RAGE impairs murine diabetic atherosclerosis regression and implicates IRF7 in macrophage inflammation and cholesterol metabolism
Laura Senatus, Raquel López-Díez, Lander Egaña-Gorroño, Jianhua Liu, Jiyuan Hu, Gurdip Daffu, Qing Li, Karishma Rahman, Yuliya Vengrenyuk, Tessa J. Barrett, M. Zahidunnabi Dewan, Liang Guo, Daniela Fuller, Aloke V. Finn, Renu Virmani, Huilin Li, Richard A. Friedman, Edward A. Fisher, Ravichandran Ramasamy, Ann Marie Schmidt
Laura Senatus, Raquel López-Díez, Lander Egaña-Gorroño, Jianhua Liu, Jiyuan Hu, Gurdip Daffu, Qing Li, Karishma Rahman, Yuliya Vengrenyuk, Tessa J. Barrett, M. Zahidunnabi Dewan, Liang Guo, Daniela Fuller, Aloke V. Finn, Renu Virmani, Huilin Li, Richard A. Friedman, Edward A. Fisher, Ravichandran Ramasamy, Ann Marie Schmidt
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Research Article Inflammation Vascular biology

RAGE impairs murine diabetic atherosclerosis regression and implicates IRF7 in macrophage inflammation and cholesterol metabolism

Abstract

Despite advances in lipid-lowering therapies, people with diabetes continue to experience more limited cardiovascular benefits. In diabetes, hyperglycemia sustains inflammation and preempts vascular repair. We tested the hypothesis that the receptor for advanced glycation end-products (RAGE) contributes to these maladaptive processes. We report that transplantation of aortic arches from diabetic, Western diet–fed Ldlr—/— mice into diabetic Ager—/— (Ager, the gene encoding RAGE) versus WT diabetic recipient mice accelerated regression of atherosclerosis. RNA-sequencing experiments traced RAGE-dependent mechanisms principally to the recipient macrophages and linked RAGE to interferon signaling. Specifically, deletion of Ager in the regressing diabetic plaques downregulated interferon regulatory factor 7 (Irf7) in macrophages. Immunohistochemistry studies colocalized IRF7 and macrophages in both murine and human atherosclerotic plaques. In bone marrow–derived macrophages (BMDMs), RAGE ligands upregulated expression of Irf7, and in BMDMs immersed in a cholesterol-rich environment, knockdown of Irf7 triggered a switch from pro- to antiinflammatory gene expression and regulated a host of genes linked to cholesterol efflux and homeostasis. Collectively, this work adds a new dimension to the immunometabolic sphere of perturbations that impair regression of established diabetic atherosclerosis and suggests that targeting RAGE and IRF7 may facilitate vascular repair in diabetes.

Authors

Laura Senatus, Raquel López-Díez, Lander Egaña-Gorroño, Jianhua Liu, Jiyuan Hu, Gurdip Daffu, Qing Li, Karishma Rahman, Yuliya Vengrenyuk, Tessa J. Barrett, M. Zahidunnabi Dewan, Liang Guo, Daniela Fuller, Aloke V. Finn, Renu Virmani, Huilin Li, Richard A. Friedman, Edward A. Fisher, Ravichandran Ramasamy, Ann Marie Schmidt

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Figure 1

RAGE is expressed in regressing atherosclerotic plaques.

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RAGE is expressed in regressing atherosclerotic plaques. (A) Model schem...
(A) Model schematic: atherosclerotic aortic arches from Ldlr—/— mice were transplanted into WT, Ager—/—, diaphanous related formin 1–deficient (Diaph1—/—), or Tg glyoxalase-1 (Glo1) recipient mice and harvested at the indicated times after aortic arch transplantation. (B) Representative images of en face Sudan IV staining of atherosclerotic lesions in nondiabetic Ldlr—/—and diabetic Ldlr—/— mice. Quantification of plaque area as percentage of total aortic surface area is shown; N = 10 mice/group. (C) Immunofluorescence staining for RAGE and CD68 of atherosclerotic plaques 5 days after aortic arch transplantation. Representative images from N = 4 mice/group are shown. Scale bars: 250 μm, and inset, 50 μm. The secondary antibody–alone control is shown. (D) Laser capture microdissection of CD68+ cells 5 days posttransplantation. Representative images from N = 4 mice/group are shown. Scale bar: 100 μm. (E) Ager mRNA expression in macrophages captured from D (N = 4 mice/group). Mean ± SEM. Unpaired t test was performed in B and E. ****P < 0.0001.