Itaconate suppresses atherosclerosis by activating a Nrf2-dependent antiinflammatory response in macrophages in mice
Jianrui Song, Yanling Zhang, Ryan A. Frieler, Anthony Andren, Sherri Wood, Daniel J. Tyrrell, Peter Sajjakulnukit, Jane C. Deng, Costas A. Lyssiotis, Richard M. Mortensen, Morgan Salmon, Daniel R. Goldstein
Jianrui Song, Yanling Zhang, Ryan A. Frieler, Anthony Andren, Sherri Wood, Daniel J. Tyrrell, Peter Sajjakulnukit, Jane C. Deng, Costas A. Lyssiotis, Richard M. Mortensen, Morgan Salmon, Daniel R. Goldstein
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Research Article Cardiology Inflammation

Itaconate suppresses atherosclerosis by activating a Nrf2-dependent antiinflammatory response in macrophages in mice

Abstract

Itaconate has emerged as a critical immunoregulatory metabolite. Here, we examined the therapeutic potential of itaconate in atherosclerosis. We found that both itaconate and the enzyme that synthesizes it, aconitate decarboxylase 1 (Acod1, also known as immune-responsive gene 1 [IRG1]), are upregulated during atherogenesis in mice. Deletion of Acod1 in myeloid cells exacerbated inflammation and atherosclerosis in vivo and resulted in an elevated frequency of a specific subset of M1-polarized proinflammatory macrophages in the atherosclerotic aorta. Importantly, Acod1 levels were inversely correlated with clinical occlusion in atherosclerotic human aorta specimens. Treating mice with the itaconate derivative 4-octyl itaconate attenuated inflammation and atherosclerosis induced by high cholesterol. Mechanistically, we found that the antioxidant transcription factor, nuclear factor erythroid 2–related factor 2 (Nrf2), was required for itaconate to suppress macrophage activation induced by oxidized lipids in vitro and to decrease atherosclerotic lesion areas in vivo. Overall, our work shows that itaconate suppresses atherogenesis by inducing Nrf2-dependent inhibition of proinflammatory responses in macrophages. Activation of the itaconate pathway may represent an important approach to treat atherosclerosis.

Authors

Jianrui Song, Yanling Zhang, Ryan A. Frieler, Anthony Andren, Sherri Wood, Daniel J. Tyrrell, Peter Sajjakulnukit, Jane C. Deng, Costas A. Lyssiotis, Richard M. Mortensen, Morgan Salmon, Daniel R. Goldstein

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Figure 3

Single-cell analysis of macrophages within the atherosclerotic aorta of WT and Acod1–/– mice.

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Single-cell analysis of macrophages within the atherosclerotic aorta of ...
WT and Acod1–/– mice were induced to become atherosclerotic via PCSK9-AAV administration followed by 10-week Western diet. (A) UMAP plot showing 8 different macrophage subpopulations revealed by scRNA-seq. (B) The expression of representative signature genes from each macrophage subpopulation was overlaid on the UMAP plot. Color intensity indicates normalized expression levels as shown for each gene. (C) The expression of M1-like and M2-like marker genes in each macrophage subpopulation was determined. The size of the dots indicates the percentage of cells expressing the gene of interest, while the intensity of the color indicates expression levels. (D) UMAP plots of macrophages from atherosclerotic WT and Acod1–/– aortas. Clusters are colored as in A. (E) The proportion of macrophage subpopulations from atherosclerotic WT and Acod1–/– aortas. (F) Differential abundance testing of changes in the proportion of macrophage subpopulations in atherosclerotic Acod1–/– aortas. Clusters that passed the threshold of adjusted P values < 0.05 and log2FC > 1.2 were deemed significant and colored. FC, fold change. (G) Volcano plot showing differentially expressed genes in macrophages from atherosclerotic Acod1–/– aortas. Up- and downregulated genes are colored orange and green, respectively. FDR, false discovery rate. (H) Violin plots showing the expression of 2 representative genes, Ccl3 and Irf7, that were differentially expressed between WT and Acod1–/– across all macrophage subpopulations. (I and J) Gene ontology analysis of (I) up- and (J) downregulated genes in macrophages from atherosclerotic Acod1–/– aortas.