Macrophage Diversity and Polarization in Atherosclerosis (original) (raw)
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Vessel Plus, 2021
Atherosclerosis is the main pathological basis of most cardiovascular diseases and the leading health threat in the world. Of note, lipid-lowering therapy could not completely retard atherosclerosis progression, even in patients that treated with combined statins and PCSK9 inhibitors. This failure further impels researchers to explore other underlying therapeutic strategies except for lipid-lowering. Monocytes and macrophages are the major immune cell groups in atherosclerotic plaques. They play important roles in all stages of atherosclerosis, including the occurrence, advance and regression. It is interesting that macrophages are demonstrated to have plastic and heterogenous characteristics within the dynamic atherosclerotic plaque microenvironment. Furthermore, the phenotype of macrophages can switch upon different microenvironmental stimulus. Therefore, macrophages have become a potential therapeutic target for anti-atherosclerosis treatment. This article reviews the phenotypic diversity of macrophages and their roles in dynamic atherosclerotic plaque microenvironment, especially the related signaling pathways involved in macrophage polarization and compounds exhibited therapeutic effects.
Macrophage heterogeneity in atherosclerotic plaques
Current opinion in lipidology, 2009
The varied behaviour of macrophages and foam cells during atherosclerosis and its clinical sequelae prompt the question whether all these activities can be the property of a single cell population. Subsets of monocytes with distinct patterns of surface markers and behaviours during inflammation have recently been characterized and shown to have complementary roles during progression of atherosclerosis. A variety of macrophage phenotypes derived from these monocyte subsets in response to mediators of innate and acquired immunity have also been found in plaques. Based on functional properties and genomic signatures, they may have different impacts on facets of plaque development, including fibrous cap and lipid core formation. Monocyte and macrophage phenotypic diversity is important in atherogenesis. More work is needed to define consistent marker sets for the different foam cell phenotypes in experimental animals and humans. Cell tracking studies are needed to establish their relati...
Macrophages are key players in atherosclerotic lesions, regulating the local inflammatory milieu and plaque stability by the secretion of many inflammatory molecules, growth factors and cytokines. Monocytes have long been considered to be the main source of plaque macrophages. However, recent findings provide evidence for proliferation of local macrophages or transdifferentiation from other vascular cells as alternative sources. Recent years of research focused on the further identification and characterisation of macrophage phenotypes and functions. In this review we describe the advances in our understanding of monocyte and macrophage heterogeneity and its implications for specific therapeutic interventions, aiming to reduce the ever growing significant risk of cardiovascular events without any detrimental side effects on the patient's immune response.
Dynamic aspects of macrophage polarization during atherosclerosis progression and regression
It is well recognized that macrophages in many contexts in vitro and in vivo display a spectrum of inflammatory features and functional properties. A convenient system to group together different subsets of macrophages has been the M1 (inflammatory)/M2 (antiinflammatory) classification. In addition to other sites of inflammation, it is now established that atherosclerotic plaques contain both M1 and M2 macrophages. We review results made possible by a number of recent mouse models of atherosclerotic regression that, taken with other literature, have shown the M1/M2 balance in plaques to be dynamic, with M1 predominating in disease progression and M2 in regression. The regulation of the macrophage phenotype in plaques and the functional consequences of the M1 and M2 states in atherosclerosis will also be discussed.
Macrophage Heterogeneity: Relevance and Functional Implications in Atherosclerosis
Current Vascular Pharmacology, 2010
Atherosclerosis is a chronic inflammatory disease involving many cell types with a well-accepted key role for macrophages. A wide array of different properties and functional characteristics are attributed to macrophages present in the atherosclerotic plaque. As an increasing body of evidence strengthens the consensus that macrophages comprise a heterogeneous population, several co-existing subtypes with diverse, even opposing specialties have already been described in fields like parasitology, tumour biology and metabolic disorders. However, macrophage heterogeneity within atherosclerotic lesions has not been studied in detail yet. In this review we will introduce the characteristics of macrophage subsets in other pathologies and address the presence and possible roles of distinct macrophage subtypes in the rapidly evolving field of atherosclerosis. Finally, we make an effort to relate these subtypes to disease progression and explore a number of opportunities for novel diagnostic and therapeutic approaches.
