Project description:Abstract: Despite impressive responses in some patients, immunotherapy fails to cure most cancer patients. Preclinical studies indicate that radiotherapy synergizes with immunotherapy, promoting radiation-induced antitumor immunity. Nearly all preclinical immunotherapy studies utilize transplant tumor models, but cure rates of transplant tumors treated with immunotherapy overestimate patient responses. Here, we show that transplant sarcomas are cured by PD-1 blockade and radiotherapy, but identical treatment fails in autochthonous sarcomas, which demonstrate tumor-specific immune tolerance. We characterize tumor-infiltrating immune cells from transplant and primary tumors and reveal striking differences in their immune landscapes. Although radiotherapy remodels myeloid cells in primary and transplant sarcomas, only transplant tumors are enriched for activated CD8+ T cells associated with tumor clearance. By CIBERSORTx, the immune microenvironment of primary sarcomas in mice transcriptionally resembles most human sarcomas, while transplant sarcomas model the most inflamed sarcomas in patients. These results identify distinct microenvironments in murine sarcomas that coevolve with the immune system and suggest that patients whose sarcomas have an immune phenotype similar to transplant tumors may benefit most from PD-1 blockade and radiotherapy.

Project description:Abstract: Transplanted tumors in syngeneic mice treated with immune checkpoint blockade and radiotherapy demonstrate synergy and an abscopal effect. Indeed, tumors generated from sarcoma cell lines transplanted into syngeneic mice are cured by PD-1 blockade and radiotherapy, but autochthonous, primary sarcomas from the same high mutational load model are resistant to the identical treatment. Here, we generated a single cell atlas of tumor-infiltrating immune cells from allograft and primary tumors, which demonstrates marked differences in their immune landscapes before and after radiation and immunotherapy. Allograft tumors are enriched for effector CD8+ T cells that mediate response to combination therapy, but the immune response to primary sarcomas shows tumor-specific tolerance. Genetic barcoding of primary tumors reveals a cellular response to combination therapy, but resistance of specific clones. Together, this comprehensive comparison of the primary and allograft tumor microenvironments identifies immune tolerance and clonal resistance to immunotherapy and radiotherapy specific to primary tumors.

Project description:Radiotherapy (RT) destroys tumor cells, which may lead to release of antigens and immune-activating signals. In this way, RT may act as an in situ vaccine and kick-start a T-cell response against the tumor. Immunotherapy enhances tumor-specific T-cell responses. Combination of radiotherapy and immunotherapy (radio-immunotherapy (RIT)) can therefore be expected to synergize in inducing and sustaining systemic anti-tumor T-cell responses. However, in the clinic, systemic combined responses between radiotherapy and immunotherapy are rarely observed, as the effect of RIT combinations on ‘abscopal’ tumors outside the radiotherapy field are not (yet) greater than the effect of immunotherapy alone. In order to define potential bottlenecks in the tumor micro-environment that impede CD8 T cell activity, we harvested irradiated and non-irradiated tumors from the same mice that were treated with RIT (10 Gy RT, anti-CD137 and anti-PD1). From these tumors, effector (CD43+) CD8 T cells, ‘other’ hematopoietic (CD45+) cells and tumor/stromal (CD45-) were sorted and RNA sequencing was performed to identify differences between these cell populations in the irradiated and non-irradiated tumors that could explain the lack of T cell activity in the non-irradiated tumor.

Project description:Immune checkpoint blockade is a powerful oncologic treatment modality for a wide variety of human malignancies. Randomized clinical trials are assessing how best to interdigitate this treatment modality with traditional therapies including radiotherapy. A challenge in oncology is to rationally and effectively integrate immunotherapy with traditional modalities including radiotherapy. Here, we demonstrate that radiotherapy induces tumor cell ferroptosis. Ferroptosis agonists augment and ferroptosis antagonists limit radiotherapy efficacy in tumor models. Immunotherapy sensitizes tumors to radiotherapy by promoting tumor cell ferroptosis. Mechanistically, IFN derived from immunotherapy-activated CD8+ T cells and radiotherapy-activated ATM independently, yet synergistically repress SLC7A11, a unit of the glutamate-cystine antiporter xc-, resulting in reduced cystine uptake, enhanced tumor lipid oxidation and ferroptosis, and improved tumor control. Thus, ferroptosis is an unappreciated mechanism and focus for the development of effective combinatorial cancer therapy.

Project description:Metastasis is the primary cause of cancer mortality. Cancer frequently metastasizes to the liver. We report that liver metastases diminish immunotherapy efficacy systemically in patients and preclinical models. Mechanistically, liver metastases siphon activated CD8+ T cells from systemic circulation. Within the liver, activated antigen-specific Fas+CD8+​ T cells undergo apoptosis following their interaction with FasL+CD11b+F4/80+ monocyte-derived macrophages. Consequently, liver metastases create a systemic immune desert in both preclinical models and patients. Liver-directed radiotherapy eliminates immunosuppressive hepatic macrophages, increases hepatic T-cell survival, and reduces hepatic siphoning. Thus, liver metastases co-opt host peripheral tolerance mechanisms to cause acquired immunotherapy resistance through CD8+ T-cell deletion and the combination of liver-directed radiotherapy and immunotherapy is a novel therapeutic strategy to promote systemic anti-tumour immunity.

