Project description:Atherosclerotic plaque rupture with subsequent embolic events is a major cause of sudden death from myocardial infarction or stroke. Although smooth muscle cells (SMC) produce and respond to collagens in vitro, there is no direct evidence in vivo that SMC are a critical source of collagens impacting lesion development or fibrous cap formation. We sought to determine how conditional SMC specific knockout of collagen type XV (COL15A1) in SMC lineage tracing mice effects advanced lesion formation. COL15A1 was chosen because: 1) we previously identified a Col15a1 sequence variant associated with age related atherosclerosis; 2) COL15A1 is a matrix organizer that enhances tissue structural integrity; and 3) siRNA mediated Col15a1 knockdown increased migration and decreased proliferation of SMC in vitro. We hypothesized that SMC derived COL15A1 is critical in advanced lesion pathogenesis and fibrous cap formation. Surprisingly, we demonstrate that SMC specific Col15a1 knockout mice fed a Western diet for 18 weeks failed to form advanced lesions. SMC Col15a1 knockout lesions have a drastic reduction in overall lesion size, cell accumulation, and the absence of a SMC and ECM- rich lesion or fibrous cap. In vivo RNA-seq analysis on lesions +/- SMC Col15a1 knockout suggests the mechanism for these effects is complex and associated with reductions in multiple pro-atherogenic inflammatory pathways in multiple cell types involved in lesion development. These results thus provide the first direct evidence that a SMC derived collagen is critical during lesion pathogenesis. Additionally, we conclude that SMC Col15a1 knockout unexpectedly inhibited rather than exacerbated lesion pathogenesis.

Project description:Recent genome wide association studies have identified a number of genes that contribute to the risk for coronary heart disease. One such gene, TCF21, encodes a basic-helix-loop-helix transcription factor believed to serve a critical role in the development of epicardial progenitor cells that give rise to coronary artery smooth muscle cells (SMC) and cardiac fibroblasts. Using reporter gene and immunolocalization studies with mouse and human tissues we have found that vascular TCF21 expression in the adult is restricted primarily to adventitial cells associated with coronary arteries and also medial SMC in the proximal aorta of mouse. Genome wide RNA-Seq studies in human coronary artery SMC (HCASMC) with siRNA knockdown found a number of putative TCF21 downstream pathways identified by enrichment of terms related to CAD, including “vascular disease,” “disorder of artery,” and “occlusion of artery” as well as disease-related cellular functions including “cellular movement,” and “cellular growth and proliferation.” In vitro studies in HCASMC demonstrated that TCF21 expression promotes proliferation and migration and inhibits SMC lineage marker expression. Detailed in situ expression studies with reporter gene and lineage tracing revealed that vascular wall cells expressing Tcf21 before disease initiation migrate into vascular lesions of ApoE-/- and Ldlr-/- mice. While Tcf21 lineage traced cells are distributed throughout the early lesions, in mature lesions they contribute to the formation of a subcapsular layer of cells, and others become associated with the fibrous cap. The lineage traced fibrous cap cells activate expression of SMC markers and growth factor receptor genes. Taken together, these data suggest that TCF21 may have a role regulating the differentiation state of SMC precursor cells that migrate into vascular lesions and contribute to the fibrous cap and more broadly, in view of the association of this gene with human CAD, provide evidence that these processes may be a mechanism for CAD risk attributable to the vascular wall.

Project description:Despite decades of research, our understanding of processes controlling the stability of late-stage atherosclerotic plaques remains poor. However, a prevailing hypothesis is that reducing inflammation may improve plaque stability. Indeed, the potent inflammatory cytokine, interleukin-1β (IL-1β), has been shown to be a key driver of atherosclerosis development. Importantly, the CANTOS Trial recently demonstrated that administration of an anti-IL-1β antibody to high-risk post-myocardial infarction (MI) patients reduced the incidence of recurrent nonfatal MI, but did not reduce the incidence of cardiovascular death or stroke. As such, although the CANTOS trial results providing exciting evidence that targeting inflammation can have clinical benefit for treating advanced atherosclerosis, extensive further investigation is needed to better understand the mechanisms by which IL-1β inhibition impacts established lesions. Therefore, we performed intervention studies on smooth muscle cell (SMC) lineage tracing mice with advanced atherosclerosis using anti-IL- 1 or IgG control antibodies. Surprisingly, we found no effect on lesion size but a profound shift in the composition of the fibrous cap characterized by reduced collagen and SMC content but an increase in macrophage number, which was primarily driven by opposite effects on the proliferation of these respective cell types. By generating SMC-specific and macrophage-selective Il1r1 KO Apoe -/- mice, we found that SMC-specific Il1r1 KO resulted in a ~60% reduction in lesion size and lesions that were nearly devoid of YFP + SMC whereas, myeloid-selective loss of IL1R1 had no effect on lesion size, or cell composition. This suggests that SMC are a primary cell type responding to IL-1β in atherosclerosis and that IL1 signaling in SMC is critical for their investment and retention within the fibrous cap. In addition, we found that inhibition of IL-1β promoted an expansion of the M2 macrophage population within the fibrous cap, and that these effects may be due in part to elevated levels of IL4. Taken together, results show that IL-1β can promote beneficial changes in late-stage murine atherosclerosis by promoting maintenance of a SMC/collagen-rich fibrous cap. Moreover, studies identify critical cell types and pathways that need to be considered when attempting to develop safer and more effective anti-inflammatory therapies for widespread treatment of atherosclerotic disease, including in moderate or low risk patients.

