Project description:The ETS transcription factor ERG is a critical transcription factor that establishes and maintains an EC identity program. ERG is downregulated in several chronic vascular diseases, including atherosclerosis, and has been implicated in suppressing endothelial-to-mesenchymal transition (EndMT). However, the dynamic phenotypic and transcriptional consequences of ERG loss in the endothelium is poorly understood. We knocked down ERG using siRNA and compared this transient ERG loss over time to chronic deletion of ERG in a CRISPR/Cas9 deletion line in aortic ECs. RNA-sequencing and ATAC-sequencing revealed profound and dynamic rewiring of endothelial and mesenchymal transcriptional programs. While EC identity was rapidly lost (24 hours knock-down) at the transcriptional level, barrier dysfunction required longer-term knock- down (72 hours). A mesenchymal gene network and enhanced cell migration also required 72 hours to manifest. Loss of ERG was accompanied by a rapid loss of occupancy of ETS motifs and a gain in open chromatin containing AP1 motifs. Inhibition of AP1, washout of ERG siRNA or expression of ERG protein in ERG knock-out cells, demonstrated that EndMT was reversible. Finally, ERG-regulated genes and regulatory elements were associated with human disease, demonstrating that this transcription factor may be a valuable target of future therapies for vascular diseases.

Project description:The ETS transcription factor ERG is a critical transcription factor that establishes and maintains an EC identity program. ERG is downregulated in several chronic vascular diseases, including atherosclerosis, and has been implicated in suppressing endothelial-to-mesenchymal transition (EndMT). However, the dynamic phenotypic and transcriptional consequences of ERG loss in the endothelium is poorly understood. We knocked down ERG using siRNA and compared this transient ERG loss over time to chronic deletion of ERG in a CRISPR/Cas9 deletion line in aortic ECs. RNA-sequencing and ATAC-sequencing revealed profound and dynamic rewiring of endothelial and mesenchymal transcriptional programs. While EC identity was rapidly lost (24 hours knock-down) at the transcriptional level, barrier dysfunction required longer-term knock- down (72 hours). A mesenchymal gene network and enhanced cell migration also required 72 hours to manifest. Loss of ERG was accompanied by a rapid loss of occupancy of ETS motifs and a gain in open chromatin containing AP1 motifs. Inhibition of AP1, washout of ERG siRNA or expression of ERG protein in ERG knock-out cells, demonstrated that EndMT was reversible. Finally, ERG-regulated genes and regulatory elements were associated with human disease, demonstrating that this transcription factor may be a valuable target of future therapies for vascular diseases.

Project description:The ETS transcription factor ERG is a critical transcription factor that establishes and maintains an EC identity program. ERG is downregulated in several chronic vascular diseases, including atherosclerosis, and has been implicated in suppressing endothelial-to-mesenchymal transition (EndMT). However, the dynamic phenotypic and transcriptional consequences of ERG loss in the endothelium is poorly understood. We knocked down ERG using siRNA and compared this transient ERG loss over time to chronic deletion of ERG in a CRISPR/Cas9 deletion line in aortic ECs. RNA-sequencing and ATAC-sequencing revealed profound and dynamic rewiring of endothelial and mesenchymal transcriptional programs. While EC identity was rapidly lost (24 hours knock-down) at the transcriptional level, barrier dysfunction required longer-term knock- down (72 hours). A mesenchymal gene network and enhanced cell migration also required 72 hours to manifest. Loss of ERG was accompanied by a rapid loss of occupancy of ETS motifs and a gain in open chromatin containing AP1 motifs. Inhibition of AP1, washout of ERG siRNA or expression of ERG protein in ERG knock-out cells, demonstrated that EndMT was reversible. Finally, ERG-regulated genes and regulatory elements were associated with human disease, demonstrating that this transcription factor may be a valuable target of future therapies for vascular diseases.

