Project description:VCAM-1 is known to be expressed by endothelial cells. We showed that this is also expressed by atherosclerotic plaque macrophages. However, the merit of this adhesion molecule is now known in atherosclerosis. In this RNA sequencing experiment, we analyzed VCAM-1+ vs. - atherosclerotic plaque macrophages. Additionally, we sorted macrophages from atherosclerotic plaques of mice after mitochondrial biogenesis gene Cmpk2 silencing in macrophages in vivo.

Project description:Atherosclerosis is a chronic inflammatory disease of the blood vessels, characterized by atherosclerotic lesions. Early vascular injury initiates excessive inflammatory and immune responses, communicated by blood leukocytes and cells from the vasculature. Key factors contributing to early stages of atherosclerosis and plaque development include the pro-inflammatory cytokine IFNγ, which is vital for both innate and adaptive immunity and is also expressed at high levels in atherosclerotic lesions. Recent discoveries provide novel evidence to suggest that IFNγ-activated STAT1 orchestrates a platform of cell-type common and specific inflammatory responses in Vascular Smooth Muscle Cells (VSMC) and macrophages (MΦ) that are instrumental in the onset and progression of atherosclerotic plaque formation. Therefore, we compared genome-wide transcriptional responses of mouse VSMCs and bone marrow-derived macrophages (BMDMs) in time-dependent IFNγ response using RNA-seq. We identified genes upregulated both in a common and cell-type-specific manner. Next, comparative analysis with RNAseq data from aortic plaques from HFD-treated ApoEKO mice identified 225 differentially expressed genes with a BMDM-specific character. These included many known IFNγ target genes containing putative GAS and ISRE sites in their promoters. Likewise, using a scRNAseq data set obtained from human coronary atherosclerotic plaques, identified 98 pro-inflammatory and pro-atherogenic genes that were characterized as BMDM-specific and exclusively expressed in foamy, inflammatory, monocytes and tissue-resident BMDM subtypes. Finally, we identified a 25 BMDM-specific gene subset commonly expressed in mouse and human plaques, over-representing STAT1-binding sites and predominantly associated with Leukocyte Chemotaxis and Migration. These results provide strong evidence for a BMDM-specific role of STAT1 in coronary artery plaque development and identify a BMDM-specific STAT1-dependent pro-inflammatory gene signature that could serve to monitor and diagnose plaque progression in human atherosclerosis.

Project description:Atherosclerosis is a chronic inflammatory disease of the blood vessels, characterized by atherosclerotic lesions. Early vascular injury initiates excessive inflammatory and immune responses, communicated by blood leukocytes and cells from the vasculature. Key factors contributing to early stages of atherosclerosis and plaque development include the pro-inflammatory cytokine IFNγ, which is vital for both innate and adaptive immunity and is also expressed at high levels in atherosclerotic lesions. Recent discoveries provide novel evidence to suggest that IFNγ-activated STAT1 orchestrates a platform of cell-type common and specific inflammatory responses in Vascular Smooth Muscle Cells (VSMC) and macrophages (MΦ) that are instrumental in the onset and progression of atherosclerotic plaque formation. Therefore, we compared genome-wide transcriptional responses of mouse VSMCs and bone marrow-derived macrophages (BMDMs) in time-dependent IFNγ response using RNA-seq. We identified genes upregulated both in a common and cell-type-specific manner. Next, comparative analysis with RNAseq data from aortic plaques from HFD-treated ApoEKO mice identified 225 differentially expressed genes with a BMDM-specific character. These included many known IFNγ target genes containing putative GAS and ISRE sites in their promoters. Likewise, using a scRNAseq data set obtained from human coronary atherosclerotic plaques, identified 98 pro-inflammatory and pro-atherogenic genes that were characterized as BMDM-specific and exclusively expressed in foamy, inflammatory, monocytes and tissue-resident BMDM subtypes. Finally, we identified a 25 BMDM-specific gene subset commonly expressed in mouse and human plaques, over-representing STAT1-binding sites and predominantly associated with Leukocyte Chemotaxis and Migration. These results provide strong evidence for a BMDM-specific role of STAT1 in coronary artery plaque development and identify a BMDM-specific STAT1-dependent pro-inflammatory gene signature that could serve to monitor and diagnose plaque progression in human atherosclerosis.

