Project description:This project presents a spatial proteomic investigation of vascular smooth muscle cells (VSMCs) and atherosclerotic plaque regions in a diabetic mouse model of atherosclerosis (DMAS). Using ApoE-/- mice fed with a high-fat diet and treated with low-dose streptozotocin (STZ) to induce a diabetic phenotype, we performed laser capture microdissection (LCM) to separately isolate plaque regions and adjacent VSMC-rich areas of the aortic arch. Subsequently, spatially resolved proteomic profiling was carried out using LC-MS/MS, followed by quantitative analysis based on iBAQ values. Differentially expressed proteins between plaque and VSMC regions were identified and enriched pathway analysis revealed significant alterations in oxidative stress response, insulin signaling, mitochondrial function, RNA transport, and extracellular matrix remodeling under diabetic conditions. Of particular interest, the spatial proteomics data highlighted a marked downregulation of the nuclear pore complex protein Nup93 in VSMCs from diabetic mice, implicating impaired nuclear transport and dysregulation of RNA alternative splicing. This finding was supported by transcriptomic integration and functional analyses that revealed aberrant splicing of SerpinE2, a gene associated with cell proliferation and ECM accumulation. This dataset provides region-specific, high-resolution proteomic profiles of vascular tissues in a diabetic atherosclerosis model. It serves as a valuable resource for investigating the spatial heterogeneity of vascular pathology and the molecular mechanisms underlying diabetes-accelerated atherosclerosis. The raw and processed data can be used to explore protein expression dynamics, identify spatiotemporal biomarkers, and validate candidate targets such as Nup93 and SerpinE2 involved in VSMC phenotypic switching.

Project description:The aim of this study was to understand if gene expression in atherosclerotic plaque macrophages is altered by diabetes. Laser capture microdissection (LCM) was used to specifically isolate macrophage enriched regions from human carotid atherosclerotic plaque samples. RNA isolated was then sent for sequencing using the Illumina bead array system. Gene expression data revealed that 106 genes from diabetic macrophages are differentially expressed (FDR<0.2) and provide mechanistic evidence for the involvement of Runt-related transcription factor 1 (RUNX1) in the development of diabetic atherosclerosis.

Project description:The multi-ligand Receptor for AGE (RAGE) contributes to atherosclerosis in apolipoprotein (ApoE) null mice in both the non-diabetic and diabetic states. Previous studies using soluble RAGE, the extracellular ligand-binding domain of RAGE, or homozygous RAGE null mice showed that blockade or deletion of RAGE resulted in marked reduction in atherosclerotic lesion area and complexity compared to control animals. In parallel, significant down-regulation of inflammatory mediators and matrix metalloproteinases was evident in ApoE null mice aortas devoid of RAGE compared to those of ApoE null RAGE-expressing mice. Although these findings suggested that RAGE triggered pro-atherogenic mechanisms via regulation of inflammatory gene expression, these studies did not reveal the broader pathways by which RAGE contributed to atherosclerosis in ApoE null mice. Therefore, we performed Affymetrix gene expression arrays on aortas of non-diabetic and diabetic ApoE null mice expressing RAGE or devoid of RAGE at nine weeks of age, as this reflected a time point at which frank atherosclerotic lesions were not yet present, but, that we would be able to identify the genes likely involved in diabetes- and RAGE-dependent atherogenesis. The comparisons were as follows: 1. diabetic ApoE null relative to non-diabetic ApoE null; 2. non-diabetic ApoE null / RAGE null relative to non-diabetic ApoE null; 3. diabetic ApoE null / RAGE null relative to non-diabetic ApoE null / RAGE null; and 4. diabetic ApoE null / RAGE null relative to diabetic ApoE null aorta. Our data reveal that there is very little overlap of the genes which are differentially expressed both in the onset of diabetes in ApoE null mice, and in the effect of RAGE deletion in diabetic ApoE null mice. We next performed a Pathway-Express analysis to determine the pathways that were most associated with the onset of diabetes in ApoE null mice and the effect of RAGE gene deletion in diabetic ApoE null mice. Rigorous statistical analysis was undertaken and revealed that the transforming growth factor-beta pathway (tgf-beta) and focal adhesion pathways might be expected to play a significant role in both the mechanism by which diabetes facilitates the formation of atherosclerotic plaques in ApoE null mice, and the mechanism by which deletion of RAGE ameliorates this effect. We focused on three genes of the tgf-betafamily which were found to be up-regulated in diabetic vs. non-diabetic ApoE null aorta, and which were reduced by deletion of RAGE. These included: thrombospondin1 (Thbs1), transforming growth factor-beta (tgf-beta) and rho-associated kinase (ROCK1). Real-time quantitative polymerase chain reaction and Western blotting experiments were performed, as well as ROCK1 activity assays in mouse aorta, and validated the findings of the Affymetrix gene array. Further, confocal microscopy revealed that a principal cell type in the ApoE null aorta expressing these factors was the vascular smooth muscle cell. Our data suggest the novel finding that the observed reduction of accelerated atherosclerosis in diabetic ApoE null / RAGE null vs. diabetic ApoE null mice occurs, all or in part, through the ROCK1 branch of the TGF-betapathway. We have inferred a detailed mechanism for this process. Taken together, these data suggest that suppression of ROCK1 activity in the atherosclerosis-vulnerable vessel wall, especially in diabetes, but in non-diabetes as well, may underlie the beneficial effects of RAGE antagonism and genetic deletion in murine models. These findings highlight logical and novel targets for therapeutic intervention in cardiovascular disease and diabetes. 1. diabetic ApoE null relative to non-diabetic ApoE null; 2. non-diabetic ApoE null / RAGE null relative to non-diabetic ApoE null; 3. diabetic ApoE null / RAGE null relative to non-diabetic ApoE null / RAGE null; and 4. diabetic ApoE null / RAGE null relative to diabetic ApoE null aorta. There were 4 mice in each group initially. However there are only 3 non-diabetic ApoE null / RAGE null mice in the final experimental sample in group 3 due to a failure to generate cRNA from that sample. All samples were normalized to remove chip-dependent regularities using the RMA method. Chips and controls at each combination of genotype and disease sate were normalized together. The statistical significance of differential expression was calculated using the empirical Bayesian LIMMA (LInear Model for MicroArrays) method A cut-off B>0 was used for the statistical significance of gene expression.