Journal of Innate Immunity, 2012
The macrophage is exquisitely sensitive to its microenvironment, as demonstrated primarily through in vitro study. Changes in macrophage phenotype and function within the atherosclerotic plaque have profound consequences for plaque biology, including rupture and arterial thrombosis leading to clinical events such as myocardial infarction. We review the evidence for dynamic changes in macrophage numbers and macrophage differentiation within the atherosclerotic plaque microenvironment and discuss potential approaches to target macrophage differentiation for therapeutic benefit in cardiovascular disease.
Distribution of macrophage polarization markers in human atherosclerosis
Atherosclerosis, 2012
Objective: Macrophages are decisive in the chronic inflammatory processes that drive atherogenesis. The purpose of this study was to explore the presence and spatial distribution of polarized macrophage populations in human atherosclerosis. Methods & results: We used transcriptomics and immunohistochemistry to analyze macrophage subset dynamics in successive stages of atherogenesis. Developing lesions progressively accumulated both M1 and M2 cells, as was signified by the enhanced expression of associated markers at the transcriptional and protein level. Histologically, these markers were confined to overlapping, but spatially distinct CD68 รพ areas of the intima. We subsequently quantified the presence of these markers in relation to morphological determinants of plaque stability. In line with their pro-inflammatory characteristics, M1 macrophages dominated the rupture-prone shoulder regions of the plaque over M2 polarized cells, while the fibrous caps of lesions showed no significant differences between subsets. In contrast, vascular adventitial tissue displayed a pronounced M2 activation profile. As expected, areas of intraplaque hemorrhage clearly associated with CD163 staining. Rather than being limited to complicated lesions, this M2 marker was also readily detectable in stable plaques. Finally, foamy macrophages displayed an ambiguous repertoire that incorporates individual M1 and M2 markers. Conclusion: M1 and M2 macrophage populations are present throughout atherogenesis. These subsets display disparity when it comes to their prevalence in morphological compartments of the vessel wall. Our current findings warrant continued investigation into the functional implications of polarized macrophage populations in human atherosclerosis.
Role of macrophages in atherosclerosis
2020
Atherosclerosis is a chronic inflammatory state, which arise from the imbalance in lipid metabolism. Over the last decade, studies have showing the association of macrophages with this maladaptive immune response. Macrophages differentiated from monocytes and populate at the growing atherosclerotic lesions. At the lesion site by accumulating lipid they actively participate in the formation of atherosclerotic plaque. These plaques are very susceptible to rupture which can lead to myocardial infarction or stroke. In future more studies are needed to classify different macrophage populations according to their phenotypic and functional characteristics to identify their roles in the pathogenesis of atherosclerosis. This review highlights several aspects of macrophages activation, diversity, recruitment, and foam cell formation in atherosclerosis.
Molecular Pathways Regulating Macrophage Polarization: Implications for Atherosclerosis
Current Atherosclerosis Reports, 2012
Recent years have seen a tremendous development of our insight into the biology of atherosclerosis and its acute thrombotic manifestations. Inflammation now takes center stage among traditional risk factors as a decisive factor in cardiovascular risk. Consequently, its assessment and modulation have become key to clinical care and fundamental research alike. Plaque macrophages orchestrate many of the inflammatory processes that occur throughout atherogenesis. These cells are characteristically heterogeneous and adopt diverse activation states in response to micro-environmental triggers. In this review, macrophagemediated inflammation in atherosclerosis sets the scene for a discussion of the gene regulatory mechanisms that facilitate and shape polarized macrophage phenotypes. When applicable, we consider these factors within the context of atherosclerosis and reflect on opportunities for future application.
International journal of cardiology, 2015
Macrophages are essential players in induction and progression of atherosclerotic inflammation. The complexity of macrophage phenotypes was observed in human plaques and atherosclerotic lesions in mouse models of atherosclerosis. Plaque macrophages were shown to exhibit a phenotypic range that is intermediate between two extremes, M1 (pro-inflammatory) and M2 (anti-inflammatory). Indeed, in atherosclerosis, macrophages demonstrate phenotypic plasticity to rapidly adjust to changing microenvironmental conditions. In the plaque, serum lipids, serum lipoproteins and various pro- or anti-inflammatory stimuli such as cytokines, chemokines and small bioactive molecules could greatly influence the macrophage phenotype inducing switch towards more proinflammatory or anti-inflammatory properties. Dynamic plasticity of macrophages is achieved by up-regulation and down-regulation of an overlapping set of transcription factors that drive macrophage polarization. Understanding of mechanisms of m...