Suppressed monocyte recruitment drives macrophage removal from atherosclerotic plaques of Apoe–/– mice during disease regression
Stephane Potteaux, … , Mary G. Sorci-Thomas, Gwendalyn J. Randolph
Stephane Potteaux, … , Mary G. Sorci-Thomas, Gwendalyn J. Randolph
Published April 18, 2011
Citation Information: J Clin Invest. 2011;121(5):2025-2036. https://doi.org/10.1172/JCI43802.
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Research Article Vascular biology

Suppressed monocyte recruitment drives macrophage removal from atherosclerotic plaques of Apoe–/– mice during disease regression

Abstract

Experimental models of atherosclerosis suggest that recruitment of monocytes into plaques drives the progression of this chronic inflammatory condition. Cholesterol-lowering therapy leads to plaque stabilization or regression in human atherosclerosis, characterized by reduced macrophage content, but the mechanisms that underlie this reduction are incompletely understood. Mice lacking the gene Apoe (Apoe–/– mice) have high levels of cholesterol and spontaneously develop atherosclerotic lesions. Here, we treated Apoe–/– mice with apoE-encoding adenoviral vectors that induce plaque regression, and investigated whether macrophage removal from plaques during this regression resulted from quantitative alterations in the ability of monocytes to either enter or exit plaques. Within 2 days after apoE complementation, plasma cholesterol was normalized to wild-type levels, and HDL levels were increased 4-fold. Oil red O staining and quantitative mass spectroscopy revealed that esterified cholesterol content was markedly reduced. Plaque macrophage content decreased gradually and was 72% lower than baseline 4 weeks after apoE complementation. Importantly, this reduction in macrophages did not involve migratory egress from plaques or CCR7, a mediator of leukocyte emigration. Instead, marked suppression of monocyte recruitment coupled with a stable rate of apoptosis accounted for loss of plaque macrophages. These data suggest that therapies to inhibit monocyte recruitment to plaques may constitute a more viable strategy to reduce plaque macrophage burden than attempts to promote migratory egress.

Authors

Stephane Potteaux, Emmanuel L. Gautier, Susan B. Hutchison, Nico van Rooijen, Daniel J. Rader, Michael J. Thomas, Mary G. Sorci-Thomas, Gwendalyn J. Randolph

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Figure 4

Analysis of blood monocyte numbers and phenotype following apoE complementation.

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Analysis of blood monocyte numbers and phenotype following apoE compleme...
(A) Total monocytes and monocyte subsets were quantified by flow cytometry in blood of baseline mice or 4 weeks after infection with ad-Empty and ad-hApoE3 (n = 10–34 mice per bar). (B) CD11b and (C) CD62L (Ly-6Chi monocytes only) expression was analyzed with (black bars) or without apoE complementation (white bars) of Apoe–/– mice maintained on a HFD. n = 5–9 mice per bar; *P < 0.01. (D) Flow plot overlays show whole leukocyte fraction in blood (gray) overlaid with profiles of Ly-6Clo monocytes (black) from Apoe–/– mice fed a HFD followed by apoE complementation or no complementation. (E) Summary of relative changes in SSC-A shifts in Ly-6Clo monocytes from Apoe–/– mice on a HFD complemented (black bar) or not (white bars) with apoE-encoding vector. Data are compared with SSC-A of monocytes from Apoe+/+ control mice. (F) Effect of hApoE3 complementation on surface expression of CD115. n = 5 mice per bar; **P < 0.001.