C3d regulates immune checkpoint blockade and enhances antitumor immunity
Jeffrey L. Platt, … , Michael C. Carroll, Marilia Cascalho
Jeffrey L. Platt, … , Michael C. Carroll, Marilia Cascalho
Published May 4, 2017
Citation Information: JCI Insight. 2017;2(9):e90201. https://doi.org/10.1172/jci.insight.90201.
View: Text | PDF
Research Article Immunology

C3d regulates immune checkpoint blockade and enhances antitumor immunity

Abstract

Despite expression of immunogenic polypeptides, tumors escape immune surveillance by engaging T cell checkpoint regulators and expanding Tregs, among other mechanisms. What orchestrates these controls is unknown. We report that free C3d, a fragment of the third component of complement, inside tumor cells — or associated with irradiated tumor cells and unattached to antigen — recruits, accelerates, and amplifies antitumor T cell responses, allowing immunity to reverse or even to prevent tumor growth. C3d enhances antitumor immunity independently of B cells, NK cells, or antibodies, but it does so by increasing tumor infiltrating CD8+ lymphocytes, by depleting Tregs, and by suppressing expression of programmed cell death protein 1 (PD-1) by T cells. These properties of C3d appear specific for the tumor and dependent on complement receptor 2, and they incur no obvious systemic toxicity. The heretofore unrecognized properties of free C3d suggest that protein might determine the effectiveness of immune surveillance and that increasing availability of the protein might prove advantageous in the treatment or prevention of cancer and premalignant conditions.

Authors

Jeffrey L. Platt, Inês Silva, Samuel J. Balin, Adam R. Lefferts, Evan Farkash, Ted M. Ross, Michael C. Carroll, Marilia Cascalho

×

Figure 3

Impact of C3d on expression of CR2 (CD21) by Tregs and on apoptosis of Tregs and CD8+ cells in lymphomas.

Options: View larger image (or click on image) Download as PowerPoint
Impact of C3d on expression of CR2 (CD21) by Tregs and on apoptosis of T...
(A) CR2 expression by Tregs after introduction of C3d+ or C3d lymphoma cells. Expression was determined by qPCR relative to GAPDH; CR2 expression by naive Tregs was subtracted. Graphs reflect analysis of 3–7 mice per time point, in triplicate. (B and F) Frequency of CD21+ Tregs determined by flow cytometry analysis of splenocytes. (C and G) Expression of CR2 (CD21) and caspase-3 and -7 in Tregs (CD4+, Foxp3+), assayed by flow cytometry, in mice injected with C3d+ or C3d lymphoma cells 10 days before analysis. The graphs depict frequencies of apoptotic Tregs in tumor-recipient mice. (D) Frequency of Tregs (CD4+, Foxp3+) determined by flow cytometry, 18 days after tumor transfer. (E) Immunofluorescence analysis of frozen sections of C3d+ or C3d lymphoid tumors stained with anti-Foxp3 antibodies (green). Each panel is representative of at least 3 different tumors. (H and I) Expression of caspase-3 and -7 in CD8+ T cells assayed by flow cytometry, in mice injected with C3d+ or C3d lymphoma cells 10 days before analysis. Flow cytometry graphs reflect analysis of splenocytes in 4–5 mice per condition. Boxes represent distribution of data between the 25th and the 75th percentiles. The mean is indicated by a horizontal line, and whiskers represent maximum and minimum values. Statistical analysis in A and B was by the Kruskal Wallis test followed by Dunn’s multiple comparison test. Analysis in C, D, and I was by the Mann Whitney 2-tailed test.