Project description:The microenvironment has profound effect on macrophage phenotype. Here we examine the phenotype of macrophages infiltrating murine undifferentiated pleomorphic sarcomas. We used microarray to examine gene expression profile of tumor-associated macrophages in murine undifferentiated pleomorphic sarcomas. The immunosuppressive tumor microenvironment (TME) is a major barrier to immunotherapy. Within solid tumors, why monocytes preferentially differentiate into immunosuppressive tumor associated macrophages (TAMs) but not immunostimulatory dendritic cells (DCs) remains unclear. Using multiple murine sarcoma models, we found that the TME induced retinoic acid (RA) production by tumor cells, which polarized intratumoral monocyte differentiation towards TAMs and away from DCs via suppression of DC-promoting transcription factor Irf4. Genetic inhibition of RA production by tumor cells or pharmacologic inhibition of RA signaling within TME increased stimulatory monocyte-derived cells, enhanced T cell-dependent anti-tumor immunity and demonstrated striking synergy with immune checkpoint blockade. Further, RA responsive gene signature in human monocytes correlated with an immunosuppressive TME in multiple human tumors. RA has been long considered as an anti-cancer agent, but our work demonstrates its tumorigenic capability via myeloid-mediated immune suppression and provides proof of concept for targeting this pathway for tumor immunotherapy.

Project description:Single cell analysis reveals distinct immune landscapes in transplant and primary sarcomas that determine response or resistance to immunotherapy: Bulk Tumor RNA Sequencing for Rag2-/- and Rag2+/- primary p53/MCA tumors

Project description:Accumulating data support the concept that ionizing radiation therapy (RT) has the potential to convert the tumor into an in situ, individualized vaccine; however this potential is rarely realized by RT alone. Transforming growth factor β (TGFβ) is an immunosuppressive cytokine that is activated by RT and inhibits the antigen-presenting function of dendritic cells and the differentiation of effector CD8+ T cells. Here we tested the hypothesis that TGFβ hinders the ability of RT to promote anti-tumor immunity. Development of tumor-specific immunity was examined in a pre-clinical model of metastatic breast cancer. Mice bearing established 4T1 mouse mammary carcinoma treated with pan-isoform specific TGFβ neutralizing antibody, 1D11, showed significantly improved control of the irradiated tumor and non-irradiated metastases, but no effect in the absence of RT. Notably, whole tumor transcriptional analysis demonstrated the selective upregulation of genes associated with immune-mediated rejection only in tumors of mice treated with RT+TGFβ blockade. Mice treated with RT+TGFβ blockade exhibited cross-priming of CD8+ T cells producing IFNγ in response to three tumor-specific antigens in tumor-draining lymph nodes, which was not evident for single modality treatment. Analysis of the immune infiltrate in mouse tumors showed a significant increase in CD4+ and CD8+ T cells only in mice treated with the combination of RT+TGFβ blockade. Depletion of CD4+ or CD8+ T cells abrogated the therapeutic benefit of RT+TGFβ blockade. These data identify TGFβ as a master inhibitor of the ability of RT to generate an in situ tumor vaccine, which supports testing inhibition of TGFβ during radiotherapy to promote therapeutically effective anti-tumor immunity. We used genome-wide microarray to depict main biological processes responsibles for the therapeutic benefit of the combination ofTGF-beta blockade and local radiotherapy. To gain a more comprehensice protrait of the effects of RT and TGFbeta blockade on gene expressionin tumors, we collected 4T1 tumors 4 days after completion of RT. Three tumors from each group were then subjected to RNA extraction and hybridization on affymetrix array.

Project description:Immunotherapy study of phagocytosis checkpoint blockade in combination with radiotherapy

Project description:Immune checkpoint blockade has limited efficacy in microsatellite stable (MSS) colorectal (CRC) and pancreatic (PDAC) cancer. Preclinical models have demonstrated the use of radiation to activate the innate immune response and stimulate responsiveness to immune checkpoint blockade. Here, we describe a Phase 2 trial of radiation therapy combined with combined anti-CTLA4 (ipilimumab) and anti-PD1 (nivolumab) antibodies in MSS CRC and PDAC. In the per protocol analysis disease control rate was 37% (10/27) in CRC and 29% (5/17) in PDAC with an overall response rate of 15% (4/27) and 18% (3/17), respectively. Whole exome and RNA sequencing of biopsies from 17 patients revealed low tumor mutational burden in all tumors, but a notable upregulation of interferon stimulated genes with concordant high expression of multiple repeat RNA transcripts in responders. Altogether, this study provides foundational human proof of concept of radiation with combination immune checkpoint blockade therapy in otherwise immunotherapy resistant cancers.