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:Radiotherapy can act as in situ vaccine activating preventive tumor-specific immune responses in treated patients. While carbon ion radiotherapy holds superior biophysical properties over conventional photon irradiation, little is known about the immunological effects induced by this radiation type. Multiple strategies combining radiotherapy with immune checkpoint inhibition (radioimmunotherapy) to enhance anti-tumor immunity have been described, however, results on the immune cell composition in tumors following radioimmunotherapy with carbon ions are lacking. Here, we present a bilateral tumor model based on time-shifted transplantation of murine, Her2+ EO771 tumor cells onto the flanks of immune competent mice followed by selective irradiation of the primal tumor. αCTLA4- but not αPD-L1-based radioimmunotherapy induced complete tumor rejection and mediated eradication of even non-irradiated, distant tumors. Cured mice were protected against EO771 rechallenge indicative of long lasting, tumor-specific immunological memory. Single cell RNA-sequencing and flow cytometric analyses of irradiated tumors revealed activation of NK cells and distinct tumor-associated macrophage clusters with upregulated expression of TNF and IL1 responsive genes. Distant tumors of irradiated mice showed higher frequencies of naïve T cells, which were activated upon combination with CTLA4 blockade. Thus, radioimmunotherapy with carbon ions plus CTLA4 inhibition reshapes the tumor-infiltrating immune cell composition and can induce complete rejection even of non-irradiated tumors. Our data suggest to combine radiotherapy approaches with CTLA4 blockade to achieve durable anti-tumor immunity. Furthermore, evaluation of future radioimmunotherapy approaches should not be restricted to immunological impacts at the irradiation site, but should also consider systemic immunological effects on non-irradiated tumors.

Project description:Natural killer (NK) cells contribute to immunosurveillance and first-line defense in the control of tumor growth and metastasis diffusion. NKEVs are constitutively secreted, are biologically active, reflect the protein and genetic repertoire of their originating cells and exert anti-tumor activity in vitro and in vivo. NKEVs from tumor-conditioned NK cells interact with naïve NK cells promoting their cytotoxic activity. In cancer NK cells exhibit profound defects in degranulation ability, a status probably reflected by their NKEVs. Hence, NKEVs could contribute to improve cancer therapy by interacting with tumor and/or immune cells at the same time sensing the actual NK cell status in cancer patients. Here we investigated the role of NKEVs in stimulating the immune system and developed an immune enzymatic test (NKExoELISA) to sense the systemic NK cell status by measuring plasma NK-derived exosomes through combined capture of exosomes, expressing typical EV (tsg101) and NK cell (CD56) markers. We analyzed by LC-MS/MS the protein content from NKEVs evaluating proteins differentially expressed in exosomes (NKExo), vescicles (NKMV) and total cell extract (Tot extr) from parental NK cells. Proteomic data confirmed the presence of many EV markers and detected several proteins involved in immune response, cell adhesion and complement biological processes.

Project description:Cryoablation of primary breast cancer tumors induces a systemic abscopal effect altering TIME (Tumor-Immune Micro-Environment) in distant tumors.

Project description:Systemic inflammation caused by surgery may aggravate immunosuppression in immunocompromised cancer patients. The natural killer (NK) cell is a critical part of anti-tumor immunity. ketamine, a N-methyl-D-asparate receptor antangonist, has anti-inflammatory activity and opioid-sparing effect. This study investigate the effect of intraopertaive ketamine administration on immune function in patients undergoing laparoscopic colorectal cancer resection.

Project description:Immunotherapy approaches for glioblastoma multiforme have been thus far largely unsuccessful, suggesting unappreciated complexity in glioma biology and immunology. The intra-tumoral heterogeneity of these intrinsic brain tumors results in therapies killing only a subset of the tumor cells; therefore, therapeutic success will require achieving and optimizing an “abscopal effect” where tumor cells not specifically targeted are recognized and attacked as bystanders by the immune system. We have modified an immune-competent, genetically-driven mouse glioma model where a portion of the tumor burden is treated and another untreated portion is used as a readout of therapeutic efficacy. We find that following radiation of one lesion, anti-PD-L1 therapy enhances the abscopal response (macrophages and T-cells) to the un-irradiated lesion. In gliomas with few baseline T-cells, the anti-PD-L1-enhanced abscopal response occurs as an anti-PD-L1-driven, macrophage-mediated, and ERK-dependent increase in phagocytosis of tumor cells. Our results indicate that combined radiation and anti-PD-L1 therapy for gliomas results in peripherally-derived macrophages being responders in tumors with few baseline T-cells in the microenvironment.

