Rationale: Regression of atherosclerosis is an important clinical goal, however the pathways that mediate the resolution of atherosclerotic inflammation and reversal of plaques are poorly understood. Regulatory T cells (Tregs) have been shown to be atheroprotective, yet the numbers of these immunosuppressive cells decrease with disease progression, and whether they contribute to atherosclerosis regression is not known. Objective: We investigated the roles of Tregs in the resolution of atherosclerotic inflammation, tissue remodeling and plaque contraction during atherosclerosis regression. Methods and Results: Using multiple independent mouse models of atherosclerosis regression, we demonstrate that an increase in plaque Tregs is a common signature of regressing plaques. Single cell RNA-sequencing of plaque immune cells from revealed that Tregs from regressing plaques shared some similarity with splenic Tregs, but were distinct from skin and colon Tregs supporting recent findings of tissue-dependent Treg heterogeneity. Unlike Tregs from progressing plaques that expressed markers of natural Tregs derived from the thymus, Tregs in regressing plaques lacked Nrp1 and Helios expression, suggesting that they are induced in the periphery during lipid lowering therapy. To test whether Tregs are required for resolution of atherosclerotic inflammation and plaque regression, Tregs were depleted using CD25 monoclonal antibody in atherosclerotic mice during apolipoprotein B anti-sense oligonucleotide-mediated lipid lowering. Morphometric analyses revealed that Treg depletion blocked plaque remodeling and contraction, and impaired hallmarks of inflammation resolution including dampening of the Th1 response, alternative activation of macrophages, efferocytosis, and upregulation of specialized pro-resolving lipid mediators. Conclusions: Our data establish essential roles for Tregs in resolving atherosclerotic cardiovascular disease and provide mechanistic insight into the pathways governing plaque remodeling and regression of disease
Rationale: Therapeutic efforts to decrease atherosclerotic cardiovascular disease risk have focused largely on reducing atherogenic lipoproteins, yet lipid lowering therapies alone are insufficient to fully regress plaque burden. We postulate that arterial repair requires resolution of a maladaptive immune response, and that targeting factors that hinder inflammation resolution will facilitate plaque regression. Objective: The guidance molecule netrin-1 is secreted by macrophages in atherosclerotic plaques, where it sustains inflammation by enhancing macrophage survival and blocking macrophage emigration. We tested whether silencing netrin-1 in advanced atherosclerosis could resolve arterial inflammation and regress plaques. Methods and Results: To temporally silence netrin-1 in myeloid cells, we generated genetically modified mice in which Ntn1 could be selectively deleted in monocytes and macrophages using a tamoxifen-induced CX3CR1-driven cre-recombinase ( Ntn1 fl/fl Cx3cr1 creERT2+ ) and littermate control mice ( Ntn1 fl/fl Cx3cr1 WT ). Mice were fed western diet in the setting of hepatic PCSK9 overexpression to render them atherosclerotic, and then treated with tamoxifen to initiate deletion of myeloid netrin-1 (Mø ΔNtn1 ) or not in controls (Mø WT ). Morphometric analyses performed 4 weeks later showed that myeloid Ntn1 silencing reduced plaque burden in the aorta (-50%) and plaque complexity in the aortic root. Monocyte-macrophage tracing experiments revealed lower monocyte recruitment, macrophage retention, and proliferation in Mø ΔNtn1 compared to Mø WT plaques, indicating a restructuring of monocyte-macrophage dynamics in the artery wall upon netrin-1 silencing. Single cell RNA-sequencing of aortic immune cells prior to and after netrin-1 silencing revealed upregulation of gene pathways involved in macrophage phagocytosis and migration, including the Ccr7 chemokine receptor signaling pathway required for macrophage emigration from plaques and atherosclerosis regression. Additionally, plaques from Mø ΔNtn1 mice showed hallmarks of inflammation resolution, including higher levels of pro-resolving macrophages, interleukin-10, and efferocytosis, as compared to plaques from Mø WT mice. Conclusions: Our data show that targeting netrin-1 in advanced atherosclerosis ameliorates atherosclerotic inflammation and promotes plaque regression.
