Project description:Chimeric antigen receptor (CAR) T cell therapy has achieved remarkable success in hematological malignancies but remains largely ineffective in solid tumors. A major factor leading to the reduced efficacy of CAR T cell therapy is T cell dysfunction, and the mechanisms mediating this dysfunction are under investigation. Here we establish a robust in vitro model to study mesothelin-redirected CAR T cell dysfunction in pancreatic cancer. Continuous antigen exposure results in hallmark features of exhaustion including reduced proliferation capacity and cytotoxicity, and severe defects in cytokine production. Here we identified a transcriptional signature at both population and single-cell levels in CAR T cells after chronic antigen exposure. In addition, TCR lineage tracing revealed a CD8+ T-to-NK-like T cell plasticity that results in reduced antigen- dependent tumor cell killing. The transcription factors SOX4 and ID3 are specifically expressed in the dysfunctional CAR NK-like T cells and are predicted to be master regulators of the dysfunction gene expression signature and of the post-thymic acquisition of an NK-like T cell fate. Finally, we identified the emergence of CAR NK-like T cells in a subset of patients after infusion of CAR T cells. The findings gleaned from this study reveal new approaches to improve the efficacy of CAR T cell therapy in solid tumors by preventing or revitalizing CAR T cell dysfunction and shed light on the plasticity of human CAR T cells.

Project description:Chimeric antigen receptor (CAR) T cell therapy has achieved remarkable success in hematological malignancies but remains largely ineffective in solid tumors. A major factor leading to the reduced efficacy of CAR T cell therapy is T cell dysfunction, and the mechanisms mediating this dysfunction are under investigation. Here we establish a robust in vitro model to study mesothelin-redirected CAR T cell dysfunction in pancreatic cancer. Continuous antigen exposure results in hallmark features of exhaustion including reduced proliferation capacity and cytotoxicity, and severe defects in cytokine production. Here we identified a transcriptional signature at both population and single-cell levels in CAR T cells after chronic antigen exposure. In addition, TCR lineage tracing revealed a CD8+ T-to-NK-like T cell plasticity that results in reduced antigen- dependent tumor cell killing. The transcription factors SOX4 and ID3 are specifically expressed in the dysfunctional CAR NK-like T cells and are predicted to be master regulators of the dysfunction gene expression signature and of the post-thymic acquisition of an NK-like T cell fate. Finally, we identified the emergence of CAR NK-like T cells in a subset of patients after infusion of CAR T cells. The findings gleaned from this study reveal new approaches to improve the efficacy of CAR T cell therapy in solid tumors by preventing or revitalizing CAR T cell dysfunction and shed light on the plasticity of human CAR T cells.

Project description:Chimeric antigen receptor (CAR) T cell therapy has achieved remarkable success in hematological malignancies but remains largely ineffective in solid tumors. A major factor leading to the reduced efficacy of CAR T cell therapy is T cell dysfunction, and the mechanisms mediating this dysfunction are under investigation. Here we establish a robust in vitro model to study mesothelin-redirected CAR T cell dysfunction in pancreatic cancer. Continuous antigen exposure results in hallmark features of exhaustion including reduced proliferation capacity and cytotoxicity, and severe defects in cytokine production. Here we identified a transcriptional signature at both population and single-cell levels in CAR T cells after chronic antigen exposure. In addition, TCR lineage tracing revealed a CD8+ T-to-NK-like T cell plasticity that results in reduced antigen- dependent tumor cell killing. The transcription factors SOX4 and ID3 are specifically expressed in the dysfunctional CAR NK-like T cells and are predicted to be master regulators of the dysfunction gene expression signature and of the post-thymic acquisition of an NK-like T cell fate. Finally, we identified the emergence of CAR NK-like T cells in a subset of patients after infusion of CAR T cells. The findings gleaned from this study reveal new approaches to improve the efficacy of CAR T cell therapy in solid tumors by preventing or revitalizing CAR T cell dysfunction and shed light on the plasticity of human CAR T cells.

