Project description:The extravillous trophoblast (EVT) cell lineage is a key feature of placentation and critical for spiral artery remodeling and successful pregnancy. Our knowledge of transcriptional regulation driving EVT cell development is limited. Here, we mapped the transcriptome and epigenome landscape as well as chromatin interactions of human trophoblast stem (TS) cells and their transition into the differentiated EVT cell lineage. We identified that chromatin accessibility in intergenic regions was more extensive in EVT cells than in TS cells in the stem state, which is indicative of increased enhancer-driven gene regulation. Using reference epigenome annotation, we noted that 18% of the chromatin landscape in EVT cells was uncharted.  We linked regulatory regions to their cognate target genes and characterized the three-dimensional organization of the TS cell functional genome by Hi-C. Integrational analysis of chromatin accessibility, long-range chromatin interactions, transcriptomic, and transcription factor binding motif enrichment enabled identification of transcription factors and regulatory mechanisms associated with EVT cell lineage development. Subsequent analyses elucidated functional roles for TFAP2C, EPAS1, SNAI1, and DLX6 in the regulation of EVT cell lineage development. EPAS1 was identified as an upstream regulator of EVT cell transcription factors, including SNAI1 and DLX6, and was found to be upregulated in idiopathic recurrent pregnancy loss. Collectively, we have revealed activation of a dynamic regulatory network that provides a framework for understanding EVT cell specification in trophoblast cell lineage development and human placentation.

Project description:The extravillous trophoblast (EVT) cell lineage is a key feature of placentation and critical for spiral artery remodeling and successful pregnancy. Our knowledge of transcriptional regulation driving EVT cell development is limited. Here, we mapped the transcriptome and epigenome landscape as well as chromatin interactions of human trophoblast stem (TS) cells and their transition into the differentiated EVT cell lineage. We identified that chromatin accessibility in intergenic regions was more extensive in EVT cells than in TS cells in the stem state, which is indicative of increased enhancer-driven gene regulation. Using reference epigenome annotation, we noted that 18% of the chromatin landscape in EVT cells was uncharted.  We linked regulatory regions to their cognate target genes and characterized the three-dimensional organization of the TS cell functional genome by Hi-C. Integrational analysis of chromatin accessibility, long-range chromatin interactions, transcriptomic, and transcription factor binding motif enrichment enabled identification of transcription factors and regulatory mechanisms associated with EVT cell lineage development. Subsequent analyses elucidated functional roles for TFAP2C, EPAS1, SNAI1, and DLX6 in the regulation of EVT cell lineage development. EPAS1 was identified as an upstream regulator of EVT cell transcription factors, including SNAI1 and DLX6, and was found to be upregulated in idiopathic recurrent pregnancy loss. Collectively, we have revealed activation of a dynamic regulatory network that provides a framework for understanding EVT cell specification in trophoblast cell lineage development and human placentation.

Project description:The extravillous trophoblast (EVT) cell lineage is a key feature of placentation and critical for spiralartery remodeling and successful pregnancy. Our knowledge of transcriptional regulation driving EVT cell development is limited. Here, we mapped the transcriptome and epigenome landscape as well as chromatin interactions of human trophoblast stem (TS) cells and their transition into the differentiated EVT cell lineage. We identified that chromatin accessibility in intergenic regions was more extensive in EVT cells than in TS cells in the stem state, which is indicative of increased enhancer-driven gene regulation. Using reference epigenome annotation, we noted that 18% of the chromatin landscape in EVT cells was uncharted. We linked regulatory regions to their cognate target genes and characterized the three-dimensional organization of the TS cell functional genome by Hi-C. Integrational analysis of chromatin accessibility, long-range chromatin interactions, transcriptomic, and transcription factor binding motif enrichment enabled identification of transcription factors and regulatory mechanisms associated with EVT cell lineage development. Subsequent analyses elucidated functional roles forTFAP2C,EPAS1,SNAI1, andDLX6in the regulation of EVT cell lineage development.EPAS1was identified as an upstream regulator of EVT cell transcription factors, includingSNAI1andDLX6, and was found to be upregulated in idiopathic recurrent pregnancy loss. Collectively, we have revealed activation of a dynamic regulatory network that provides a framework for understanding EVT cell specification in trophoblast cell lineage development and human placentation.