Project description:By modeling interaction of cigarette smoke and hypercholesterolemia, we provide experimental evidence that atherosclerotic disease directly contributes to AAA formation and rupture; AAA progression is mediated by inflammatory Mφ residing within associated atherosclerotic plaque.

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:Atherosclerosis represents an age-related disease, which remains one of the leading cause of deaths in developed countries. It begins with a local deposition of lipid in the innermost part of the artery – intima. Thereafter a number of immune cells are attracted and infiltrate into the artery wall, where, together with endothelia and smooth muscle cells, form an atherosclerotic plaque (Libby, 2008). Thus, atherosclerosis is considered as an inflammatory disease, characterized by intense immunological activity (Libby P, 2012). One of the main risk factor for atherosclerosis is aging. It was demonstrated that there is an accumulation of senescent cells within atherosclerotic plaque (..). Accordingly, vascular smooth muscle cells (VSMCs) derived from the lesion demonstrate a phenotype characteristic for senescent cells: diminished proliferative potential, shorter telomeres, increased number of DNA damage and upregulation of SA-β-gal activity (Gorenne, 2006; Matthes, 2006, Mahomoudi, 2008). Accumulation of senescent VSMCs within the area of plaque development promotes its instability due to lack of proliferation and impaired production of extracellular matrix, both leading to weakening of fibrous cap (Gorenne, 2006). This has been further confirmed by the observation, that elimination of senescent cells in the atherosclerosis-prone low-density lipoprotein receptor-deficient (Ldlr-/-) mice slowed down the disease progression (27789842). One of the most important feature of senescent cells, that has the biggest impact on tissue microenvironment, is their ability to secrete a number of cytokines, chemokines, matrix metalloproteinases and growth factors collectively known as the Senescence Associated Secretory Phenotype (SASP) (20078217, 28165648). Apart from soluble factors, senescent cells secret also an increased number of extracellular vesicles (EVs), research of which has only recently begun (32461143). EVs are small membranous vesicles that can be categorized based on their size and origin, into: exosomes, microvesicles and apoptotic bodies. EVs play crucial role as carriers of proteins, different types of RNA and DNA, lipids and metabolites that, take part in intercellular communication (23420871). They were shown to participate in many physiological but also pathological conditions. Studies performed over the last decade proved that EVs affect atherosclerosis progression at different stages by several distinct mechanisms (as reviewed by Knokhot, 2020, 33261815). The increased concentrations of EVs have been found in plasma of patients suffering from cardiovascular diseases as well as in atherosclerotic plaque itself (Yin, 2015, 26142082; Rautou, 2011, 21852557). However, the role of EVs derived from senescent cells in atherosclerosis, particularly in the context of the plaque development, remains unknown. The functioning of immune cells within atherosclerotic plaque is modulated by local milieu. Thus, senescent cells present in the lesion can influence plaque development by non-cell autonomous mechanism. Indeed, recently it was demonstrated that SASP factors secreted by senescent VSMCs promote recruitment of monocytes, induce expression of adhesion receptors on endothelial cells and activate adjacent normal VSMCs, promoting inflammation in the plaque (Gardner, 2015). However, the role of EVs in this context has not been studied. Thus, we have undertaken research aimed at investigating the role of senescent cell derived EVs on immune cells activity. To this end, we isolated and characterized the EVs secreted by human VSMCs undergoing senescence. We performed unbiased quantitative proteomic analysis of both soluble and insoluble SASP components. Moreover, we analyzed the influence of EVs derived from senescent and non-senescent cells on T lymphocytes and monocytes. Altogether our studies revealed that EVs produced by senescent VSMCs strengthen inflammatory response of the immune cells, what would have a tremendous significance in atherosclerotic plaque development.

