Project description:Immunogenic cell death (ICD) in cancer represents a functionally unique therapeutic response that can induce tumor-targeting immune responses. ICD is characterized by the exposure and release of numerous damage-associated molecular patterns (DAMPs), which confer adjuvanticity to dying cancer cells. The spatiotemporally defined emission of DAMPs during ICD has been well described; whereas the epigenetic mechanisms that regulate ICD hallmarks have not yet been deeply elucidated. Here, we aimed to examine the involvement of miRNAs and their putative targets taking advantage from well-established in vitro models of ICD. To this end, B cell lymphoma (Mino) and breast cancer (MDA-MB-231) cell lines were exposed to two different ICD inducers: the combination of retinoic acid (RA) and interferon-alpha (IFN-a) and doxorubicin, and to non ICD inducers like gamma irradiation. Then, miRNA and mRNA profiles were studied by next generation sequencing. Co-expression analysis identified 16 miRNAs differentially modulated in cells subjected to ICD. Integrated miRNA-mRNA functional analysis revealed candidate miRNAs, mRNAs, and modulated pathways associated with Immune System Process (GO Term). In this sense, ICD induced a distinctive transcriptional signature hallmarked by regulation of antigen presentation, a crucial step for a proper immune system antitumor response activation. Interestingly, the major histocompatibility complex class I (MHC-I) pathway was upregulated whereas class II (MHC-II) was downregulated. Analysis of MHC-II associated transcripts and HLA-DR surface expression validated the inhibition of this pathway by ICD on lymphoma cells. miR-4284 and miR-212-3p were the strongest miRNAs upregulated by ICD associated with this event. It is well known that MHC-II expression on tumor cells facilitates the recruitment of CD4+ T cells. However, the interaction between tumor MHC-II and the inhibitory co-receptor LAG-3 on tumor-associated lymphocytes could provide an immunosuppressive signal that directly represses effector cytotoxic activity. In this context, MHC-II downregulation by ICD could enhance antitumor immunity. Overall, we found that the miRNA profile was significantly altered during ICD. Several miRNAs are predicted to be involved in the regulation of Class I and II MHC pathway, whose implication in ICD was demonstrated herein for the first time, which could eventually modulate tumor recognition and attack by the immune system.

Project description:Most clinically applied cancer immunotherapies rely on the ability of CD8+ cytolytic T-cells to directly recognise and kill tumor cells. These strategies are limited by the emergence of MHC-deficient tumor cells and the development of an immunosuppressive tumor microenvironment. The ability of CD4+ effector cells to contribute to anti-tumor immunity independently of CD8+ T-cells is increasingly recognised, but strategies to unleash their full potential remain to be identified. Here, we describe a mechanism through which a small number of CD4+ T-cells is sufficient to eradicate MHC-deficient tumors that escape direct CD8+ T-cell targeting. The CD4+ effector T-cells preferentially cluster at tumor invasive margins where they interact with MHC-II+CD11c+ antigen-presenting cells. We show that Th1-directed CD4+ T-cells and innate immune stimulation reprogram the tumor-associated myeloid cell network towards IFN-activated antigen-presenting and iNOS-expressing tumoricidal effector phenotypes. Together, CD4+ T-cells and tumoricidal myeloid cells orchestrate a remote inflammatory cell death process that indirectly eradicates IFN-unresponsive and MHC-deficient tumors. These results warrant to clinically exploit the ability of CD4+ T-cells and innate immune stimulators as a strategy to complement the direct cytolytic activity of CD8+ T- and NK-cells and advance cancer immunotherapies.

Project description:This is a mathematical model describing tumor-CD4+-cytokine interactions, with specific emphasis on the role that CD4+ T lymphocytes play in tumor regression.

Project description:Up to know CD4 T cell antitumor responses have been mostly studied in transplanted tumor models. However, although they are valuable tools, they are not suitable to study the long term interactions between tumors and the immune system We used gene expression profiling to characterize the fate of naive tumor antigen-specific CD4 T cells in a genetically-induced lung adenocarcinoma expressing the MHC-II restricted DBY antigen as a model tumor antigen.

Project description:This is a proposed mathematical model describing interactions between tumor cells, CD4+ T cells, cytokines, and host cells within the context of CD4+ T cells inducing tumor regression. A platform is provided to assess the effectiveness of single or combination therapy with CD4+ T cells and/or cytokines.

Project description:Expression data from mouse tumor-specific CD4+ T cells The central role of tumor-specific Th1 cells in fighting cancer is becoming increasingly appreciated. However, little is known about how these cells are generated in vivo. Here, we used flow cytometry and gene expression microarrays to characterize the primary activation and Th1 differentiation of naïve tumor-specific CD4+ T cells in a mouse model for cancer immunosurveillance. We took advantage of T cell receptor-transgenic mice where CD4+ T cells recognize a tumor-specific antigen secreted by the major histocompatibility complex (MHC) class II-negative MOPC315 myeloma. Cancer cells were injected subcutaneously and T cell activation was analyzed in draining lymph nodes and at the incipient tumor site at day +8. After activation and migration to the incipient tumor site, tumor-specific CD4+ T cells had 29 up-regulated molecules (CD2, CD5, CD11a, CD18, CD25, CD28, CD44, CD45, CD49d, CD51, CD54, CD69, CD71, CD83, CD86, CD90, CD95, CD102, CD122, CD153, CD166, CD200, CD249, CD254, CD274, CD279, Ly6C, MHC class I, and CCR7) and 5 down-regulated molecules (CD27, CD31, CD45RB, CD62L, and CD126) on the surface. The activated CD4+ T cells produced interferon , a cytokine consistent with Th1 polarization, and also interleukin 2 (IL-2), IL-3, IL-10, and tumor necrosis factor . Activation of naïve tumor-specific CD4+ T cells in draining lymph node resulted in the up-regulation of 609 genes and down-regulation of 284 genes. Bioinformatics analysis of genes differentially expressed identified functional pathways related to tumor-specific Th1 cell activation. This study may represent a useful resource to guide the development of Th1-based immunotherapy for cancer. TCR-transgenic SCID mice (n = 12-15) were injected s.c. on the flank with 10(5) MOPC315 cells suspended in 250 µl ice-cold growth factor-reduced Matrigel. At day +8, draining axillary LN were dissected out and pooled, single-cell suspensions were made and staining with mAb was carried out. Activated tumor-specific CD4+ GB113+ T cells were sorted by FACSAria (≥ 95% pure) in three independent experiments. Naïve tumor-specific CD4+ control T cells were obtained from pooled LN from naive TCR-transgenic SCID mice and treated identically in two independent experiments.

