Project description:We hypothesized that gene expression changes in EMT6.5 tumors after Microbeam Radiotherapy (MRT) are different from those seen after broad beam (BB) at 4-48 h postirradiation. Our findings demonstrate molecular differences in the tumor response to MRT vs. BB and provide insight into the underlying mechanisms of MRT and BB.

Project description:We hypothesized that gene expression changes in EMT6.5 tumors after Microbeam Radiotherapy (MRT) are different from those seen after broad beam (BB) at 4-48 h postirradiation. Our findings demonstrate molecular differences in the tumor response to MRT vs. BB and provide insight into the underlying mechanisms of MRT and BB. Total RNA obtained from isolated EMT6.5 tumours irradiated by MRT or BB at 4, 24 or 48 hours post-irradiation compared to unirradiated control tumours.

Project description:Immunotherapy holds tremendous promise for improving cancer treatment. Administering radiotherapy with immunotherapy has been shown to improve immune responses and can elicit an “abscopal effect”. Unfortunately, response rates for this strategy remain low. Herein, we report an improved cancer immunotherapy approach that utilizes antigen-capturing nanoparticles (AC-NPs). We engineered several AC-NPs formulations and by using a proteomic approach, we demonstrated that the set of protein antigens captured by each AC-NP formulation is dependent upon NP surface properties.

Project description:Most metastatic melanoma patients show variable responses to radiotherapy and do not benefit from immune checkpoint inhibitors (ICIs). Improved strategies for combination therapy that leverage potential benefits from radiotherapy and ICI are critical. Genes coding for subunits of GABAARs express functional GABAARs in melanoma cells. By enhancing GABAAR mediated anion transport, benzodiazepines depolarize melanoma cells and impair their viability. In vivo, benzodiazepine alone reduces tumor growth and potentiates radiotherapy and α-PD-L1 anti-tumor activity. Combination of benzodiazepine, radiotherapy, and α-PD-L1 results in near complete regression of treated tumors and a potent abscopal effect, mediated by increased infiltration of polyfunctional CD8+ T cells. Treated tumors show expression of cytokine:cytokine receptor interactions and overrepresentation of p53 signaling. This study identifies an anti-tumor strategy combining radiation and/or immune checkpoint inhibitor with modulation of GABAARs in melanoma using a benzodiazepine.

Project description:In this study, we have identified candidates for IFN-M-NM-3-inducible CTLs-suppressive factors in melanoma cells using cDNA microarray analysis Double-stranded cDNAs were synthesized from mRNAs extracted from melanoma cell lines that express melanoma-associated antigen recognized by T cells 1 (MART-1) and HLA-A*0201 (526mel, 1833mel, 2487mel, and 501Amel), with or without pretreatment with recombinant human IFN-M-NM-3 (rhIFN-M-NM-3, 1000 U/mL, 48hours).

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:Despite accumulating cases of radiotherapy-induced abscopal effect in the lung cancer with the introduction of immune checkpoint inhibitors (ICIs), the occurrence of this effect remains infrequent and unpredictable to be a therapeutic goal. Here, we showed that the combination of radiotherapy (8Gy*3F) and ICI alleviated the tumor burden at the irradiated site whereas no discernible benefit was observed in the abscopal tumors. RNA-sequencing data showed that extracellular structure organization pathways were enriched in the abscopal tumors after combined therapy, with Sfrp2 being identified as a central hub. SFRP2 expression was observed in cancer-associated fibroblasts (CAFs) and was elevated in abscopal tumors after combined therapy. Blockade of SFRP2 followed by combined radiotherapy and ICI reinvigorated infiltration and cytotoxicity of CD8+ T cells, and elicited regression of abscopal tumors, which was abrogated by CD8α depletion. Mechanistically, in vitro experiments demonstrated that SFRP2+ CAFs induced apoptosis of CD8+ T cells. The spatial transcriptome analysis showed that SFRP2+ CAFs were located in proximity to the vessels and surrounded by abundant macrophages and limited CD8Tex, thereby creating an immunosuppressive perivascular niche, which was validated in paraffin sections of human lung cancer. Lineage-tracing assays showed SFRP2+ CAFs were derived from pericytes. IGF-1 released by irradiated tumors facilitated the transition of pericytes into fibroblasts and stimulated the expression of SFRP2. In summary, SFRP2+ CAFs hijack the abscopal effect from combined radiotherapy and immunotherapy via inducing apoptosis of CD8+ T cells and orchestrating a hostile perivascular niche in the lung cancer. Targeting SFRP2+ CAF may recondition the TME and promote the abscopal effect.

Project description:Radiation therapy is a mainstay of cancer treatment, with more than 50% of all cancer patients receiving radiation during the course of their disease. Tumor irradiation can activate both innate and adaptive immune responses, and these responses can be pro- or anti-tumor growth . These observations have led to the search for antitumor approaches combining radiotherapy and specific immunotherapies, most commonly strategies promoting the systemic activation of T cells. Thus far, however, many cancer patients still suffer from local recurrence and/or untreatable metastatic disease after radiotherapy. Here we combine radiotherapy with activation of macrophage-mediated phagocytosis via blockade of the ?don?t-eat-me? cell surface molecule CD47 in small-cell lung cancer (SCLC), a highly metastatic form of lung cancer for which treatment options remain limited. We found that irradiation of SCLC cells in culture results in the secretion of inflammatory cytokines that results in increased migration and phagocytosis by macrophages. In vivo, CD47 blockade potently enhances the local antitumor effects of radiation therapy in murine and human pre-clinical models of SCLC. Strikingly, CD47 blockade also stimulates abscopal antitumor effects inhibiting the growth of non-irradiated SCLC tumors in mice receiving radiation. Similar abscopal antitumor effects were observed in colon cancer and lymphoma models. Surprisingly, these abscopal effects are completely independent of T cells but require macrophages that migrate into the non-irradiated tumor sites in response to inflammatory signals mediated by radiation and are locally activated by CD47 blockade to eliminate cancer cells. The systemic activation of antitumor macrophages following radiotherapy and CD47 blockade may be particularly important in cancer patients who suffer from metastatic disease.

Project description:Genome-Wide Transcription Responses to Synchrotron Microbeam Radiotherapy

Project description:Transcriptional profiling of mouse tumor-specific cytotoxic T lymphocytes (CTL) comparing activation-induced gene expression profiles induced by tumor-specific antigen (Ag) and CD3 mAb. CTLs were stimulated with either Ag or CD3 mAb for 3 and 24 h, respectively. The stimulated CTLs were compared to un-stimulated CTLs. The objective was to identify differential gene expression profiles induced by the two activation (Ag vs CD3 mAb) conditions. Two-condition experiments, un-stimulated vs stimulated CTLs. Biological replicates: 3 replicates for each comparison. Unstimulated CTLs were compared to stimulated CTLs (Ag and CD3 mAb, respectively).