Project description:This mathematical model of the dynamics between tumor, virus and virus-specific CTL populations is described by the publication: Wodarz D. "Viruses as antitumor weapons: defining conditions for tumor remission". Cancer Res. 2001 Apr 15;61(8):3501-7. PMID: 11309314 Comment: Reproduction of Fig. 3A was achieved by using the initial conditions infected_tumor_cells = 0.01, uninfected_tumor_cells = 0.0001, virus-specific_CTLs = 0, and with modified parameter sets. For Fig. 3A non-cytotoxic virus, k = 17 and beta= 0.5. For Fig. 3A cytotoxic virus, beta = 0.5. These simulation conditions yield plots similar to Fig. 3A in the manuscript. Abstract: Recent research has indicated that viruses specifically infecting tumor cells could be used as an alternative therapeutic approach in cancer patients. A particular example is the adenovirus ONYX-015, which has entered clinical trials in the context of head and neck cancer. Successful therapy crucially requires an understanding about how viral and host parameters influence tumor load. The interactions between the growing tumor, the replicating virus, and possible immune responses are multifactorial and nonlinear. Hence, a complete understanding of how virus and host characteristics influence the outcome of therapy requires mathematical models. In this study, such mathematical models are presented and analyzed. The study investigates three possible scenarios that could be relevant for therapy: (a) viral cytotoxicity alone kills tumor cells; (b) a virus-specific lytic CTL response contributes to killing of infected tumor cells; (c) the virus elicits immunostimulatory signals within the tumor that promote the development of tumor-specific CTL. The models precisely define conditions required for successful therapy. They identify the parameters that need to be measured and modulated to evaluate and refine the existing therapy regimes.

Project description:An innovative multikinase inhibitor (H89)-based antitumor immunotherapy in colorectal cancer (CRC) is presented. The study was designed to evaluate the effect of H89 on colon tumor growth and carcinogenesis through in vivo analyses. Syngeneic mouse models of CRC cancer in BALB/c mice and chemically colon tumorigenesis, reveals that H89 delays colon oncogenesis, related to a preventive effect, and prevents tumor growth, underlying an antitumor effect respectively. Using immunodeficient and monoclonal antibody-specific immunosuppression, we identified immune cell populations involved in the preventive (NK-cell dependent) and antitumor activity of H89 (T-cell dependent). Flow cytometry analysis showed that the antitumor effect of H89 was correlated with an increase in the tumor microenvironment of CD4+ Th1 cells and CD8+ cytotoxic T cells and a decrease of CD4+ Treg cells infiltration. Furthermore, qRT-PCR revealed that H89 can promote naïve CD4+ T cells differentiation into Th1, decreases Treg differentiation and increases ex vivo CD8+ T cell-mediated killing of cancer cells. An RNAseq profiling experiment showed that H89 induces an overexpression of genes involved in antitumor immune response, such as IL-15RA, whose inhibition counteracts the antitumor effect of H89. In conclusion, our findings identify H89 as a potential strategy for the prevention and treatment of CRC.

Project description:Many human cancers are resistant to immunotherapy, for reasons that are poorly understood. We used a genome-scale CRISPR-Cas9 screen to identify mechanisms of tumor cell resistance to killing by cytotoxic T cells, the central effectors of antitumor immunity. Inactivation of >100 genes—including Pbrm1, Arid2, and Brd7, which encode components of the PBAF form of the SWI/SNF chromatin remodeling complex—sensitized mouse B16F10 melanoma cells to killing by T cells. Loss of PBAF function increased tumor cell sensitivity to interferon-γ, resulting in enhanced secretion of chemokines that recruit effector T cells. Treatment-resistant tumors became responsive to immunotherapy when Pbrm1 was inactivated. In many human cancers, expression of PBRM1 and ARID2 inversely correlated with expression of T cell cytotoxicity genes, and Pbrm1-deficient murine melanomas were more strongly infiltrated by cytotoxic T cells.