Project description:The extravillous trophoblast (EVT) cell lineage is a key feature of placentation and critical for spiralartery remodeling and successful pregnancy. Our knowledge of transcriptional regulation driving EVT cell development is limited. Here, we mapped the transcriptome and epigenome landscape as well as chromatin interactions of human trophoblast stem (TS) cells and their transition into the differentiated EVT cell lineage. We identified that chromatin accessibility in intergenic regions was more extensive in EVT cells than in TS cells in the stem state, which is indicative of increased enhancer-driven gene regulation. Using reference epigenome annotation, we noted that 18% of the chromatin landscape in EVT cells was uncharted. We linked regulatory regions to their cognate target genes and characterized the three-dimensional organization of the TS cell functional genome by Hi-C. Integrational analysis of chromatin accessibility, long-range chromatin interactions, transcriptomic, and transcription factor binding motif enrichment enabled identification of transcription factors and regulatory mechanisms associated with EVT cell lineage development. Subsequent analyses elucidated functional roles forTFAP2C,EPAS1,SNAI1, andDLX6in the regulation of EVT cell lineage development.EPAS1was identified as an upstream regulator of EVT cell transcription factors, includingSNAI1andDLX6, and was found to be upregulated in idiopathic recurrent pregnancy loss. Collectively, we have revealed activation of a dynamic regulatory network that provides a framework for understanding EVT cell specification in trophoblast cell lineage development and human placentation.

Project description:The extravillous trophoblast (EVT) cell lineage is a key feature of placentation and critical for spiralartery remodeling and successful pregnancy. Our knowledge of transcriptional regulation driving EVT cell development is limited. Here, we mapped the transcriptome and epigenome landscape as well as chromatin interactions of human trophoblast stem (TS) cells and their transition into the differentiated EVT cell lineage. We identified that chromatin accessibility in intergenic regions was more extensive in EVT cells than in TS cells in the stem state, which is indicative of increased enhancer-driven gene regulation. Using reference epigenome annotation, we noted that 18% of the chromatin landscape in EVT cells was uncharted. We linked regulatory regions to their cognate target genes and characterized the three-dimensional organization of the TS cell functional genome by Hi-C. Integrational analysis of chromatin accessibility, long-range chromatin interactions, transcriptomic, and transcription factor binding motif enrichment enabled identification of transcription factors and regulatory mechanisms associated with EVT cell lineage development. Subsequent analyses elucidated functional roles forTFAP2C,EPAS1,SNAI1, andDLX6in the regulation of EVT cell lineage development.EPAS1was identified as an upstream regulator of EVT cell transcription factors, includingSNAI1andDLX6, and was found to be upregulated in idiopathic recurrent pregnancy loss. Collectively, we have revealed activation of a dynamic regulatory network that provides a framework for understanding EVT cell specification in trophoblast cell lineage development and human placentation.

Project description:The extravillous trophoblast (EVT) cell lineage is a key feature of placentation and critical for spiralartery remodeling and successful pregnancy. Our knowledge of transcriptional regulation driving EVT cell development is limited. Here, we mapped the transcriptome and epigenome landscape as well as chromatin interactions of human trophoblast stem (TS) cells and their transition into the differentiated EVT cell lineage. We identified that chromatin accessibility in intergenic regions was more extensive in EVT cells than in TS cells in the stem state, which is indicative of increased enhancer-driven gene regulation. Using reference epigenome annotation, we noted that 18% of the chromatin landscape in EVT cells was uncharted. We linked regulatory regions to their cognate target genes and characterized the three-dimensional organization of the TS cell functional genome by Hi-C. Integrational analysis of chromatin accessibility, long-range chromatin interactions, transcriptomic, and transcription factor binding motif enrichment enabled identification of transcription factors and regulatory mechanisms associated with EVT cell lineage development. Subsequent analyses elucidated functional roles forTFAP2C,EPAS1,SNAI1, andDLX6in the regulation of EVT cell lineage development.EPAS1was identified as an upstream regulator of EVT cell transcription factors, includingSNAI1andDLX6, and was found to be upregulated in idiopathic recurrent pregnancy loss. Collectively, we have revealed activation of a dynamic regulatory network that provides a framework for understanding EVT cell specification in trophoblast cell lineage development and human placentation.

