VEGFR2 activity on myeloid cells mediates immune suppression in the tumor microenvironment
Yuqing Zhang, Huocong Huang, Morgan Coleman, Arturas Ziemys, Purva Gopal, Syed M. Kazmi, Rolf A. Brekken
Yuqing Zhang, Huocong Huang, Morgan Coleman, Arturas Ziemys, Purva Gopal, Syed M. Kazmi, Rolf A. Brekken
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Research Article Immunology Oncology

VEGFR2 activity on myeloid cells mediates immune suppression in the tumor microenvironment

Abstract

Angiogenesis, a hallmark of cancer, is induced by vascular endothelial growth factor–A (hereafter VEGF). As a result, anti-VEGF therapy is commonly used for cancer treatment. Recent studies have found that VEGF expression is also associated with immune suppression in patients with cancer. This connection has been investigated in preclinical and clinical studies by evaluating the therapeutic effect of combining antiangiogenic reagents with immune therapy. However, the mechanisms of how anti-VEGF strategies enhance immune therapy are not fully understood. We and others have shown selective elevation of VEGFR2 expression on tumor-associated myeloid cells in tumor-bearing animals. Here, we investigated the function of VEGFR2+ myeloid cells in regulating tumor immunity and found VEGF induced an immunosuppressive phenotype in VEGFR2+ myeloid cells, including directly upregulating the expression of programmed cell death 1 ligand 1. Moreover, we found that VEGF blockade inhibited the immunosuppressive phenotype of VEGFR2+ myeloid cells, increased T cell activation, and enhanced the efficacy of immune checkpoint blockade. This study highlights the function of VEGFR2 on myeloid cells and provides mechanistic insight on how VEGF inhibition potentiates immune checkpoint blockade.

Authors

Yuqing Zhang, Huocong Huang, Morgan Coleman, Arturas Ziemys, Purva Gopal, Syed M. Kazmi, Rolf A. Brekken

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Figure 5

VEGF blockade by mcr84 promotes perivascular accumulation of T cells and stimulates T cell activation.

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VEGF blockade by mcr84 promotes perivascular accumulation of T cells and...
(A) Flow cytometry analysis or IHC of the indicated cell types in 4T1 tumors. (B) Normalized distribution of CD8+ T cells around CD31+ blood vessels in 4T1 tumors (n = 5/group). Representative images of CD8 (brown) and CD31 (red) staining in 4T1 tumors are shown. Scale bar: 50 μm. (C and D) Flow cytometry analysis of PD-1, CTLA-4, EOMES, intracellular IFN-γ, and granzyme B on CD8+ T cells in 4T1 tumors treated as indicated. (E and F) Flow cytometry analysis of intracellular IFN-γ (E) and TNF-α (F) expression on CD8+ T cells in MC38 tumors treated as indicated. The left panels (E and F) show representative flow cytometry analysis of indicated cytokines in gated CD8+ T cells. (G and H) Flow cytometry analysis of T effector cells/exhausted T cells (G) and Tregs (H) in 4T1 and MC38 tumors treated as indicated. T effector cells were characterized as PD-1Ki67+CD8+ T cells. Exhausted T cells were characterized as CTLA-4+PD-1+CD8+ T cells. Tregs were characterized as CD25+FoxP3+CD4+ T cells. Each dot indicates 1 tumor. Data are displayed as mean ± SEM with 5 to 9 animals per group. (IK) An in vitro cell cytotoxicity assay was performed following the instructions of the basic cytotoxicity assay kit. Splenocytes from animals treated as indicated, or splenic CD8+ T cells from OT-1 MC38 TB mice were cocultured with CFSE prelabeled 4T1, MC38, or MC38-OVA cells at different ratios for 72 or 48 hours. Dead cells were labeled with 7-AAD. Samples were analyzed by flow cytometry. Representative images of gating strategy of 4T1 coculture are shown (I). Cytotoxicity percentages were calculated in (I) (4T1), (J) (MC38), and (K) (MC38-OVA). n = 2 to 3/group. *, P < 0.05; **, P < 0.005 vs. control, by Welch’s t test.