Project description:Immunotherapies with CAR-T cells achieve remarkable success, especially against B-cell malignancies. However, their activity against non-hematopoietic solid tumors is very limited. One central cause of this failure may be that a pro-oxidative tumor microenvironment can downmodulate the activation and migration of T-cells. In contrast to tumor cells, primary T cells have very low levels of antioxidants. This makes them prone to pro-oxidative effects. Oxidation-induced dysregulation of actin cytoskeletal dynamics hinders T-cell migration which allows only low tumor infiltration rates. In addition, the proliferation and the effector functions of T-cells (tumor cell killing) are disrupted. In order to strengthen human CAR-T cells against a pro-oxidative tumor microenvironment, we have increased increase their antioxidant capacity, e.g. by expressing antioxidants. We aimed to characterize the importance of antioxidant empowerment at functional level and at the molecular level. Among the antioxidant systems, thioredoxin1 (TRX1)-empowerment, allowed CAR T cells to retain their capacities for cytolytic immune synapse formation, cytokine release, proliferation, and cytotoxicity under pro-oxidative conditions. At the molecular level, gene expression analysis revealed that a pro-oxidative micromilieu caused a downmodulation of costimulatory and cytokine signals of T cells. One unique focus of this study was also to investigate global influence of reactive oxygen species on protein oxidation in T cells. Therefore, using TRX1 kinetic trapping and consequently mass spectrometry was employed to get insight into global oxidation levels in T cells. This analysis, namely redoxosome analysis, unveiled 196 oxidized proteins which were annotated to regulate several antitumor T cell functions. Taken together, our results provide evidence that TRX1 empowerment can increase CAR T cell efficacy against solid tumors.

Project description:T helper cells integrate signals from their microenvironment to acquire distinct specialization programs for efficient clearance of diverse pathogens or for immunotolerance. Ionic signals have recently been demonstrated to affect T cell polarization and function. Sodium chloride (NaCl) was proposed to accumulate in peripheral tissues upon dietary intake and to promote autoimmunity via the Th17 cell axis. Here we demonstrate that high NaCl conditions induced a stable, pathogen-specific, anti-inflammatory Th17 cell fate in human T cells in vitro. The p38/MAPK pathway, involving NFAT5 and SGK1, regulated FoxP3 and interleukin (IL)-17-expression in high-NaCl conditions. The NaCl-induced acquisition of an anti-inflammatory Th17 cell fate was confirmed in vivo in an experimental autoimmune encephalomyelitis (EAE) mouse model, which demonstrated strongly reduced disease symptoms upon transfer of T cells polarized in high NaCl conditions. However, NaCl was coopted to promote murine and human Th17 cell pathogenicity, if T cell stimulation occurred in a pro-inflammatory and TGF--low cytokine microenvironment. Taken together, our findings reveal a context-dependent, dichotomous role for NaCl in shaping Th17 cell pathogenicity. NaCl might therefore prove beneficial for the treatment of chronic inflammatory diseases in combination with cytokine-blocking drugs.

Project description:The paper describes a model of antitumor vaccine therapy. Created by COPASI 4.25 (Build 207) This model is described in the article: A Mathematical Model of the Enhancement of Tumor Vaccine Efficacy by Immunotherapy Shelby Wilson and Doron Levy Bull Math Biol. 2012 July ; 74(7) Abstract: TGF-β is an immunoregulatory protein that contributes to inadequate antitumor immune responses in cancer patients. Recent experimental data suggests that TGF-β inhibition alone, provides few clinical benefits, yet it can significantly amplify the anti-tumor immune response when combined with a tumor vaccine. We develop a mathematical model in order to gain insight into the cooperative interaction between anti-TGF-β and vaccine treatments. The mathematical model follows the dynamics of the tumor size, TGF-β concentration, activated cytotoxic effector cells, and regulatory T cells. Using numerical simulations and stability analysis, we study the following scenarios: a control case of no treatment, anti-TGF-β treatment, vaccine treatment, and combined anti-TGF-β vaccine treatments. We show that our model is capable of capturing the observed experimental results, and hence can be potentially used in designing future experiments involving this approach to immunotherapy. To cite BioModels Database, please use: BioModels Database: An enhanced, curated and annotated resource for published quantitative kinetic models . To the extent possible under law, all copyright and related or neighbouring rights to this encoded model have been dedicated to the public domain worldwide. Please refer to CC0 Public Domain Dedication for more information.