Project description:Background: Although tumor-infiltrating T cells represent a favorable prognostic marker for cancer patients, the majority of these cells are rendered with an exhausted phenotype. Hence, there is an unmet need to identify factors which can reverse this dysfunctional profile and restore their anti-tumorigenic potential. Activin-A is a pleiotropic cytokine, exerting a broad range of pro- or anti-inflammatory functions in different disease contexts, including allergic and autoimmune disorders and cancer. Given that activin-A exhibits a profound effect on CD4+ T cells in the airways and is elevated in lung cancer patients, we hypothesized that activin-A can effectively regulate anti-tumor immunity in lung cancer. Methods: To evaluate the effects of activin-A in the context of lung cancer, we utilized the OVA-expressing Lewis Lung Carcinoma mouse model as well as the B16F10 melanoma model of pulmonary metastases. The therapeutic potential of activin-A-treated lung tumor-infiltrating CD4+ T cells was evaluated in adoptive transfer experiments, using CD4-/--tumor bearing mice as recipients. In a reverse approach, we disrupted activin-A signaling on CD4+ T cells using an inducible model of CD4+ T cell-specific knockout of activin-A type I receptor. RNA-Sequencing analysis was performed to assess the transcriptional signature of these cells and the molecular mechanisms which mediate activin-A’s function. In a translational approach, we validated activin-A’s anti-tumorigenic properties using primary human tumor-infiltrating CD4+ T cells from lung cancer patients. Results: Administration of activin-A in lung tumor-bearing mice attenuated disease progression, an effect associated with heightened ratio of infiltrating effector to regulatory CD4+ T cells. Therapeutic transfer of lung tumor-infiltrating activin-A-treated CD4+ T cells, delayed tumor progression in CD4-/- recipients and enhanced T cell-mediated immunity. CD4+ T cells genetically unresponsive to activin-A, failed to elicit effective anti-tumor properties and displayed an exhausted molecular signature governed by the transcription factors Tox and Tox2. Of translational importance, treatment of activin-A on tumor-infiltrating CD4+ T cells from lung cancer patients augmented their immunostimulatory capacity towards autologous CD4+ and CD8+ T cells. Conclusions: In this study, we introduce activin-A as a novel immunomodulatory factor in the lung tumor microenvironment, which bestows exhausted CD4+ T cells with effector properties.

Project description:Dysbiosis, or changes within the microbiome, is a common feature of solid tumors, however whether this dysbiosis directly contributes to tumor development is largely unknown. We previously characterized the lung cancer microbiome and identified the Gram-negative Acidovorax temperans as enriched in tumors and associated with smoking status and TP53 mutations. To determine if A. temperans exposure could contribute to the development of lung cancer, we investigated its effect in an animal model of lung adenocarcinoma driven by mutant Kras and Tp53 alleles. This revealed A. temperans exposure accelerates tumor development and burden through infiltration of proinflammatory cells in the lungs. Neutrophils exposed to A. temperans displayed a mature, pro-tumorigenic phenotype with increased cytokine signaling, with a global shift away from IL-1β signaling. Neutrophil to monocyte and macrophage signaling promoted maturation of the latter cell types which upregulated MHC II to activate CD4+ T cells. Activated T cells were then polarized to an IL-17A+ phenotype detectable in CD4+ and γδ populations. Furthermore, T17 cells shared a common gene expression profile predictive of poor survival in human LUAD cases. These data indicate a clear role for microbiota-induced inflammation as a key mechanism in the development of lung cancer, demonstrating that dysbiosis contributes to tumor growth.

Project description:In this study, we explored the molecular basis of site-specific metastasis of breast cancer to the lungs in a clinically relevant model based on the JygMC(A) cell line. In this dataset, we include expression data from JygMC(A) primary mammary tumors (carcinoma and EMT-like areas), lung metastases, normal mammary glands and normal lung parenchyma. In total, 36 laser microdissected samples were analyzed. We built a customized NanoString nCounter® Gene Expression Codeset of 104 genes and controls that contained significant embryonic core stem cell genes and EMT-MET markers. This customized assay was performed to target gene expression profiling on the following samples: primary tumor carcinoma, primary tumor EMT, lung metastasis, normal mammary gland and normal lung parenchyma.

Project description:This is a mathematical model investigating interactions among malignant tumor cells, CD4+ T cells, anti-tumor cytokines (specifically IFN-gamma), and the immune checkpoint inhibitor CTLA-4 to assess the importance of immune checkpoints in mediating tumor regression.