Mediators of Inflammation

2011

DOI: 10.1155/2011/941396

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Dendritic Cells in Human Atherosclerosis: From Circulation to Atherosclerotic Plaques

Emily A. Van Vré

¹

,

Ilse Van Brussel

²

,

³

et al.

Abstract: Background. Atherosclerosis is a chronic inflammatory disease with atherosclerotic plaques containing inflammatory infiltrates predominantly consisting of monocytes/macrophages and activated T cells. More recent is the implication of dendritic cells (DCs) in the disease. Since DCs were demonstrated in human arteries in 1995, numerous studies in humans suggest a role for these professional antigen-presenting cells in atherosclerosis. Aim. This paper focuses on the observations made in blood and arteries of pati… Show more

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Circulating Dcs: Biomarkers Of Disease?1

Ifns In Atherosclerosis1

Tissue-resident Dendritic Cells (Dcs)1

Characterizing Vascular Dendritic Cell Subsets1

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Cited by 53 publications

(48 citation statements)

References 105 publications

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“…27 The mechanisms responsible for the decline in blood DCs in atherosclerosis may include an enhanced recruitment to lymphoid organs or sites of inflammation, as suggested by their accumulation in vulnerable lesions, 20 an increased DC turnover, or a decreased production or release from bone marrow. 37 Interestingly, decreased numbers of blood Lin −…”

Section: Circulating Dcs: Biomarkers Of Disease?mentioning

confidence: 99%

Dendritic Cells in Atherosclerosis

¹

2015

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Abstract-Atherosclerotic vascular disease is driven by chronic inflammation involving both innate and adaptive immune responses. Dendritic cells (DCs) are found in healthy arteries and accumulate in atherosclerotic lesions and engage in diverse pathogenic and protective mechanisms during atherogenesis. DCs contribute to early foam cell formation, regulate lipid metabolism, and control pro-and antiatherosclerotic T-cell responses by multifarious mechanisms. We, here, review the roles of DCs and plasmacytoid DCs in experimental models of atherosclerosis and the approaches to target DCs in therapeutic vaccination strategies. We, furthermore, discuss the evidence of the potential function of DCs in human atherosclerosis, and dissect the efforts to harness DC subsets as biomarkers of disease. Finally, we discuss necessary future steps that will help to understand the specific contribution of bona fide DCs in atherosclerosis to move toward novel therapeutic approaches. On the basis of distinct developmental pathways, cDCs are further segregated into cDCs type 1 (cDC1s), encompassing CD8α + DCs in lymphoid and CD103 + DCs in nonlymphoid tissue, and CD11b + cDC2s. Analyses of the entire transcriptome revealed a core cDC gene signature absent from monocytes/macrophages and pDCs that include the genes Zbtb46 and Ccr7.7 CD8α + /CD103 + cDCs were furthermore revealed to express toll like receptor (Tlr) 3 and Xcr1, and to require the transcription factors BATF3, IRF8, Id2 for their development, whereas the differentiation of CD11b + cDCs is controlled by RELB, RBPJ and IRF4. The transcription factor E2-2/Tcf4 is an essential regulator of pDC development. [6][7][8][9][10][11][12] Both cDCs and pDCs depend on the growth factor fms-like tyrosine kinase 3 ligand (Flt3L), and Flt3L-dependence can serve as a surrogate marker for common DC precursor origin. 6,10 In contrast, macrophage colony-stimulating factor 1 receptor + monocytes that circulate in blood and enter tissues under inflammatory conditions, give rise to macrophages and monocyte-derived DCs. It is currently unclear if monocyte-derived DCs and macrophages constitute two distinct lineages, or if they are instead highly plastic cells that acquire different functional modules in response to microenvironmental cues 10 (Table 1). In humans, pDCs and 2 types of cDCs (previously referred to as myeloid DCs), namely CD1c + and CD141 + DCs are discriminated, which are considered homologs of CD11b + and CD8 + /CD103 + DCs in mice, respectively. 8,21 These DC subsets circulate as precursors or in an immature state in blood (Table 2) and originate from hematopoietic stem cells in the bone marrow via either granulocyte macrophage progenitors or multilymphoid progenitors. Human homologs of murine DC precursors remain unidentified. 14 Similar to mice, DCs can be detected in the arterial intima of healthy young individuals, 32 and increased numbers of DCs are found in atherosclerotic lesions 29 using unspecific markers, such as S100, CD1a, or fascin. However, a detailed analysis of the...

“…27 The mechanisms responsible for the decline in blood DCs in atherosclerosis may include an enhanced recruitment to lymphoid organs or sites of inflammation, as suggested by their accumulation in vulnerable lesions, 20 an increased DC turnover, or a decreased production or release from bone marrow. 37 Interestingly, decreased numbers of blood Lin −…”