Project description:Despite unprecedented advances in the treatment of atherosclerotic cardiovascular diseases (CVD), it remains the leading cause of death in patients with diabetes worldwide. Lipid-laden atherosclerotic plaque development within the arterial vessel wall is initiated with endothelial cell activation, monocyte adhesion and foam cell formation. Although the current focus has been on mitigation of risk factors, the disease continues to progress, and thus newer approaches and druggable targets need to be identified that can directly inhibit the underlying pathobiology of atherosclerosis. We utilised a single cell RNA sequencing (scRNA-seq) approach to distinguish the proatherogenic transcriptional profile of aortic ce­lls in diabetes.

Project description:Pathological vascular remodeling is the underlying cause of main cardiovascular diseases (CVD) including atherosclerosis and abdominal aortic aneurysm (AAA). We analyzed the potential role of galectin-1 (Gal-1) in atherosclerosis and AAA. Atherosclerosis was induced in mice lacking Gal-1 (Lgals1-/-) and wild-type (WT) by pAAV/D377Y-mPCSK9 adenovirus injection (1011 vector genome copies) followed by western diet during 16 weeks. In a second model, atherosclerostic WT mice were treated with recombinant Gal-1 protein (rGal-1, 100 µg 3 days/week) or vehicle during 16 weeks. Moreover, the same therapeutic approach was performed in elastase-induced AAA in mice treated for 2 weeks. Finally, Gal-1 expression was assessed in human atherosclerotic plaques and AAA lesions. Gal-1 deletion led to higher atherosclerotic burden along the aorta and larger atherosclerotic plaques in the aortic root. This deleterious effect was associated to higher circulating and lesional lipid levels and lower alpha- smooth muscle actin (α-SMA) staining in the plaques. Proteomic analysis of aorta homogenates showed an upregulation of Fibronectin and VCAM-1 in Lgals1-/- mice as compared to WT aortic tissues. In vitro experiments in VSMCs from Lgals1-/- mice or transfected with Gal-1 siRNA showed increased Fibronectin, VCAM-1 and KLF4 mRNA expression along with a decrease in α-SMA mRNA expression. Treatment with rGal-1 decreased atherosclerotic plaques (size and burden) and elastase-induced aortic dilatation, associated to higher content of α-SMA staining, in both experimental models. Gal-1 protein and mRNA tissue levels were decreased in human atherosclerotic plaques and AAA as compared to control aortic tissues.

