Identification of Specific Coronary Artery Disease Phenotypes Implicating Differential Pathophysiologies.

Background and Aims: The roles of multiple risk factors of coronary artery disease (CAD) are well established. Commonly, CAD is considered as a single disease entity. We wish to examine whether coronary angiography allows to identify distinct CAD phenotypes associated with major risk factors and differences in prognosis. Methods: In a cohort of 4,344 patients undergoing coronary angiography at Heidelberg University Hospital between 2014 and 2016, cluster analysis of angiographic reports identified subgroups with similar patterns of spatial distribution of high-grade stenoses. Clusters were independently confirmed in 3,129 patients from the LURIC study. Results: Four clusters were identified: cluster one lacking critical stenoses comprised the highest percentage of women with the lowest cardiovascular risk. Patients in cluster two exhibiting high-grade stenosis of the proximal RCA had a high prevalence of the metabolic syndrome, and showed the highest levels of inflammatory biomarkers. Cluster three with predominant proximal LAD stenosis frequently presented with acute coronary syndrome and elevated troponin levels. Cluster four with high-grade stenoses throughout had the oldest patients with the highest overall cardiovascular risk. All-cause and cardiovascular mortality differed significantly between the clusters. Conclusions: We identified four phenotypic subgroups of CAD bearing distinct demographic and biochemical characteristics with differences in prognosis, which may indicate multiple disease entities currently summarized as CAD.

CXCL4-induced macrophages in human atherosclerosis.

Atherosclerosis is considered an inflammatory disease of the arterial wall. Monocytes and monocyte-derived cells (most often termed macrophages) play an essential role in the formation of atherosclerotic lesions, as they take up lipids leading to subsequent foam cell formation accompanied by release of pro-inflammatory cytokines. Similarly, platelets have been discovered to represent an important cell type mediating inflammatory and immune processes in atherogenesis, mainly by secreting chemokines, which are stored in the platelets' alpha granules, upon platelet activation. Therefore, the interaction between monocyte-derived cells and platelets is of exceptional importance. In this review, we specifically focus on the chemokine (platelet factor-4, PF4) and its effects on monocytes and monocyte-derived cells. By formation of heterodimers dimers and -oligomers with CCL5, CXCL4 induces binding of monocytes cells to endothelial cell and thereby promotes diapedesis of monocytes into the subendothelial space. CXCL4 also affects the differentiation of monocytes as it induces a specific macrophage phenotype, which we suggested to term "M4". For example, CXCL4-induced macrophages irreversibly lose the hemoglobin-haptoglobin scavenger receptor CD163. The combination of CD68, S100A8, and MMP7 turned out to reliably identify M4 macrophages both in vitro and in vivo within atherosclerotic lesions. In human atherosclerotic plaques, M4 macrophages are predominantly present in the adventitia and the intima and their prevalence is associated with plaque instability suggesting that they are a marker of pro-inflammatory activity. Overall, CXCL4-induced M4 macrophages may represent a target for diagnostic and therapeutic interventions in human atherosclerotic disease.

Systematic RNA-interference in primary human monocyte-derived macrophages: A high-throughput platform to study foam cell formation.

Macrophage-derived foam cells are key regulators of atherogenesis. They accumulate in atherosclerotic plaques and support inflammatory processes by producing cytokines and chemokines. Identifying factors that regulate macrophage lipid uptake may reveal therapeutic targets for coronary artery disease (CAD). Here, we establish a high-throughput screening workflow to systematically identify genes that impact the uptake of DiI-labeled low-density lipoprotein (LDL) into monocyte-derived primary human macrophages. For this, monocytes isolated from peripheral blood were seeded onto 384-well plates, solid-phase transfected with siRNAs, differentiated in vitro into macrophages, and LDL-uptake per cell was measured by automated microscopy and quantitative image analysis. We applied this workflow to study how silencing of 89 genes impacts LDL-uptake into cells from 16 patients with CAD and 16 age-matched controls. Silencing of four novel genes (APOC1, CMTM6, FABP4, WBP5) reduced macrophage LDL-uptake. Additionally, knockdown of the chemokine receptor CXCR4 reduced LDL-uptake, most likely through a G-protein coupled mechanism that involves the CXCR4 ligand macrophage-induced factor (MIF), but is independent of CXCL12. We introduce a high-throughput strategy to systematically study gene function directly in primary CAD-patient cells. Our results propose a function for the MIF/CXCR4 signaling pathway, as well as several novel candidate genes impacting lipid uptake into human macrophages.