Section: Circulating Dcs: Biomarkers Of Disease?mentioning

confidence: 99%

Dendritic Cells in Atherosclerosis

¹

2015

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Abstract-Atherosclerotic vascular disease is driven by chronic inflammation involving both innate and adaptive immune responses. Dendritic cells (DCs) are found in healthy arteries and accumulate in atherosclerotic lesions and engage in diverse pathogenic and protective mechanisms during atherogenesis. DCs contribute to early foam cell formation, regulate lipid metabolism, and control pro-and antiatherosclerotic T-cell responses by multifarious mechanisms. We, here, review the roles of DCs and plasmacytoid DCs in experimental models of atherosclerosis and the approaches to target DCs in therapeutic vaccination strategies. We, furthermore, discuss the evidence of the potential function of DCs in human atherosclerosis, and dissect the efforts to harness DC subsets as biomarkers of disease. Finally, we discuss necessary future steps that will help to understand the specific contribution of bona fide DCs in atherosclerosis to move toward novel therapeutic approaches. On the basis of distinct developmental pathways, cDCs are further segregated into cDCs type 1 (cDC1s), encompassing CD8α + DCs in lymphoid and CD103 + DCs in nonlymphoid tissue, and CD11b + cDC2s. Analyses of the entire transcriptome revealed a core cDC gene signature absent from monocytes/macrophages and pDCs that include the genes Zbtb46 and Ccr7.7 CD8α + /CD103 + cDCs were furthermore revealed to express toll like receptor (Tlr) 3 and Xcr1, and to require the transcription factors BATF3, IRF8, Id2 for their development, whereas the differentiation of CD11b + cDCs is controlled by RELB, RBPJ and IRF4. The transcription factor E2-2/Tcf4 is an essential regulator of pDC development. [6][7][8][9][10][11][12] Both cDCs and pDCs depend on the growth factor fms-like tyrosine kinase 3 ligand (Flt3L), and Flt3L-dependence can serve as a surrogate marker for common DC precursor origin. 6,10 In contrast, macrophage colony-stimulating factor 1 receptor + monocytes that circulate in blood and enter tissues under inflammatory conditions, give rise to macrophages and monocyte-derived DCs. It is currently unclear if monocyte-derived DCs and macrophages constitute two distinct lineages, or if they are instead highly plastic cells that acquire different functional modules in response to microenvironmental cues 10 (Table 1). In humans, pDCs and 2 types of cDCs (previously referred to as myeloid DCs), namely CD1c + and CD141 + DCs are discriminated, which are considered homologs of CD11b + and CD8 + /CD103 + DCs in mice, respectively. 8,21 These DC subsets circulate as precursors or in an immature state in blood (Table 2) and originate from hematopoietic stem cells in the bone marrow via either granulocyte macrophage progenitors or multilymphoid progenitors. Human homologs of murine DC precursors remain unidentified. 14 Similar to mice, DCs can be detected in the arterial intima of healthy young individuals, 32 and increased numbers of DCs are found in atherosclerotic lesions 29 using unspecific markers, such as S100, CD1a, or fascin. However, a detailed analysis of the...

“…The T1 IFN-producing pDCs have also been found in plaques, with a specific localization in its rupture-prone areas. [45][46][47][48] Overall, the role of IFN-γ in atherosclerosis has been investigated thoroughly, 27,28,32,[49][50][51] whereas research on the role of T1 IFNs in atherosclerosis development has only recently started. 26,52,53 Table 2 summarizes important murine atherosclerotic studies on the T1 and T2 IFNs.…”

Section: Ifns In Atherosclerosismentioning

confidence: 99%

Interferons as Essential Modulators of Atherosclerosis

¹

,

²

2015

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Abstract-Interferons (IFNs) are key regulators of both innate and adaptive immune responses. The family of IFN cytokines can be divided into 3 main subtypes of which type I and type II IFNs are most well-defined. IFNs are known to be important mediators in atherosclerosis. Evidence from both in vitro and in vivo studies shows that the IFNs are generally proatherosclerotic. However, their role in atherosclerosis is complex, with distinct roles for these cytokines throughout different stages of the disease. In this review, we will discuss the current knowledge on the role of type I and type II IFNs in atherosclerosis development, specifically focusing on their role in endothelial activation, cell recruitment, foam cell formation, and regulation of apoptosis. Furthermore, we will discuss whether IFNs could be considered as new molecular targets for therapeutic intervention in atherosclerosis. (Arterioscler Thromb Vasc Biol. 2015;35:1579-1588.

“…pDCs (0.2% in leukocytes) express BDCA-2 (or CD303) and CD123, and are specialized in antiviral innate immune responses by producing copious amounts of type I interferons (IFN-γ) upon exposure of intracellular TLR9 and TLR7 to DNA and RNA viruses. In addition, a small third population (0.02% of leukocytes) of blood DCs are distinguishable based on the expression of CD11c and BDCA-3 (or CD141), but not BDCA-1, CD123 and BDCA-2 [ 14 ]. Mouse blood DCs are less well characterized with a majority of circulating MHC class II + CD11c + as pDCs and low numbers of MHC class II + CD11c + and MHC class II – CD11c + DC progenitors that give rise to CD8α + and CD8α – DCs in lymphoid organs.…”

Section: Tissue-resident Dendritic Cells (Dcs)mentioning

confidence: 99%

Tissue-resident dendritic cells and diseases involving dendritic cell malfunction

¹

,

²

,

³

et al. 2016

International Immunopharmacology

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Dendritic cells (DCs) control immune responses and are central to the development of immune memory and tolerance. DCs initiate and orchestrate immune responses in a manner that depends on signals they receive from microbes and cellular environment. Although DCs consist mainly of bone marrow-derived and resident populations, a third tissue-derived population resides the spleen and lymph nodes (LNs), different subsets of tissue-derived DCs have been identified in the blood, spleen, lymph nodes, skin, lung, liver, gut and kidney to maintain the tolerance and control immune responses. Tissue-resident DCs express different receptors for microbe-associated molecular patterns (MAMPs) and damage-associated molecular patterns (DAMPs), which were activated to promote the production of pro- or anti-inflammatory cytokines. Malfunction of DCs contributes to diseases such as autoimmunity, allergy, and cancer. It is therefore important to update the knowledge about resident DC subsets and diseases associated with DC malfunction.

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