Project description:Tumor-infiltrating (TI)-NK cell numbers predict better than TIL score the efficacy of HER2-targeted antibodies in primary breast cancer patients. To understand the mechanism/s underlying this association, biological processes enriched in NK cell-infiltrated as compared to NK cell-desert HER2-positive breast tumors paired by TIL score were leveraged from transcriptomic data. NK cell-infiltrated tumors were enriched in transcripts regulated by interferons and NF-kB. Among them, levels of CCL5/IFNG-CXCL9/10 positively correlated with the number of TI-NK cells in the original biopsy. Indeed, coordinated expression of CCL5/IFNG-CXCL9/10 transcripts was also evidenced in tumor biopsies from a phase II clinical trial where IFNG levels associated to the achievement of pathological complete response to anti-HER2 antibody treatment (OR 96.3, p=0.01) and correlated with their TI-NK cell score. In in vitro models, anti-HER2 antibody-dependent NK cell activation led to the secretion of CCL5/IFN-? and the subsequent production of IFN-?-dependent CXCL9/10 by bystander breast cancer cells. Ex vivo treatment of breast tumor-derived multicellular cultures with trastuzumab induced the activation of CD16+ TI-NK cells and their conversion into a CD16-CD103+ subpopulation, both endowed with CCL5 and IFN-? producing potential. CD16+ and CD16-CD103+ TI-NK cell subpopulations shared the expression of EOMES, TBX21 and several KIR genes, indicating their lineage relationship; and their proportions positively correlated with total NK cell, CD8+ and tissue-resident T cell frequencies, immune cell subsets with anti-tumor potential. Remarkably, the coordinated induction of CCL5/IFNG-CXCL9/CXCL10 expression, concomitant to the conversion of CD16+ into CD16+/-CD103+ tumor-infiltrating NK cells, was recapitulated in a humanized HER2+ breast cancer in vivo model treated with a combination of anti-HER2 antibodies and in vitro expanded human NK cells, paralleling tumor growth control. Finally, patients achieving good clinical responses to anti-HER2 antibody-based neoadjuvant treatment showed an early and coordinated increase in sera CCL5 and CXCL9/CXCL10 levels which positively correlated with TI-NK cell numbers in the corresponding diagnosis biopsy. Overall, our data point to NK cells as regulators of the tumor microenvironment through the early secretion of CCL5/IFN-? resulting in the production of CXCL9/10 and the recruitment/differentiation of immune infiltrates with anti-tumor potential, ultimately contributing to anti-HER2 antibody clinical efficacy.

Project description:Tumor-infiltrating (TI)-NK cell numbers predict better than TIL score the efficacy of HER2-targeted antibodies in primary breast cancer patients. To understand the mechanism/s underlying this association, biological processes enriched in NK cell-infiltrated as compared to NK cell-desert HER2-positive breast tumors paired by TIL score were leveraged from transcriptomic data. NK cell-infiltrated tumors were enriched in transcripts regulated by interferons and NF-kB. Among them, levels of CCL5/IFNG-CXCL9/10 positively correlated with the number of TI-NK cells in the original biopsy. Indeed, coordinated expression of CCL5/IFNG-CXCL9/10 transcripts was also evidenced in tumor biopsies from a phase II clinical trial where IFNG levels associated to the achievement of pathological complete response to anti-HER2 antibody treatment (OR 96.3, p=0.01) and correlated with their TI-NK cell score. In in vitro models, anti-HER2 antibody-dependent NK cell activation led to the secretion of CCL5/IFN-ɣ and the subsequent production of IFN-ɣ-dependent CXCL9/10 by bystander breast cancer cells. Ex vivo treatment of breast tumor-derived multicellular cultures with trastuzumab induced the activation of CD16+ TI-NK cells and their conversion into a CD16-CD103+ subpopulation, both endowed with CCL5 and IFN-ɣ producing potential. CD16+ and CD16-CD103+ TI-NK cell subpopulations shared the expression of EOMES, TBX21 and several KIR genes, indicating their lineage relationship; and their proportions positively correlated with total NK cell, CD8+ and tissue-resident T cell frequencies, immune cell subsets with anti-tumor potential. Remarkably, the coordinated induction of CCL5/IFNG-CXCL9/CXCL10 expression, concomitant to the conversion of CD16+ into CD16+/-CD103+ tumor-infiltrating NK cells, was recapitulated in a humanized HER2+ breast cancer in vivo model treated with a combination of anti-HER2 antibodies and in vitro expanded human NK cells, paralleling tumor growth control. Finally, patients achieving good clinical responses to anti-HER2 antibody-based neoadjuvant treatment showed an early and coordinated increase in sera CCL5 and CXCL9/CXCL10 levels which positively correlated with TI-NK cell numbers in the corresponding diagnosis biopsy. Overall, our data point to NK cells as regulators of the tumor microenvironment through the early secretion of CCL5/IFN-ɣ resulting in the production of CXCL9/10 and the recruitment/differentiation of immune infiltrates with anti-tumor potential, ultimately contributing to anti-HER2 antibody clinical efficacy.

Project description:Immune checkpoint inhibitors and cytokines have revolutionized tumor treatment but are still limited by dose-dependent toxicity and efficacy. In situ vaccine platforms based on intelligent microbes are promising therapeutic strategies, which can sustainably deliver drugs locally without causing severe systemic risks. Here, we have innovatively engineered a nonpathogenic, adjuvant-acting Mycobacterium smegmatis (M. smegmatis) that coexpresses a PD-L1 inhibitor and an IL-15 cytokine complex containing the IL-15Rα sushi domain (Ms-PDL1scfv-IL15). We demonstrate that PD-L1 inhibitor and IL-15 secretion systemically binds mouse or human PD-L1 and maintains IL-15 stimulatory activity. The bifunctional Ms-PDL1scfv-IL15 overcomes resistance to PD-L1 blockade, recruits numerous immune cells in situ, induces dendritic cells (DCs) maturation, initiates the M1 anti-tumor polarization of macrophages, increases the proliferation and activation of NK cells and tumor-infiltrating CD8+ T cells, inhibits the Tregs, elicits abscopal effects, stimulates rapid tumor regression, prevents metastasis, and leads to long-term survival in several syngeneic tumor mouse models. We also found that the combination of Ms-PDL1scfv-IL15 with GM–CSF synergistically stunted the tumor progress and stasis. Moreover, intratumoral administration of Ms-PDL1scfv-IL15 can capture tumor antigen fragments, and boost DCs presentation of antigens, which remarkably initiates tumor antigen-specific immune response, leading to durable tumor regression and specific antitumor immunity. In summary, this engineered M. smegmatis to recruit and activate innate and adaptive antitumor immune responses, offering a potent cancer immunotherapy strategy to treat patients with cold tumors or resistance to checkpoint blockade.

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.