Galectin-3 binding protein, coronary artery disease and cardiovascular mortality: Insights from the LURIC study.

BACKGROUND AND AIMS: Galectin-3 binding protein (Gal-3BP) has been associated with inflammation and cancer, however, its role in coronary artery disease (CAD) and cardiovascular outcome remains unclear. METHODS: Gal-3BP plasma levels were measured by ELISA in 2922 individuals from the LURIC study (62.7 ± 10.6 years, 62.7% male). All-cause and cardiovascular mortality was assessed by Kaplan-Meier analysis and Cox proportional hazards regression. Causal involvement of Gal-3BP was tested for by Mendelian randomization. Gal-3BP effects on human monocyte-derived macrophages were assessed in vitro. RESULTS: During 8.8 ± 3.0 years, 866 individuals died, 654 of cardiovascular causes. There was a significant increase in all-cause and cardiovascular mortality with increasing Gal-3BP quintiles. After thorough adjustment, all-cause mortality remained significantly increased in the fifth Gal-3BP quintile (HRQ5 1.292 (1.030-1.620), p = 0.027); cardiovascular mortality remained increased in Gal-3BP quintiles two to five (HRQ51.433 (1.061-1.935, p = 0.019). Gal-3BP levels were not associated with diagnosis and extent of coronary artery disease. In addition, Mendelian randomization did not show a direct causal relationship between Gal-3BP levels and mortality. Gal-3BP levels were, however, independently associated with markers of metabolic and inflammatory distress. In vitro, Gal-3BP induced a pro-inflammatory response in human monocyte-derived macrophages. Adding Gal-3BP levels to the ESC score improved risk assessment in patients with ESC SCORE-based risk >5% (p = 0.010). CONCLUSIONS: In a large clinical cohort of CAD patients, Gal-3BP levels are independently associated with all-cause and cardiovascular mortality. The underlying mechanisms may likely involve metabolic and inflammatory distress. To further evaluate the potential clinical value of Gal-3BP, prospective studies are needed.

Galectin-3 binding protein plasma levels are associated with long-term mortality in coronary artery disease independent of plaque morphology.

BACKGROUND AND AIMS: Galectin-3 binding protein (Gal-3BP) is a secreted protein associated with inflammation and carotid atherosclerosis. We hypothesized that high Gal-3BP levels may indicate unfavorable plaque morphology and outcome in coronary artery disease (CAD). METHODS: Gal-3BP plasma levels were measured by ELISA in 233 patients (63 ± 10 years, 50.2% male) undergoing computed coronary angiography tomography (CCTA). RESULTS: In 149 patients, CCTA confirmed CAD (stenosis grade >20%). Mean Gal-3BP plasma levels were 5.9 ± 2.7 µg/mL and did not differ between patients with or without CAD. Over a follow-up time of up to 4.4 years (median 2.5 years), there were 17 cases of revascularization, five cases of myocardial infarction, and five deaths (four non-cardiac, one fatal myocardial infarction). Kaplan-Meier analysis revealed that high Gal-3BP levels were significantly associated with long-term mortality (p < 0.001). Cox proportional hazards regression analysis showed that this association was independent of cardiovascular risk factors (HR 1.238, 95%-CI 1.012-1.514, p = 0.038). After adjustment for troponin T and C-reactive protein (hs-CRP) levels, significance was lost (p = 0.123). Further analysis revealed that Gal-3BP levels were significantly related to body mass index and hs-CRP levels indicating an association with metabolic and inflammatory distress. There was no correlation between Gal-3BP and calcium score, plaque volume, or vascular remodeling. CONCLUSIONS: While high Gal-3BP plasma levels are associated with long-term mortality, we could not confirm it as a marker of cardiac mortality or unstable plaque morphology.

Differential regulation of aldose reductase expression during macrophage polarization depends on hyperglycemia.