Project description:Sodium chloride in the tumor microenvironment enhances T cell metabolic fitness and tumor killing

Project description:Respiratory viral infections reprogram pulmonary macrophages with altered anti-infectious functions. However, the potential function of virus-trained macrophages in antitumor immunity in the lung, a preferential target of both primary and metastatic malignancies, is not well understood. Using mouse models of influenza and lung metastatic tumors, we show here that influenza trains respiratory mucosal-resident alveolar macrophages (AMs) to exert long-lasting and tissue-specific antitumor immunity. Trained AMs infiltrate tumor lesions and have enhanced phagocytic and tumor cell cytotoxic functions, which are associated with epigenetic, transcriptional and metabolic resistance to tumor-induced immune suppression. Generation of antitumor trained immunity in AMs is dependent on interferon-γ and natural killer cells. Notably, human AMs with trained immunity traits in non-small cell lung cancer tissue are associated with a favorable immune microenvironment. These data reveal a function for trained resident macrophages in pulmonary mucosal antitumor immune surveillance. Induction of trained immunity in tissue-resident macrophages might thereby be a potential antitumor strategy.

Project description:Respiratory viral infections reprogram pulmonary macrophages with altered anti-infectious functions. However, the potential function of virus-trained macrophages in antitumor immunity in the lung, a preferential target of both primary and metastatic malignancies, is not well understood. Using mouse models of influenza and lung metastatic tumors, we show here that influenza trains respiratory mucosal-resident alveolar macrophages (AMs) to exert long-lasting and tissue-specific antitumor immunity. Trained AMs infiltrate tumor lesions and have enhanced phagocytic and tumor cell cytotoxic functions, which are associated with epigenetic, transcriptional and metabolic resistance to tumor-induced immune suppression. Generation of antitumor trained immunity in AMs is dependent on interferon-γ and natural killer cells. Notably, human AMs with trained immunity traits in non-small cell lung cancer tissue are associated with a favorable immune microenvironment. These data reveal a function for trained resident macrophages in pulmonary mucosal antitumor immune surveillance. Induction of trained immunity in tissue-resident macrophages might thereby be a potential antitumor strategy.

Project description:Cancer immunotherapies boost antitumor immunity and improve the survival of cancer patients. V-domain Immunoglobulin Suppressor of T cell Activation (VISTA) is an immune 20 checkpoint target but presents elusive signaling mechanisms. We report a novel VISTA binding partner, Leucine-Rich Repeats and Immunoglobulin Like Domains 1 (LRIG1), which acts as an inhibitory receptor by engaging VISTA and suppressing T cell receptor signaling pathways. Mice with T cell-specific LRIG1 deletion developed superior antitumor T cell responses. Mechanistically, LRIG1-deficient tumor-specific CD8+ cytotoxic T cells (CTLs) exhibited longer 25 persistence due to improved expansion and survival and greater effector function. Sustained tumor control was also associated with a reduction of quiescent CTLs (TCF1+ CD62Lhi PD-1low) and a reciprocal increase in progenitor and memory-like CTLs (TCF1+ PD-1+). In human melanoma, an elevated LRIG1 expression on tumor-infiltrating CD8+ CTLs correlated with resistance to immunotherapies. Taken together, these results delineate the role of LRIG1 as an inhibitory 30 immune checkpoint receptor and propose a rationale for targeting the VISTA/LRIG1 axis for cancer immunotherapy.