Project description:Genome-wide association studies (GWAS) for coronary artery disease (CAD, also termed coronary heart disease, CHD) have discovered and validated 48 loci genome-wide and recent 1000-Genomes based meta-analyses have discovered additional 8 loci with significant association, however, true follow-up studies on the mechanisms of association are still scarce. Here we analyze the relationship of two transcription factors, TCF21, one of the lead GWAS candidate genes for coronary artery disease and AHR, aryl hydrocarbon receptor, which previously was not implicated as fundamental for the atherosclerotic process. We show that both the predicted and in-vivo ChIP-Seq binding sites for TCF and AHR colocalize in the human genome with over 400 predicted sites and 119 ChIP-Seq sites directly overlapping. TCF and AHR-ARNT predicted binding sites longitudinal phasing was observed near the transcription start sites, outlining the position of +1 nucleosome. AHR-ARNT matrix was highly enriched in both TCF21 ChIP-Seq peaks and ATAC-Seq open chromatin regions in human coronary artery smooth muscle cells (HCASMC), implicating the role of AHR in this important cell type for vascular biology. Co-expression modules of TCF21 and AHR showed high degree of connectivity. Separation of rotationally phased and unphased predicted binding sites for TCF and AHR resolved the roles of direct and indirect TCF-AHR interactions, and implicated as highly-modulated various inflammatory, interleukin and cytokine related processes, while ChIP-Seq co-localization of TCF21 and AHR/ARNT emphasized the role of calcium related processes. We performed TCF21 overexpression analysis in human coronary artery smooth muscle cells (HCASMC) and obtained GO ontologies that recapitulate in vivo pathophysiology of the atherosclerotic vessel wall, and a set of chronic inflammatory ontologies was established with the colocalization of TCF21 and AHR ChIP-Seq sites as well as with the binomial testing of GWAS SNP overrepresentation. We experimentally confirmed that TCF21 binds to and regulates AHR gene expression in HCASMC, as well as to elements near AHR downstream genes, such as CYP1A1, using reporter assays. The functional relevance of AHR pathway in HCASMC is confirmed using AHR ligands TCDD and oxidized LDL. Finally, we show that AHR is elevated in atherosclerotic arteries using laser capture microdissection in mice in vivo and in human ex vivo. In conclusion, we extend GWAS results to functional assays and show that TCF21 and AHR functional connectivity provides a novel mechanism for diseased coronary vessel wall biology.

Project description:In response to various stimuli, vascular smooth muscle cells (SMCs) can de-differentiate, proliferate and migrate in a process known as phenotypic modulation. However, the phenotype of modulated SMCs in vivo during atherosclerosis and the influence of this process on coronary artery disease (CAD) risk have not been clearly established. Using single cell RNA sequencing, we comprehensively characterized the transcriptomic phenotype of modulated SMCs in vivo in atherosclerotic lesions of both mouse and human. We performed CITE-seq in mouse atherosclerotic lesions using antibodies directed against several macrophage surface markers. In the mice, we also performed SMC-specific knockout of TCF21, a causal CAD gene, to determine the effect of this gene on SMC phenotypic modulation. Finally, we performed ChIP-seq for the transcription factor TCF21 in a pooled DNA sample comprised of 52 different human coronary artery smooth muscle cell (HCASMC) lines to determine TCF21 target genes.

Project description:In response to various stimuli, vascular smooth muscle cells (SMCs) can de-differentiate, proliferate and migrate in a process known as phenotypic modulation. However, the phenotype of modulated SMCs in vivo during atherosclerosis and the influence of this process on coronary artery disease (CAD) risk have not been clearly established. Using single cell RNA sequencing, we comprehensively characterized the transcriptomic phenotype of modulated SMCs in vivo in atherosclerotic lesions of both mouse and human. We performed CITE-seq in mouse atherosclerotic lesions using antibodies directed against several macrophage surface markers. In the mice, we also performed SMC-specific knockout of TCF21, a causal CAD gene, to determine the effect of this gene on SMC phenotypic modulation. Finally, we performed ChIP-seq for the transcription factor TCF21 in a pooled DNA sample comprised of 52 different human coronary artery smooth muscle cell (HCASMC) lines to determine TCF21 target genes.