Aldose reductase (AR; gene AKR1B1) is the rate-limiting enzyme of the polyol pathway and has been associated with diabetes and atherosclerosis. Here, we sought to identify the mechanisms underlying differential AR expression in human atherosclerotic plaque macrophages. In vitro, M1-polarized human monocyte-derived macrophages expressed significantly higher levels of AKR1B1 mRNA and AR protein compared with M2-polarized macrophages. AR activity was significantly higher in M1 macrophages. AKR1B1 mRNA expression correlated positively with the M1 marker TNF(r = 0.430,P = 0.006) and negatively with the M2 marker MRC1 (r = -0.443,P = 0.044). Increased AR expression in M1 macrophages depended on hyperglycemia. Concomitantly, expression of SLC2A1 (coding for the Glc transporter GLUT-1) was significantly higher in M1 than in M2 macrophages. Pharmacological inhibition of GLUT-1 using STF-32 completely abrogated Glc-induced AR up-regulation in M1 macrophages. When analyzing AR expression in post-mortem coronary artery plaque macrophages, a history of diabetes was associated with a significantly increased proportion of CD68(+)AR(++)macrophages, supporting the in vivo relevance of our in vitro findings. We demonstrate that the phenotype of atherosclerotic plaque macrophages may be affected by cardiovascular risk factors such as hyperglycemia. Our data illustrate the complex interplay between systemic and local factors in atherogenesis.

CXCL4 Plasma Levels Are Not Associated with the Extent of Coronary Artery Disease or with Coronary Plaque Morphology.

BACKGROUND: CXCL4 is a platelet chemokine released at micromolar concentrations upon platelet activation. CXCL4 has been shown to promote atherogenesis by various mechanisms. However, data on CXCL4 plasma levels in patients with coronary artery disease are largely inconclusive. Computed coronary artery angiography (CCTA) represents an excellent tool to quantify and characterize coronary atherosclerotic plaques. We hypothesized that increased CXCL4 plasma levels may be associated with features of plaque instability resulting in adverse cardiovascular events. Specifically, we sought to determine whether CXCL4 levels are correlated with specific features of coronary artery disease including (1) plaque volume, (2) calcium score, (3) degree of stenosis, or (4) vascular remodeling. METHODS AND RESULTS: CXCL4 plasma levels were measured by ELISA in 217 patients undergoing CCTA for suspected CAD (mean age 64.2 ± 9.4 years, 107 (49.3%) male). Mean CXCL4 plasma levels were 12.5 ± 4.6 ng/mL. There was no significant correlation between CXCL4 levels and any clinical or demographic parameters including cardiovascular risk factors. CXCL4 plasma levels did not differ between patient with or without coronary artery disease (CAD: 12.5 ± 4.5 ng/ml, no CAD: 12.5 ± 4.8 ng/ml). Neither univariate nor multivariate analysis showed an association between CXCL4 levels and plaque volume, total calcium score, degree of stenosis, or vascular remodeling. Subgroup analysis of patients with CAD as confirmed by CCTA did not show any association of CXCL4 levels with the extent of CAD. CONCLUSIONS: While CXCL4 may be present and active within the arterial wall, local increase of CXCL4 may not translate into systemically elevated CXCL4 levels. Further studies will have to test whether CXCL4 may still represent a suitable therapeutic target in human atherosclerosis.

Prevalence of M4 macrophages within human coronary atherosclerotic plaques is associated with features of plaque instability.

BACKGROUND: The platelet chemokine CXCL4 induces monocyte differentiation resulting in a macrophage phenotype called "M4", which co-expresses CD68, MMP7, and S100A8. We hypothesized that M4 macrophages are associated with plaque destabilization. METHODS: Atherosclerotic arteries were obtained from explanted hearts of patients with severe coronary artery disease (CAD, n = 32) and of patients with dilated cardiomyopathy and no or mild CAD (controls, n = 19). Coronary arteries were stained with H&E, and immuno-fluorescence was performed against CD68, MMP7, and S100A8. RESULTS: Both CD68(+) macrophages representing the entire macrophage population and MMP7(+)S100A8(+)CD68(+) M4 macrophages could be reproducibly identified within all arterial layers. The average proportion of the M4 macrophage phenotype amongst all CD68(+) macrophages was 31.7 ± 16.2%. The highest number of M4 macrophages was found in the adventitia, followed by the intima. CD68(+) and M4 macrophage numbers were significantly higher in patients with severe CAD. The presence of M4 macrophages within the intima and the media was significantly associated with plaque instability as determined by Stary class. Multivariate analysis showed a highly significant contribution of cardiovascular risk factors (P = 0.008) to plaque instability, while only trends were observed for age (P = 0.060) and intimal prevalence of M4 macrophages (P = 0.098). CONCLUSIONS: We demonstrate for the first time that M4 macrophages can be reproducibly found in coronary artery plaques. The prevalence of M4 macrophages is associated with indexes of plaque instability, most likely representing a surrogate marker of inflammatory activity. These findings suggest a pathogenetic role of M4 macrophages in vulnerable atherosclerotic plaques.

