcription co-factor, shows postive effect on Hiv-1 LTR enhancer element(NF-κB site); and Cirh1a null is preimplantation lethal, but highly expressed in the early mice embryo (E6.0-E12.5). We hypothesis that Cirh1a's effect on gene transcription of early embryo can be detected with Cirh1a down regulated in Cirh1a+/- state. Result shows that Cirh1a+/- has significant effect on early mice embryo gene transcription, Differentially expressed genes (DEGs) detected are mainly involved in cell proliferation/differenciation, cell cycle progress, embryo development and multi-orgnaogenesis. Littermate embryos (E8.5) were dissected into RNAlater reagent for total RNA extraction, and yolk sac was used for genotyping PCR. Littermate embryos (E9.5) were dissected into RNAlater reagent for total RNA extraction, and yolk sac was used for genotyping PCR. Liver buds from littermate embryos (E11.5) were dissected into RNAlater reagent for total RNA extraction, and yolk sac was used for genotyping PCR. Liver buds from littermate embryos were dissected into RNAlater reagent for total RNA extraction, and yolk sac was used for genotyping PCR.

Project description:Purpose: Next-generation sequencing (NGS) has revolutionized systems-based analysis of cellular pathways. The goals of this study are to compare NGS-derived yolk sac transcriptome profiling (RNA-seq) of E16.5 Rsu1-/- mouse embryos to that of the wild-type controls Methods: Yolk sac mRNA profiles of yolk sac isolated from E16.5 wild-type (WT) and ras suppressor 1 (Rsu1−/−) emdbryos were generated by deep sequencing, in triplicate, using Illumina Hiseq 2500 platform. The sequence reads that passed quality filters were were mapped to human reference genome GRCh38 by HISAT2 v2.2.1 with default parameters. Results: Using an optimized data analysis workflow, we mapped about 40 million sequence reads per sample to the mouse genome and identified ___ transcripts in the yolk sacs of E16.5 WT and Rsu1−/− embryos with HISAT2 v2.2.1 workflow . Approximately __ % of the transcripts showed differential expression between the WT and Rsu1−/− yolk sac, with a fold change ≥2.0 and p value <0.05. Altered expression of 12 genes was confirmed with qRT–PCR, demonstrating the high degree of sensitivity of the RNA-seq method. Conclusions: Our study represents the first detailed analysis of E16.5 Rsu1-/- yolk sac transcriptomes, which would expedite genetic network analyses and permit the dissection of complex biologic functions of Rsu1 during late embryogenesis.

Project description:The embryonic zebrafish is an ideal system for lipid analyses with relevance to many areas of bioscience research, including biomarkers and therapeutics. Research in this area has been hampered by difficulties in extracting, identifying and quantifying lipids. We employed 1H-NMR at 700MHz to profile lipids in developing zebrafish embryos. The optimal method for lipidomics in embryonic zebrafish incorporated rapid lipid extraction using chloroform and an environment without oxygen depletion. Pools of 10 embryos gave the most acceptable signal-to-noise ratio, and the inclusion of chorions in the sample had no significant effect on lipid abundances. Embryos, bisected into cranial (head and yolk sac) and caudal (tail) regions, were compared by principal component analysis and analysis of variance.

Project description:Investigating the blood, immune and stromal cells present in a human fetal embryo in a world first single cell transcriptomic atlas. The embryo was dissected into 12 coronal sections, yolk sac, and yolk sac stalk. Live single cells sorted, with cell suspension then undergoing 10x chromium 5 prime scRNA-seq. This accession contains the yolk sac and yolk sac stalk data from this embryo. A matched accession contains the coronal section data. Lane "WS_wEMB12142156" (from yolk sac) was excluded from downstream analysis due to low fraction reads in cells post-CellRanger QC. Termination procedure for this embryo was medical. The F158_[features...barcodes...matrix].[tsv...mtx].gz files attached to this accession represent raw count data from all the 10x lanes in this accession combined, and as output from CellRanger filtered matrices (CellRanger version 6.0.1 using human reference genome GRCh38-2020-A). One set of count matrices relates to the yolk sac data, and one set of count matrices relates to the yolk sac stalk data.