Recent evidence indicates that the most powerful anti-tumor T cells recognize neoantigens derived from unique mutated proteins expressed by an individual tumor, suggesting that precision vaccination is required to induce effective anti-tumor immunity in cancer patients. Importantly, such anti-tumor T cells cause tumor regression at advanced disease stages upon therapeutic immune checkpoints blockade. We have pioneered studies exploring the use of local tumor radiotherapy (RT) as a means to generate an in situ individualized vaccine. We were the first to demonstrate in a pre-clinical model that RT sensitizes unresponsive tumors to CTLA-4 blockade by inducing T cells specific for endogenous tumor antigens. Emerging evidence by us and others suggests a similar effect of RT in the clinic. However, lack of knowledge about the mechanisms involved precludes rapid progress towards the effective use of RT as an immune adjuvant. One critical unanswered question is whether dose and fractionation affect RT ability to elicit anti-tumor immune responses. We have previously found in two mouse carcinomas that generation of an in situ vaccine synergistic with anti-CTLA-4 treatment in inducing immune-mediated regression of irradiated and synchronous non-irradiated tumors (abscopal effect) was achieved by RT given in 3 fractions of 8 Gy but not by a single 20 Gy dose, suggesting that the RT regimen employed is critical. We now have data supporting the hypothesis that carcinoma cell-intrinsic activation of type I interferon (IFN-I) pathway by RT is required to generate an in situ vaccine, suggesting that RT triggers canonical defense pathways in neoplastic epithelial cells that mimic a viral infection. Our data also indicat that fractionated (FRT) but not single dose (SDRT) radiation can accomplish this via activation of the cytosolic DNA sensor cyclic GMP-AMP synthase (cGAS) and downstream stimulator of IFN genes (STING) within the irradiated cancer cells. To test the above hypothesis several mouse and human carcinoma cells will be employed to determine which RT dose/fractionation activates cGAS/STING. Next, in vivo experiments using cancer cells with selective knockdown of cGAS or STING implanted in syngeneic immunocompetent wild type, cGAS-deficient, and STING-deficient mice will be performed to determine the role of this pathway in RT-mediated induction of anti-tumor T cells that mediate tumor regression and abscopal responses. To determine whether the effects of IFN-I produced by irradiated cancer cells are cancer cell autonomous or require signaling in host DC, IFNAR1-deficient mice will be used as tumor recipient. The relationship between cancer cell-derived IFN-I and DC recruitment to tumors will be established. Finally, we will investigate the mechanisms whereby RT activates the cGAS/STING pathway in cancer cells. Overall, data obtained will have important implications for a novel use of radiotherapy as a relatively simple and widely available modality for individualized tumor vaccination.

Public Health Relevance

Recent evidence shows that unique mutated antigens expressed by a patient tumor can be targets of powerful anti-tumor immunity, but there are currently no reliable strategies to vaccinate patients against their own tumor. We have shown that local tumor radiation can induce anti-tumor immunity to antigens expressed by a tumor in place, but the mechanisms involved are incompletely understood. Improved understanding of the use of radiation to generate an effective individualized tumor vaccine could have huge benefits for cancer treatment.

Agency
National Institute of Health (NIH)
Institute
National Cancer Institute (NCI)
Type
Research Project (R01)
Project #
5R01CA201246-02
Application #
9207065
Study Section
Cancer Immunopathology and Immunotherapy Study Section (CII)
Program Officer
Ahmed, Mansoor M
Project Start
2016-01-19
Project End
2020-12-31
Budget Start
2017-01-01
Budget End
2017-12-31
Support Year
2
Fiscal Year
2017
Total Cost
Indirect Cost
Name
Weill Medical College of Cornell University
Department
Radiation-Diagnostic/Oncology
Type
Schools of Medicine
DUNS #
060217502
City
New York
State
NY
Country
United States
Zip Code
10065
Lhuillier, Claire; Vanpouille-Box, Claire; Galluzzi, Lorenzo et al. (2018) Emerging biomarkers for the combination of radiotherapy and immune checkpoint blockers. Semin Cancer Biol 52:125-134
Vanpouille-Box, Claire; Demaria, Sandra; Formenti, Silvia C et al. (2018) Cytosolic DNA Sensing in Organismal Tumor Control. Cancer Cell 34:361-378
Rodríguez-Ruiz, María E; Vanpouille-Box, Claire; Melero, Ignacio et al. (2018) Immunological Mechanisms Responsible for Radiation-Induced Abscopal Effect. Trends Immunol 39:644-655
Vanpouille-Box, Claire; Formenti, Silvia C; Demaria, Sandra (2018) Toward Precision Radiotherapy for Use with Immune Checkpoint Blockers. Clin Cancer Res 24:259-265
Diamond, Julie M; Vanpouille-Box, Claire; Spada, Sheila et al. (2018) Exosomes Shuttle TREX1-Sensitive IFN-Stimulatory dsDNA from Irradiated Cancer Cells to DCs. Cancer Immunol Res 6:910-920
Formenti, Silvia C; Rudqvist, Nils-Petter; Golden, Encouse et al. (2018) Radiotherapy induces responses of lung cancer to CTLA-4 blockade. Nat Med 24:1845-1851
Wennerberg, Erik; Vanpouille-Box, Claire; Bornstein, Sophia et al. (2017) Immune recognition of irradiated cancer cells. Immunol Rev 280:220-230
Vanpouille-Box, Claire; Alard, Amandine; Aryankalayil, Molykutty J et al. (2017) DNA exonuclease Trex1 regulates radiotherapy-induced tumour immunogenicity. Nat Commun 8:15618
Galluzzi, Lorenzo; Yamazaki, Takahiro; Demaria, Sandra (2017) Heavy Metal to Rock the Immune Infiltrate. Trends Immunol 38:539-541
Wennerberg, Erik; Lhuillier, Claire; Vanpouille-Box, Claire et al. (2017) Barriers to Radiation-InducedIn SituTumor Vaccination. Front Immunol 8:229

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