Project description:In response to various stimuli, vascular smooth muscle cells (SMCs) can de-differentiate, proliferate and migrate in a process known as phenotypic modulation. However, the phenotype of modulated SMCs in vivo during atherosclerosis and the influence of this process on coronary artery disease (CAD) risk have not been clearly established. Using single cell RNA sequencing, we comprehensively characterized the transcriptomic phenotype of modulated SMCs in vivo in atherosclerotic lesions of both mouse and human. We performed CITE-seq in mouse atherosclerotic lesions using antibodies directed against several macrophage surface markers. In the mice, we also performed SMC-specific knockout of TCF21, a causal CAD gene, to determine the effect of this gene on SMC phenotypic modulation. Finally, we performed ChIP-seq for the transcription factor TCF21 in a pooled DNA sample comprised of 52 different human coronary artery smooth muscle cell (HCASMC) lines to determine TCF21 target genes.

Project description:In response to various stimuli, vascular smooth muscle cells (SMCs) can de-differentiate, proliferate and migrate in a process known as phenotypic modulation. However, the phenotype of modulated SMCs in vivo during atherosclerosis and the influence of this process on coronary artery disease (CAD) risk have not been clearly established. Using single cell RNA sequencing, we comprehensively characterized the transcriptomic phenotype of modulated SMCs in vivo in atherosclerotic lesions of both mouse and human. We performed CITE-seq in mouse atherosclerotic lesions using antibodies directed against several macrophage surface markers. In the mice, we also performed SMC-specific knockout of TCF21, a causal CAD gene, to determine the effect of this gene on SMC phenotypic modulation. Finally, we performed ChIP-seq for the transcription factor TCF21 in a pooled DNA sample comprised of 52 different human coronary artery smooth muscle cell (HCASMC) lines to determine TCF21 target genes.

Project description:To investigate effects of IGF-1 on human-like coronary atherosclerosis we used high fat diet-fed Rapacz pigs with familial hypercholesterolemia (FH pigs). We used spatial transcriptomics (ST) analysis to identify global transcriptome changes in advanced plaque compartments and to obtain mechanistic insights into IGF-1 effects. IGF-1-injected FH pigs had 1.8-fold increase in total circulating IGF-1 levels compared to control. IGF-1 decreased relative coronary atheroma (data obtained by serial intravascular ultrasound) and lesion cross-sectional area (post-mortem histology). IGF-1 increased fibrous cap thickness, and reduced necrotic core size, macrophage content, and cell apoptosis, changes consistent with promotion of a stable plaque phenotype. ST analysis revealed that IGF-1 suppressed FOS/FOSB factors and gene expression of MMP9 and CXCL14 suggesting possible involvement of these molecules in IGF-1’s effect on atherosclerosis.

Project description:Growing evidence correlated changes in bioactive sphingolipids, particularly sphingosine-1-phosphate (S1P) and ceramides, with coronary artery diseases. Furthermore, specific plasma ceramide species can predict major cardiovascular events. Dysfunction of the endothelium lining lesion-prone areas plays a pivotal role in the initiation and progression of atherosclerosis. Yet, how sphingolipid metabolism and signaling change and contribute to endothelial dysfunction and atherosclerosis remain poorly understood. By using a mouse model of coronary atherosclerosis, we demonstrated that hemodynamic stress induces an early metabolic rewiring of endothelial sphingolipid de novo biosynthesis favoring S1P signaling over ceramide as protective response. Furthermore, our data are paradigm shift from the current believe that ceramide accrual contributes to endothelial dysfunction. The de novo biosynthesis of sphingolipids is commenced by serine palmitoyltransferase (SPT), and is downregulated by NOGO-B, an ER membrane protein. We showed that Nogo-B is upregulated by hemodynamic stress in myocardial endothelial cells (EC) of ApoE-/- mice and is expressed in the endothelium lining coronary lesions in mice and human. We demonstrated that mice lacking Nogo-B specifically in EC (Nogo-A/BECKOApoE-/-) were resistant to coronary atherosclerosis development and progression, and mortality. Fibrous cap thickness was significantly increased in Nogo-A/BECKOApoE-/- mice and correlated with reduced necrotic core and macrophage infiltration. Mechanistically, the deletion of Nogo-B in EC sustained the rewiring of sphingolipid metabolism towards S1P, imparting an atheroprotective transcriptional signature that refrain coronary atherogenesis and its progression. These findings also set forth the foundation for sphingolipid-based therapeutics to reduce the treat this condition.