Project description:Adipogenesis occurs through a specific gene program in undifferentiated fat progenitors. We hypothesized that the properties of the fat progenitors are regulated by hox genes, the developmental genes essential in different tissue stem cells. Their biased expression in white and brown fat implies roles in distinguishing the two fat types. Among 39 Hox genes, Hoxc8 is highly enriched in undifferentiated adipose tissue stem cells (ADSCs) and down-regulated in differentiated adipocytes. Forced expression of Hoxc8 suppressed adipocyte differentiation of ADSCs. Using microarrays, we investigated the effect of Hoxc8 overexpression on global transcripts in ADSCs. We compared among four groups: untreated ADSCs, adipogenic induction media (MDI)-treated ADSCs, MDI-treated ADSC-vector and MDI-treated ADSC-Hoxc8. A number of, but not all, adipogenesis-related genes are suppressed by Hoxc8. This dataset illustrates the global effect of Hoxc8, a developmental transcription factor, on the expression of adipogenesis-related genes. Gene expression was compared among untreated ADSCs (control), adipogenic induction media-treated ADSCs, adipogenic induction media-treated ADSC-vector (ADSCs transduced with control vector), and adipogenic induction media-treated ADSC-Hoxc8 (ADSCs transduced with human Hoxc8). Total RNA was isolated from ADSCs using the Qiagen RNeasy kit (Qiagen). At NimbleGen, quality and yield were verified before cDNA synthesis and Cy3-end labeling. The labeled cDNA samples were hybridized to Homo sapiens 4-Plex arrays (Roche NimbleGen, A4487001-00-01) that represent 24,000 human genes. Raw data files for each sample were normalized and background-corrected using a Robust Multi-Array Analysis as implemented by NimbleScan software. Students’ two-tail t-tests were conducted among the samples for each transcript and fold-change was determined. Transcripts whose abundance was significantly altered (P < 0.05) and an absolute fold change greater than 2 were defined as differentially regulated.

Project description:<div><b>OBJECTIVE:</b> Atherosclerotic plaque development is closely associated with the hemodynamic forces applied to endothelial cells (EC). Among these, shear stress (SS) plays a key role in disease development since changes in flow intensity and direction could stimulate an atheroprone or atheroprotective phenotype. EC under low or oscillatory SS (LSS) shows upregulation of inflammatory, adhesion and cellular permeability molecules. On the contrary, cells under high or laminar SS (HSS) increase their expression of protective and anti-inflammatory factors. The mechanism behind SS regulation of an atheroprotective phenotype is not completely elucidated.</div><div><b>APPROACH and RESULTS:</b> Here we used proteomics and metabolomics to better understand the changes in endothelial cells (HUVECs) under in vitro LSS and HSS that promote an atheroprone or atheroprotective profile and how these modifications can be connected to atherosclerosis development. Our data showed that lipid metabolism, in special cholesterol metabolism, was downregulated in cells under LSS. The LDLR showed significant alterations both at the quantitative expression level, as well as regarding post-translational modifications. Under LSS, LDLR was seen at lower concentrations and with a different glycosylation profile. Finally, modulating LDLR with atorvastatin led to the recapitulation of a HSS metabolic phenotype in EC under LSS.</div><div><b>CONCLUSIONS:</b> Altogether, our data suggest that there is significant modulation of lipid metabolism in endothelial cells under different SS intensities and that this could contribute to the atheroprone phenotype of LSS. Statin treatment was able to partially recover the protective profile of these cells.</div>

Project description:The rupture of atherosclerotic plaque contributes significantly to cardiovascular disease (CVD). Plasma concentrations of bilirubin, a by-product of heme catabolism, inversely associate with risk of CVD, although the link between bilirubin and atherosclerosis remains unclear.

Project description:IL-1 plays an important role in atherosclerosis, and alters expression of a number of genes involved in atherosclerotic plaque development and progression. Smooth muscle cells play important roles in atherosclerotic plaque formation and stability, so this study was undertaken to determine the global effects of IL-1b on gene expression in smooth muscle cells in vitro.