CD11c+ macrophages are proangiogenic and necessary for experimental choroidal neovascularization
Steven Droho, … , Harris Perlman, Jeremy A. Lavine
Steven Droho, … , Harris Perlman, Jeremy A. Lavine
Published February 23, 2023
Citation Information: JCI Insight. 2023;8(7):e168142. https://doi.org/10.1172/jci.insight.168142.
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Research Article Inflammation Ophthalmology

CD11c+ macrophages are proangiogenic and necessary for experimental choroidal neovascularization

Abstract

Patients with neovascular AMD (nAMD) suffer vision loss from destructive angiogenesis, termed choroidal neovascularization (CNV). Macrophages are found in CNV lesions from patients with nAMD. Additionally, Ccr2–/– mice, which lack classical monocyte–derived macrophages, show reduced CNV size. However, macrophages are highly diverse cells that can perform multiple functions. We performed single-cell RNA-Seq on immune cells from WT and Ccr2–/– eyes to uncover macrophage heterogeneity during the laser-induced CNV mouse model of nAMD. We identified 12 macrophage clusters, including Spp1+ macrophages. Spp1+ macrophages were enriched from WT lasered eyes and expressed a proangiogenic transcriptome via multiple pathways, including vascular endothelial growth factor signaling, endothelial cell sprouting, cytokine signaling, and fibrosis. Additionally, Spp1+ macrophages expressed the marker CD11c, and CD11c+ macrophages were increased by laser and present in CNV lesions. Finally, CD11c+ macrophage depletion reduced CNV size by 40%. These findings broaden our understanding of ocular macrophage heterogeneity and implicate CD11c+ macrophages as potential therapeutic targets for treatment-resistant patients with nAMD.

Authors

Steven Droho, Amrita Rajesh, Carla M. Cuda, Harris Perlman, Jeremy A. Lavine

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Figure 6

CD11c+ macrophages are significantly increased by laser injury.

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CD11c+ macrophages are significantly increased by laser injury. (A) Flow...
(A) Flow cytometry gating strategy. Left panel: CD45+ cells were identified from Live, Singlet cells identically to Figure 1B. Middle left panel: Lineage (CD4, CD8 [T cells], B220 [B cells], Ly6G [neutrophils], NK1.1 [NK cells], SiglecF [eosinophils]) versus CD11b plot to gate forward CD11b+Lin mononuclear phagocytes. Middle right panel: CD64+ macrophages were discriminated from CD64 monocytes and DCs. Right panel: Cx3cr1 versus CD45 plot to delineate Cx3cr1hiCD45dim microglia from CD45hi infiltrating macrophages. (B and C) Flow cytometry gating strategy for the identification of macrophage and microglia subtypes, DCs, and monocytes from control (B) and laser-treated (C) choroid and retina. Right panel: CD45hi infiltrating macrophages were separated into 4 groups: CD11c+, CD11c+Ly6C+, Ly6C+, and double-negative (DN) macrophages. Middle right panel: CD45dim microglia were divided into 2 groups: CD11c+ and CD11c microglia. Middle left panel: DCs were identified as CD64MHCII+CD11c+ cells. Left panel: Ly6C versus Cx3cr1 plot from Not DC cells to delineate Ly6C+Cx3cr1+ classical monocytes and Ly6CCx3cr1+ nonclassical monocytes. (DF and HJ) Quantitative analysis of mononuclear phagocyte cell numbers after laser treatment. CD11c+ macrophages (D, Welch’s t test), CD11c+Ly6C+ macrophages (E, Welch’s t test), Ly6C+ macrophages (F, unpaired t test), CD11c+ microglia (H, unpaired t test), CD11c microglia (I, unpaired t test), and DCs (J, unpaired t test) were significantly increased in the choroid and retina after laser treatment (n = 6 per group for all). (G, K, and L) DN macrophage (G, Welch’s t test), classical monocyte (K, unpaired t test), and nonclassical monocytes (L, Welch’s t test) numbers were not significantly increased after laser treatment. *P < 0.05, **P < 0.01, ***P < 0.001, ****P < 0.0001.