Low levels of natural IgM antibodies against phosphorylcholine are independently associated with vascular remodeling in patients with coronary artery disease.

Low anti-phosphorylcholine (PC) IgM plasma levels have been associated with increased incidence of adverse events in coronary artery disease (CAD). The underlying mechanisms are unclear. We hypothesized that atheroprotection mediated by anti-PC IgM antibodies is associated with reduced vascular remodeling and therefore tested whether anti-PC IgM plasma levels independently predict vascular remodeling. In a prospective cross-sectional study, anti-PC IgM plasma levels were measured in 175 consecutive patients with suspected CAD undergoing cardiac computed tomography angiography. Plaque morphology was thoroughly analyzed. Vascular remodeling was defined by a change in the vessel diameter at the plaque site in comparison to the reference segment proximal to the lesion (reference diameter) of ≥10%. Mean age of the patients was 64.8 ± 10.7 years, 48.6% were female. In 98 patients CAD was diagnosed, 57 (58.2%) of which displayed non-obstructive CAD (stenosis <50%), whereas 41 (41.8%) exhibited obstructive CAD (stenosis ≥50%). In 34 of 98 (34.7%) CAD patients vascular remodeling was present. Mean anti-PC IgM levels did not differ between patients with and without CAD (70.8 ± 52.7 vs. 69.1 ± 55.1 U/mL). However, anti-PC IgM levels were significantly lower in CAD patients compared to those without vascular remodeling (46.6 ± 31.6 vs. 73.3 ± 58.5 U/mL, P = 0.024). Using multivariate logistic regression, anti-PC IgM plasma levels independently predicted coronary vascular remodeling (HR 0.322, 95% confidence interval 0.121-0.856, P = 0.023). In conclusion, low anti-PC IgM levels are independently associated with coronary vascular remodeling. These findings may represent the link between in vitro studies demonstrating atheroprotective effects of anti-PC IgM and clinical data demonstrating that low anti-PC IgM levels are associated with adverse outcome in CAD patients.

CXCL4-induced plaque macrophages can be specifically identified by co-expression of MMP7+S100A8+ in vitro and in vivo.

Macrophage heterogeneity in human atherosclerotic plaques has been recognized; however, markers for unequivocal identification of some subtypes are lacking. We found that the platelet chemokine CXCL4 induces a unique macrophage phenotype, which we proposed to call 'M4'. Here, we sought to identify suitable markers that identify M4 macrophages in vitro and in vivo. Using a stringent algorithm, we identified a set of potential markers from transcriptomic data derived from polarized macrophages. We specifically focused on matrix metalloproteinase (MMP)7 and S100A8, the co-expression of which has not been described in any macrophage type thus far. We found dose- and time-dependent MMP7 and S100A8 expression in M4 macrophages at the gene and protein levels. CXCL4-induced up-regulation of both MMP7 and S100A8 was curbed in the presence of heparin, which binds to CXCL4 and glycosaminoglycans, most likely representing the macrophage receptor for CXCL4. Immunofluorescence of post-mortem atherosclerotic coronary arteries identified CD68(+)MMP7(+), CD68(+)MMP7(-), CD68(+)S100A8(+) and CD68(+)S100A8(-) macrophages. A small proportion of MMP7(+)S100A8(+) macrophages most likely represent M4 macrophages. In summary, we have identified co-expression of MMP7 and S100A8 to be a marker combination exclusively found in M4 macrophages. This finding may allow further dissection of the role of M4 macrophages in atherosclerosis and other pathologic conditions.

Inflammatory therapeutic targets in coronary atherosclerosis-from molecular biology to clinical application.

Atherosclerosis is the leading cause of death worldwide. Over the past two decades, it has been clearly recognized that atherosclerosis is an inflammatory disease of the arterial wall. Accumulating data from animal experiments have supported this hypothesis, however, clinical applications making use of this knowledge remain scarce. In spite of optimal interventional and medical therapy, the risk for recurrent myocardial infarction remains by about 20% over 3 years after acute coronary syndromes, novel therapies to prevent atherogenesis or treat atherosclerosis are urgently needed. This review summarizes selected potential molecular inflammatory targets that may be of clinical relevance. We also review recent and ongoing clinical trails that target inflammatory processes aiming at preventing adverse cardiovascular events. Overall, it seems surprising that translation of basic science into clinical practice has not been a great success. In conclusion, we propose to focus on specific efforts that promote translational science in order to improve outcome and prognosis of patients suffering from atherosclerosis.