Project description:Lipodystrophy syndromes (LD) are characterized by loss of adipose tissue, metabolic complications such as dyslipidemia, insulin resistance and fatty liver disease, as well as accelerated atherosclerosis. As a result of adipose tissue deficiency, the systemic concentration of the adipokine leptin is reduced. A current promising therapeutic option for patients with LD is treatment with recombinant leptin (metreleptin) resulting in reduced risk of mortality. Here, we investigate the effects of leptin on endothelial-to-mesenchymal transition (EndMT), which impairs the functional properties of endothelial cells and promotes atherogenesis in LD. Leptin treatment reduced inflammation, TGF-β2-induced expression of mesenchymal genes and prevented impairment of endothelial barrier function. Treatment of lipodystrophic and atherosclerosis prone animals (Ldlr-/-; aP2-nSrebp1c-Tg) with leptin reduced macrophage accumulation in atherosclerotic lesions, vascular plaque protrusion and the number of endothelial cells with mesenchymal gene expression, confirming a reduction in EndMT in LD after leptin treatment. Treatment with leptin inhibited LD-mediated induction of the pro-atherosclerotic cytokine growth/differentiation factor 15 (GDF15). Inhibition of GDF15 reduced EndMT induction triggered by plasma from LD patients. Our study reveals that in addition to the effects on adipose tissue function, leptin treatment exerts beneficial effects protecting endothelial function and identity in LD by reducing GDF15.

Project description:Cell phenotype switching is increasingly being recognized in atherosclerosis. Intraplaque hemorrhage (IPH) is thought to be a major contributor to plaque progression in part by stimulating the influx of CD163+ macrophages. We explored the hypothesis that CD163 macrophages cause plaque progression through the induction of pro-apoptotic endothelial to mesenchymal transition (EndMT) within the fibrous cap.

Project description:Endothelial-to-mesenchymal transition (EndMT) in which endothelial cells lose their characteristics and acquire mesenchymal property has recently been recognized as a driver of disease progression in wide range of pathologies. However, the regulatory mechanism of EndMT has not been fully understood. Here, we found that combined knockdown of two ETS family transcription factors, ERG and FLI1, induced EndMT. Hence, we analyzed functions of ERG and FLI1 using gene expression microarray and ChIP-seq to elucidate the regulatory mechanism of EndMT.

Project description:Endothelial-to-mesenchymal transition (EndMT) in which endothelial cells lose their characteristics and acquire mesenchymal property has recently been recognized as a driver of disease progression in wide range of pathologies. However, the regulatory mechanism of EndMT has not been fully understood. Here, we found that combined knockdown of two ETS family transcription factors, ERG and FLI1, induced EndMT. Hence, we analyzed functions of ERG and FLI1 using gene expression microarray and ChIP-seq to elucidate the regulatory mechanism of EndMT.

Project description:Endothelial-to-mesenchymal transition (EndMT) is an example of endothelial cell (EC) heterogeneity which is commonly modeled in vitro to better understand driving mechanisms of disease proceses, including atherosclerosis. We used multi-modal single nucleus RNA sequencing (snRNA-seq) and ATAC sequencing (snATAC-seq) to analyze the diversity of ECs in vitro, divergent EC responses to known EndMT perturbations, and the ability of in vitro EC known EndMT models to recapitulate the in vivo 'omic profiles of cells observed in atherosclerosis.