Project description:Invasive trophoblast cells are critical to spiral artery remodeling in hemochorial placentation. Insufficient trophoblast invasion and vascular remodeling can lead to pregnancy disorders including preeclampsia, preterm birth, and intrauterine growth restriction. Previous studies in the mouse identified achaete-scute homolog 2 (ASCL2) as essential to extraembryonic development. We hypothesized that ASCL2 is a critical and conserved regulator of invasive trophoblast lineage development. In contrast to the mouse, the rat possesses deep intrauterine trophoblast cell invasion and spiral artery remodeling similar to human placentation. In this report, we investigated invasive/extravillous trophoblast (EVT) cell differentiation using human trophoblast stem (TS) cells and a loss-of-function mutant Ascl2 rat model. ASCL2 transcripts are expressed in the EVT column and junctional zone, which represent tissue sources of invasive trophoblast progenitor cells within human and rat placentation sites, respectively. Differentiation of human TS cells into EVT cells resulted in significant upregulation of ASCL2 and several other transcripts indicative of EVT cell differentiation. Disruption of ASCL2 impaired EVT cell differentiation as indicated by cell morphology and transcript profiles. RNA sequencing analysis of ASCL2-deficient trophoblast cells identified both downregulation of EVT cell-associated transcripts and upregulation of syncytiotrophoblast-associated transcripts, indicative of dual activating and repressing functions. ASCL2 deficiency in the rat impacted placental morphogenesis resulting in junctional zone dysgenesis and failed intrauterine trophoblast cell invasion. ASCL2 acts as a critical and conserved regulator of invasive trophoblast cell lineage development and a species-specific modulator of the syncytiotrophoblast lineage.

Project description:WNT activated signal transduction is a conserved regulator of morphogenesis of many organ systems, including the placenta. In human trophoblast stem (TS) cells, activation of canonical WNT signaling is a key to maintenance of the TS cell stem state. NOTUM, a negative regulator of canonical WNT signaling, was prominently expressed in first trimester EVT cells developing in situ and upregulated in EVT cells derived from human TS cells. Furthermore, NOTUM was required for human TS cell differentiation to EVT cells. Canonical WNT signaling is essential for maintaining human trophoblast cell stemness and prevention of human TS cell differentiation. Downregulation of canonical WNT signaling via the actions of NOTUM is required for EVT cell differentiation.

Project description:WNT activated signal transduction is a conserved regulator of morphogenesis of many organ systems, including the placenta. In human trophoblast stem (TS) cells, activation of canonical WNT signaling is a key to maintenance of the TS cell stem state. NOTUM, a negative regulator of canonical WNT signaling, was prominently expressed in first trimester EVT cells developing in situ and upregulated in EVT cells derived from human TS cells. Furthermore, NOTUM was required for human TS cell differentiation to EVT cells. Canonical WNT signaling is essential for maintaining human trophoblast cell stemness and prevention of human TS cell differentiation. Downregulation of canonical WNT signaling via the actions of NOTUM is required for EVT cell differentiation.

Project description:Trophoblast stem (TS) cell renewal and differentiation are essential processes in placentation. Here, we have identified the mechanism/targets of chromatin organizer/transcription factor called special AT-rich binding protein 1 (SATB1) action on TS cell renewal by RNA-seq analysis in Rcho-1 TS cells expressing Satb1 shRNAs.