Project description:Chimeric antigen receptor (CAR) T cell therapy has achieved remarkable success in hematological malignancies but remains largely ineffective in solid tumors. A major factor leading to the reduced efficacy of CAR T cell therapy is T cell dysfunction, and the mechanisms mediating this dysfunction are under investigation. Here we establish a robust in vitro model to study mesothelin-redirected CAR T cell dysfunction in pancreatic cancer. Continuous antigen exposure results in hallmark features of exhaustion including reduced proliferation capacity and cytotoxicity, and severe defects in cytokine production. Here we identified a transcriptional signature at both population and single-cell levels in CAR T cells after chronic antigen exposure. In addition, TCR lineage tracing revealed a CD8+ T-to-NK-like T cell plasticity that results in reduced antigen- dependent tumor cell killing. The transcription factors SOX4 and ID3 are specifically expressed in the dysfunctional CAR NK-like T cells and are predicted to be master regulators of the dysfunction gene expression signature and of the post-thymic acquisition of an NK-like T cell fate. Finally, we identified the emergence of CAR NK-like T cells in a subset of patients after infusion of CAR T cells. The findings gleaned from this study reveal new approaches to improve the efficacy of CAR T cell therapy in solid tumors by preventing or revitalizing CAR T cell dysfunction and shed light on the plasticity of human CAR T cells.

Project description:Chimeric antigen receptor (CAR) T-cell therapy has achieved remarkable success in the treatment of hematopoietic cancers, but resistance is common, and efficacy is limited in solid tumors. We demonstrate that CAR T-cells autonomously propagate epigenetically-programmed type I interferon signaling through chronic stimulation or antigen-independent tonic activation, which progressively hampers antitumor effector function. EGR2 transcriptional regulator knockoutnot only blocks this type I interferon-mediated inhibitory program, but also independently expands early memory CAR T-cells with improved efficacy against liquid and solid tumors. The protective effect of EGR2 deletion in CAR T-cells against chronic antigen-induced dysfunction can be overridden by interferon-β exposure, suggesting that EGR2 ablation suppresses CAR T-cell dysfunction through inhibition of type I interferon signaling. Finally, enrichment of an EGR2 gene signature is a clinical biomarker for type I interferon-associated CAR T-cell failure and shorter overall patient survival. These findings conceptually connect prolonged CAR T-cell activation with deleterious immunoinflammatory signaling and point to an EGR2-type I interferon axis as a therapeutically amenable biologic system.

Project description:Chimeric antigen receptor (CAR) T-cell therapy has achieved remarkable success in the treatment of hematopoietic cancers, but resistance is common, and efficacy is limited in solid tumors. We demonstrate that CAR T-cells autonomously propagate epigenetically-programmed type I interferon signaling through chronic stimulation or antigen-independent tonic activation, which progressively hampers antitumor effector function. EGR2 transcriptional regulator knockoutnot only blocks this type I interferon-mediated inhibitory program, but also independently expands early memory CAR T-cells with improved efficacy against liquid and solid tumors. The protective effect of EGR2 deletion in CAR T-cells against chronic antigen-induced dysfunction can be overridden by interferon-β exposure, suggesting that EGR2 ablation suppresses CAR T-cell dysfunction through inhibition of type I interferon signaling. Finally, enrichment of an EGR2 gene signature is a clinical biomarker for type I interferon-associated CAR T-cell failure and shorter overall patient survival. These findings conceptually connect prolonged CAR T-cell activation with deleterious immunoinflammatory signaling and point to an EGR2-type I interferon axis as a therapeutically amenable biologic system.

Project description:This model of the use of chimeric antigen receptor (CAR)-T cell therapy in the treatment of solid tumours is described in the article: "Dual-Target CAR-Ts with On- and Off-Tumour Activity May Override Immune Suppression in Solid Cancers: A Mathematical Proof of Concept" Odelaisy León-Triana, Antonio Pérez-Martínez, Manuel Ramírez-Orellana and Víctor M. Pérez-García Cancers 2021, 13, 703.; doi: 10.3390/cancers13040703 Comment: This is the first mathematical model, derived from equations 1 and 2, used in the paper. Reproduction of Fig. 5a was achieved by setting alpha_1 = 0.04, different to the value quoted in the article caption for Fig. 5. Abstract: Chimeric antigen receptor (CAR)-T cell-based therapies have achieved substantial success against B-cell malignancies, which has led to a growing scientific and clinical interest in extending their use to solid cancers. However, results for solid tumours have been limited up to now, in part due to the immunosuppressive tumour microenvironment, which is able to inactivate CAR-T cell clones. In this paper we put forward a mathematical model describing the competition of CAR-T and tumour cells, taking into account their immunosuppressive capacity. Using the mathematical model, we show that the use of large numbers of CAR-T cells targetting the solid tumour antigens could overcome the immunosuppressive potential of cancer. To achieve such high levels of CAR-T cells we propose, and study computationally, the manufacture and injection of CAR-T cells targetting two antigens: CD19 and a tumour-associated antigen. We study in silico the resulting dynamics of the disease after the injection of this product and find that the expansion of the CAR-T cell population in the blood and lymphopoietic organs could lead to the massive production of an army of CAR-T cells targetting the solid tumour, and potentially overcoming its immune suppression capabilities. This strategy could benefit from the combination with PD-1 inhibitors and low tumour loads. Our computational results provide theoretical support for the treatment of different types of solid tumours using T cells engineered with combination treatments of dual CARs with on- and off-tumour activity and anti-PD-1 drugs after completion of classical cytoreductive treatments.