Background and Aims: The progression of chronic liver diseases towards liver cirrhosis is accompanied by drastic tissue changes. This study combines elaborate transcriptomic and histological methods aiming at spatially resolving the hepatic immune microenvironment in NAFLD (including NASH, primary sclerosing cholangitis, primary biliary cholangitis, and severe alcoholic hepatitis). Approach and Results: Human liver samples were subjected to RNA-sequencing (n=225) and imaging cytometry (n=99) across 3 independent patient cohorts. Liver samples from alcoholic hepatitis and primary biliary cholangitis patients were used for comparison. Myeloid populations were further characterized in corresponding mouse models. Imaging, clinical, and phenotypical data were combined for multidimensional analysis. NAFLD/NASH and primary sclerosing cholangitis disease stages were associated with loss of parenchymal areas, increased ductular cell accumulation, and infiltration of immune cells. NASH patients predominantly exhibited myeloid cell accumulation, whereas primary sclerosing cholangitis patients additionally had pronounced lymphoid cell responses. Correlating to disease stage, both etiologies displayed intense IBA1+CD16lowCD163low macrophage aggregation in nonparenchymal areas, with a distinct spatial proximity to ductular cells. Mouse models revealed that disease-associated IBA1+ hepatic macrophages originated from bone marrow–derived monocytes. Using an unbiased, machine learning–based algorithm, IBA1 in combination with hepatocyte and ductular cell immunostaining–predicted advanced cirrhosis in human NASH, primary sclerosing cholangitis, and alcoholic hepatitis. Conclusions: Loss of hepatocytes and increased ductular reaction are tightly associated with monocyte-derived macrophage accumulation and represent the most prominent common immunological feature revealing the progression of NAFLD, primary sclerosing cholangitis, primary biliary cholangitis, and alcoholic hepatitis, suggesting IBA1+CD163low macrophages are key pathogenic drivers of human liver disease progression across diverse etiologies.
Rationale: MicroRNA-33 post-transcriptionally represses genes involved in lipid metabolism and energy homeostasis. Targeted inhibition of miR-33 increases plasma HDL cholesterol and promotes atherosclerosis regression, in part, by enhancing reverse cholesterol transport and dampening plaque inflammation. However, how miR-33 reshapes the immune microenvironment of plaques remains poorly understood. Objective: To define how miR-33 inhibition alters the dynamic balance and transcriptional landscape of immune cells in atherosclerotic plaques. Methods and Results: We used single cell RNA-sequencing of aortic CD45 + cells, combined with immunohistologic, morphometric and flow cytometric analyses to define the changes in plaque immune cell composition, gene expression and function following miR-33 inhibition. We report that anti-miR-33 treatment of Ldlr -/- mice with advanced atherosclerosis reduced plaque burden and altered the plaque immune cell landscape by shifting the balance of pro- and anti-atherosclerotic macrophage and T cell subsets. By quantifying the kinetic processes that determine plaque macrophage burden, we found that anti-miR-33 reduced levels of circulating monocytes and splenic myeloid progenitors, decreased macrophage proliferation and retention, and promoted macrophage attrition by apoptosis and efferocytotic clearance. scRNA-sequencing of aortic arch plaques showed that anti-miR-33 reduced the frequency of MHCIIhi "inflammatory" and Trem2hi "metabolic" macrophages, but not tissue resident macrophages. Furthermore, anti-miR-33 led to derepression of distinct miR-33 target genes in the different macrophage subsets: in resident and Trem2hi macrophages, anti-miR-33 relieved repression of miR-33 target genes involved in lipid metabolism (e.g., Abca1, Ncoa1, Ncoa2, Crot), whereas in MHCIIhi macrophages, anti-miR-33 upregulated target genes involved in chromatin remodeling and transcriptional regulation. Anti-miR-33 also reduced the accumulation of aortic CD8+ T cells and CD4+ Th1 cells, and increased levels of FoxP3+ regulatory T cells in plaques, consistent with an immune-dampening effect on plaque inflammation. Conclusions: Our results provide insight into the immune mechanisms and cellular players that execute anti-miR-33's atheroprotective actions in the plaque.
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