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.

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.