Tumor-infiltrating myeloid cells induce tumor cell resistance to cytotoxic T cells in mice
Tangying Lu, … , Michael B. Sporn, Dmitry Gabrilovich
Tangying Lu, … , Michael B. Sporn, Dmitry Gabrilovich
Published September 12, 2011
Citation Information: J Clin Invest. 2011;121(10):4015-4029. https://doi.org/10.1172/JCI45862.
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Research Article Immunology

Tumor-infiltrating myeloid cells induce tumor cell resistance to cytotoxic T cells in mice

Abstract

Cancer immunotherapeutic approaches induce tumor-specific immune responses, in particular CTL responses, in many patients treated. However, such approaches are clinically beneficial to only a few patients. We set out to investigate one possible explanation for the failure of CTLs to eliminate tumors, specifically, the concept that this failure is not dependent on inhibition of T cell function. In a previous study, we found that in mice, myeloid-derived suppressor cells (MDSCs) are a source of the free radical peroxynitrite (PNT). Here, we show that pre-treatment of mouse and human tumor cells with PNT or with MDSCs inhibits binding of processed peptides to tumor cell–associated MHC, and as a result, tumor cells become resistant to antigen-specific CTLs. This effect was abrogated in MDSCs treated with a PNT inhibitor. In a mouse model of tumor-associated inflammation in which the antitumor effects of antigen-specific CTLs are eradicated by expression of IL-1β in the tumor cells, we determined that therapeutic failure was not caused by more profound suppression of CTLs by IL-1β–expressing tumors than tumors not expressing this proinflammatory cytokine. Rather, therapeutic failure was a result of the presence of PNT. Clinical relevance for these data was suggested by the observation that myeloid cells were the predominant source of PNT in human lung, pancreatic, and breast cancer samples. Our data therefore suggest what we believe to be a novel mechanism of MDSC-mediated tumor cell resistance to CTLs.

Authors

Tangying Lu, Rupal Ramakrishnan, Soner Altiok, Je-In Youn, Pingyan Cheng, Esteban Celis, Vladimir Pisarev, Simon Sherman, Michael B. Sporn, Dmitry Gabrilovich

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Figure 6

Experimental model of tumor-associated inflammation.

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Experimental model of tumor-associated inflammation. (A and B) LLC-OVA o...
(A and B) LLC-OVA or LLC-IL-1β-OVA tumors were established in C57BL/6 mice. The percentages of MDSCs (A) and macrophages (B) were determined in spleens and tumors by flow cytometry. Data are mean ± SEM for 3 experiments. *P < 0.05. (C) Measurement of ROS in splenic MDSCs using the oxidation-sensitive dye DCFDA. Cells were incubated with DCFDA (2 μM) with or without PMA (300 nM) for 30 minutes in serum-free media. Cells were then washed and detected by flow cytometry. Cumulative results of 3 experiments are shown. (D) NO production by MDSCs was measured by detection of nitrite concentrations. Cumulative results of 3 experiments are shown. (E and F) NT staining in LLC and LLC-IL-1β tumors. Double staining of NT+ (brown) and either Gr-1+ or F4/80+ (red) cells in tumor tissues. Scale bars: 100 μm. (E) The percentages of NT+ cells in LLC and LLC-IL1β tumor tissues analyzed by Aperio software. Ten fields (800 × 600 μm2 each) were selected from each tumor, and mean ± SEM is shown. Four experiments with the same results were performed. *P < 0.01. (G and H) Antitumor effect of T cell therapy. Mice were injected s.c. with different numbers of LLC-OVA (G) or LLC-IL1β-OVA (H) cells, which provided for similar tumor sizes 2 weeks after inoculation. On days 18 and 23, 8 × 106 activated OT-I T cells were injected i.v. Tumors were measured. Each group included 9–12 mice. Data are mean ± SEM. In G the differences were significant on day 23. (P < 0.05).