Project description:Background: Genome-wide association studies (GWAS) have identified multiple novel loci that contribute to coronary artery disease (CAD) pathogenesis, but the mechanisms of these associations remain largely unknown. Methods: In this study we used a multi-trait colocalization approach to prioritize novel endothelial specific loci for atherosclerosis. We combined computational methods with in vitro assays and mouse models to study one of those new loci targeting gene REST. Results: A multi-trait colocalization approach across expression quantitative trait loci (eQTL) in atherosclerosis-relevant cell types followed by in vitro CRISPR interference revealed that a conserved regulatory element in a chromosome 4 genetic locus increases risk of CAD and decreases the expression of REST, a transcriptional repressor, in endothelial cells. Pcsk9-overexpressing mice with an endothelial-specific knockout of Rest exhibited increased atherosclerotic plaque formation in their aortas, with increased macrophage and lipid deposition within the plaque after 16 weeks of high-fat diet exposure compared to littermate controls. RNA-seq in human aortic endothelial cells (HAEC) after REST silencing followed by assessment of protein expression revealed that REST silencing triggers endothelial-to-mesenchymal transition (endMT). Consistently, REST silencing increased endothelial permeability and migration in vitro. Single nucleus RNA sequencing in endothelial lineage traced atherosclerotic mice with Rest knock-out revealed evidence of endothelial TGFb signalling activation and of transition smooth muscle-like cells in atherosclerotic aortas upon genetic knockout of Rest. CUT&Tag sequencing did not identify any known TGFb effector genes as direct REST transcriptional targets. Instead, joint analysis of CUT&Tag with RNA-seq, highlighted L1CAM, a known endMT activator, and its interactors as the most significant gene-set directly affected by REST in the endothelium. Simultaneous silencing of L1CAM and REST in HAEC inhibited the upregulation of mesenchymal genes and the enhanced migration induced by REST silencing and diminished the upregulation of several TGFb effectors overexpressed upon REST silencing. Conclusion: In summary, our data reveal the novel role of REST as a repressor in endothelial cells that functions to constitutively inhibit endMT and protect against atherosclerosis. Key words: GWAS, NRSF/REST, endothelial to mesenchymal transition, CRISPRi, CUT&TAG, endothelial cells, L1CAM, atherosclerosis

Project description:Background: Genome-wide association studies (GWAS) have identified multiple novel loci that contribute to coronary artery disease (CAD) pathogenesis, but the mechanisms of these associations remain largely unknown. Methods: In this study we used a multi-trait colocalization approach to prioritize novel endothelial specific loci for atherosclerosis. We combined computational methods with in vitro assays and mouse models to study one of those new loci targeting gene REST. Results: A multi-trait colocalization approach across expression quantitative trait loci (eQTL) in atherosclerosis-relevant cell types followed by in vitro CRISPR interference revealed that a conserved regulatory element in a chromosome 4 genetic locus increases risk of CAD and decreases the expression of REST, a transcriptional repressor, in endothelial cells. Pcsk9-overexpressing mice with an endothelial-specific knockout of Rest exhibited increased atherosclerotic plaque formation in their aortas, with increased macrophage and lipid deposition within the plaque after 16 weeks of high-fat diet exposure compared to littermate controls. RNA-seq in human aortic endothelial cells (HAEC) after REST silencing followed by assessment of protein expression revealed that REST silencing triggers endothelial-to-mesenchymal transition (endMT). Consistently, REST silencing increased endothelial permeability and migration in vitro. Single nucleus RNA sequencing in endothelial lineage traced atherosclerotic mice with Rest knock-out revealed evidence of endothelial TGFb signalling activation and of transition smooth muscle-like cells in atherosclerotic aortas upon genetic knockout of Rest. CUT&Tag sequencing did not identify any known TGFb effector genes as direct REST transcriptional targets. Instead, joint analysis of CUT&Tag with RNA-seq, highlighted L1CAM, a known endMT activator, and its interactors as the most significant gene-set directly affected by REST in the endothelium. Simultaneous silencing of L1CAM and REST in HAEC inhibited the upregulation of mesenchymal genes and the enhanced migration induced by REST silencing and diminished the upregulation of several TGFb effectors overexpressed upon REST silencing. Conclusion: In summary, our data reveal the novel role of REST as a repressor in endothelial cells that functions to constitutively inhibit endMT and protect against atherosclerosis. Key words: GWAS, NRSF/REST, endothelial to mesenchymal transition, CRISPRi, CUT&TAG, endothelial cells, L1CAM, atherosclerosis