Project description:This model of the use of chimeric antigen receptor (CAR)-T cell therapy in the treatment of solid tumours is described in the article: "Dual-Target CAR-Ts with On- and Off-Tumour Activity May Override Immune Suppression in Solid Cancers: A Mathematical Proof of Concept" Odelaisy León-Triana, Antonio Pérez-Martínez, Manuel Ramírez-Orellana and Víctor M. Pérez-García Cancers 2021, 13, 703.; doi: 10.3390/cancers13040703 Comment: This is the second mathematical model, derived from equations 3 to 6, used in the paper. Reproduction of Figure 5b was achieved by setting alpha_1 = 0.183, in substitution for alpha_1 = 0.2 as quoted in the article. Abstract: Chimeric antigen receptor (CAR)-T cell-based therapies have achieved substantial success against B-cell malignancies, which has led to a growing scientific and clinical interest in extending their use to solid cancers. However, results for solid tumours have been limited up to now, in part due to the immunosuppressive tumour microenvironment, which is able to inactivate CAR-T cell clones. In this paper we put forward a mathematical model describing the competition of CAR-T and tumour cells, taking into account their immunosuppressive capacity. Using the mathematical model, we show that the use of large numbers of CAR-T cells targetting the solid tumour antigens could overcome the immunosuppressive potential of cancer. To achieve such high levels of CAR-T cells we propose, and study computationally, the manufacture and injection of CAR-T cells targetting two antigens: CD19 and a tumour-associated antigen. We study in silico the resulting dynamics of the disease after the injection of this product and find that the expansion of the CAR-T cell population in the blood and lymphopoietic organs could lead to the massive production of an army of CAR-T cells targetting the solid tumour, and potentially overcoming its immune suppression capabilities. This strategy could benefit from the combination with PD-1 inhibitors and low tumour loads. Our computational results provide theoretical support for the treatment of different types of solid tumours using T cells engineered with combination treatments of dual CARs with on- and off-tumour activity and anti-PD-1 drugs after completion of classical cytoreductive treatments.

Project description:Chronic stimulation with Acute Myeloid Leukemia can induce dysfunction in NK and CAR-NK cells. We evaluated transcriptomic differences on the day 10 of chronic antigen stimulation in NK cells secreting IL15 compared to non-secreting NK cells

Project description:Chimeric antigen receptor (CAR) T cell therapy has proven highly successful in the treatment of hematological malignancies, notably acute lymphoblastic leukemia and B cell lymphoma. However, the efficacy of CAR T cells against solid tumors is poor, likely due to tumor-associated immunosuppression. Here, we demonstrate that antagonizing Inhibitor of Apoptosis Proteins (IAPs) with the clinical smac-mimetic, birinapant, significantly enhanced the anti-tumor activity of CAR T cells in a TNF-dependent manner. Enhanced tumor cell death occurred independently of the perforin-mediated granule exocytosis pathway, underscoring the cytotoxic potential of CAR T cell-derived TNF. Importantly, combining CAR T cell therapy with birinapant dramatically reduced established tumor growth in vivo, where either therapy alone was relatively ineffective. Using patient biopsy-derived tumoroids, we demonstrate the synergistic potential of combining CAR T cell therapy with smac-mimetics. Taken together, we identify CAR T cell-derived TNF as a potent anti-tumor effector, which can be further harnessed by smac-mimetics.