Abstract
Simple SummaryThe recent discovery of immune checkpoint inhibitors constituted a breakthrough in cancer treatment, but most patients are resistant to this therapy. Although the co-stimulatory molecule cluster of differentiation (CD) 80 has been detected in several types of tumor cells, its role in the tumor microenvironment and its sensitivity to immune checkpoint blockade are unclear. We, therefore, introduced a clinically relevant mouse tumor model with deactivated CD80. The deactivation promoted a “hot” tumor microenvironment and enhanced the sensitivity to immune checkpoint blockade with antibody against the cytotoxic T-lymphocyte antigen 4 (CTLA-4). This study contributed to the research into predictive markers to select patients who are suitable for immune checkpoint blockade therapy and suggested the development of a novel cancer immunotherapy based on a tumor-cell-targeted CD80 blockade. Cluster of differentiation (CD) 80 is mainly expressed in immune cells but can also be found in several types of cancer cells. This molecule may either activate or inhibit immune reactions. Here, we determined the immunosuppressive role of CD80 in the tumor microenvironment by CRISPR/Cas9-mediated deactivation of the corresponding gene in the mouse oncogenic TC-1 cell line. The tumor cells with deactivated CD80 (TC-1/dCD80-1) were more immunogenic than parental cells and induced tumors that gained sensitivity to cytotoxic T-lymphocyte antigen 4 (CTLA-4) blockade, as compared with the TC-1 cells. In vivo depletion experiments showed that the deactivation of CD80 switched the pro-tumorigenic effect of macrophages observed in TC-1-induced tumors into an anti-tumorigenic effect in TC-1/dCD80-1 tumors and induced the pro-tumorigenic activity of CD4+ cells. Moreover, the frequency of lymphoid and myeloid cells and the CTLA-4 expression by T helper (Th)17 cells were increased in TC-1/dCD80-1- compared with that in the TC-1-induced tumors. CTLA-4 blockade downregulated the frequencies of most immune cell types and upregulated the frequency of M2 macrophages in the TC-1 tumors, while it increased the frequency of lymphoid cells in TC-1/dCD80-1-induced tumors. Furthermore, the anti-CTLA-4 therapy enhanced the frequency of CD8+ T cells as well as CD4+ T cells, especially for a Th1 subset. Regulatory T cells (Treg) formed the most abundant CD4+ T cell subset in untreated tumors. The anti-CTLA-4 treatment downregulated the frequency of Treg cells with limited immunosuppressive potential in the TC-1 tumors, whereas it enriched this type of Treg cells and decreased the Treg cells with high immunosuppressive potential in TC-1/dCD80-1-induced tumors. The immunosuppressive role of tumor-cell-expressed CD80 should be considered in research into biomarkers for the prediction of cancer patients’ sensitivity to immune checkpoint inhibitors and for the development of a tumor-cell-specific CD80 blockade.
Highlights
The costimulatory molecule cluster of differentiation (CD) 80, which can be expressed on antigen-presenting cells (APCs) or tumor cells, interacts with both costimulatory (CD28)and coinhibitory (cytotoxic T-lymphocyte antigen 4 (CTLA-4)) receptors and regulates the immune response [1,2]
To investigate the impact of the CD80 deactivation in tumor cells on anti-tumor immune reactions, we depleted CD4+, CD8+, natural killer (NK) 1.1+ cells, or macrophages in mice bearing TC-1- and TC-1/dCD80-1-induced tumors (Figure 3)
The proportion of Treg subpopulation 3 was increased in TC1/dCD80-1-induced tumors treated with CTLA-4 blockade, which resulted in a significant difference in this subpopulation in comparison with the TC-1-induced tumors treated with the same antibody
Summary
The costimulatory molecule cluster of differentiation (CD) 80, which can be expressed on antigen-presenting cells (APCs) or tumor cells, interacts with both costimulatory (CD28). Treg cells inhibit the anti-tumor immune response, enhance cancer progression, and mediate resistance to cancer therapy by several mechanisms. CTLA-4 inhibits the immune response via a blockade of antigen presentation due to its higher affinity to CD80 in comparison with CD28. Regarding the various interacting partners of CD80, with their broad range of effects on anti-tumor immune responses, the role of CD80 in the tumor microenvironment and its impact on the efficacy of cancer therapy need to be elucidated. Regarding the various interacting partners of CD80, with their broad range of effects on anti-tumor immune responses, the role of CD80 in the tumor microenvironment aofn1d7 its impact on the efficacy of cancer therapy need to be elucidated. W Whhiillee tthhee ggrroowwtthh ooff tthheeTTCC--11//ddCCDD8800--11--iinndduucceeddttuummoorrssaaftfeterrininoocuculaltaitoinonofo3f 3××11004 4aanndd11×× 110055 cceellllss wwaass sslloowweerr tthhaann tthhaatt ooff TTCC--11--iinndduucceeddttuummoorrss,,tthhee33×× 110055 ddoosseessiiggnniiffiiccaannttllyy eennhhaanncceedd tthhee ggrroowwtthh ooff TTCC--11//ddCCDD8800--11--inindduucceeddttuummoorrssaannddpprroovviiddeeddttuummoorrss ooff aa ssiimmiillaarr ssiizzee ttoo tthhoossee iinndduucceedd wwiitthh 33 ××110044TTCC-1-1ceclellsls(F(Figiguurere22BB).)
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