Project description:The multi-ligand Receptor for AGE (RAGE) contributes to atherosclerosis in apolipoprotein (ApoE) null mice in both the non-diabetic and diabetic states. Previous studies using soluble RAGE, the extracellular ligand-binding domain of RAGE, or homozygous RAGE null mice showed that blockade or deletion of RAGE resulted in marked reduction in atherosclerotic lesion area and complexity compared to control animals. In parallel, significant down-regulation of inflammatory mediators and matrix metalloproteinases was evident in ApoE null mice aortas devoid of RAGE compared to those of ApoE null RAGE-expressing mice. Although these findings suggested that RAGE triggered pro-atherogenic mechanisms via regulation of inflammatory gene expression, these studies did not reveal the broader pathways by which RAGE contributed to atherosclerosis in ApoE null mice. Therefore, we performed Affymetrix gene expression arrays on aortas of non-diabetic and diabetic ApoE null mice expressing RAGE or devoid of RAGE at nine weeks of age, as this reflected a time point at which frank atherosclerotic lesions were not yet present, but, that we would be able to identify the genes likely involved in diabetes- and RAGE-dependent atherogenesis. The comparisons were as follows: 1. diabetic ApoE null relative to non-diabetic ApoE null; 2. non-diabetic ApoE null / RAGE null relative to non-diabetic ApoE null; 3. diabetic ApoE null / RAGE null relative to non-diabetic ApoE null / RAGE null; and 4. diabetic ApoE null / RAGE null relative to diabetic ApoE null aorta. Our data reveal that there is very little overlap of the genes which are differentially expressed both in the onset of diabetes in ApoE null mice, and in the effect of RAGE deletion in diabetic ApoE null mice. We next performed a Pathway-Express analysis to determine the pathways that were most associated with the onset of diabetes in ApoE null mice and the effect of RAGE gene deletion in diabetic ApoE null mice. Rigorous statistical analysis was undertaken and revealed that the transforming growth factor-β pathway (tgf-β) and focal adhesion pathways might be expected to play a significant role in both the mechanism by which diabetes facilitates the formation of atherosclerotic plaques in ApoE null mice, and the mechanism by which deletion of RAGE ameliorates this effect. We focused on three genes of the tgf-β family which were found to be up-regulated in diabetic vs. non-diabetic ApoE null aorta, and which were reduced by deletion of RAGE. These included: thrombospondin1 (Thbs1), transforming growth factor-β2 (tgf-β2) and rho-associated kinase (ROCK1). Real-time quantitative polymerase chain reaction and Western blotting experiments were performed, as well as ROCK1 activity assays in mouse aorta, and validated the findings of the Affymetrix gene array. Further, confocal microscopy revealed that a principal cell type in the ApoE null aorta expressing these factors was the vascular smooth muscle cell. Our data suggest the novel finding that the observed reduction of accelerated atherosclerosis in diabetic ApoE null / RAGE null vs. diabetic ApoE null mice occurs, all or in part, through the ROCK1 branch of the TGF-β pathway. We have inferred a detailed mechanism for this process. Taken together, these data suggest that suppression of ROCK1 activity in the atherosclerosis-vulnerable vessel wall, especially in diabetes, but in non-diabetes as well, may underlie the beneficial effects of RAGE antagonism and genetic deletion in murine models. These findings highlight logical and novel targets for therapeutic intervention in cardiovascular disease and diabetes.

Project description:Neutrophil extracellular traps (NETs) promote inflammation and atherosclerosis progression. In diabetes they are increased and impair wound healing, during which inflammation normally resolves. Atherosclerosis regression, a process resembling wound healing, is also impaired in diabetes. Thus, we hypothesized that NETs impede atherosclerosis regression in diabetes through unresolved inflammation. Objective: To investigate in diabetes the effect of NETs on plaque macrophage inflammation and whether NETs reduction improves atherosclerosis regression. Findings: Transcriptomic profiling of plaque macrophages from NET positive and negative areas in Ldlr-/- mice revealed inflammasome and glycolysis pathway upregulation, indicating a pro-inflammatory phenotype. During atherosclerosis regression in non-diabetic mice, plaque NET content decreased. In contrast, in diabetic mouse plaques NETs were enriched and persisted after lipid-lowering. DNase1 treatment (to degrade NETs) of diabetic mice reduced plaque NETs and macrophage inflammation and improved atherosclerosis regression after lipid-lowering. Conclusions: NETs decline during atherosclerosis regression in non-diabetic mice, but persist in diabetes and impair regression by exacerbating macrophage inflammation. DNase1 reduced diabetic plaque NETs and macrophage inflammation, and restored atherosclerosis resolution after lipid-lowering, despite ongoing hyperglycemia. Given that humans with diabetes also exhibit impaired atherosclerosis resolution with lipid-lowering, these data suggest that NETs contribute to the increased CVD risk in this population.

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

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