Project description:Chimeric antigen receptor (CAR) engineering of NK cells is an active area of research with early-phase clinical studies showing an excellent safety profile with encouraging clinical responses. However, the transcriptional signatures that control the fate of CAR-NK cell after infusion and their association with tumor control remain poorly understood. Here, we performed single-cell RNA sequencing (scRNA-seq) to depict the evolution of various engineered CAR-NK cells from the ex vivo infusion products to the in vivo peak phase of tumor control and finally to the relapse phase. Single cell RNA sequencing (scRNA) has revolutionized high-thoughout systems-based analysis of cellular and functional heterogeneity, and dynamic changes in the immune response during the anti-tumor immune cell therapy . The goals of this work are to compare transcriptome profiling (RNA-seq) from both engrafted tumor cells and infused CAR-NK cells over time of treatment course to evaluate the kenetic of tumor cell response and effector functional change of CAR-NK cell. Our study represents the first detailed transcriptomic analysis of using CAR-NK cell therapy aganist Raji-engrafted mouse model. Collecting samples from different time points and organs, the data analysis reported here should privide an envision of the dynamic about how tumor response to immune cell therapy of using CAR-NK cells and also how immune effector fucntion of CAR-NK cell was modulated over time during the treatment courses.

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:A significant challenge for chimeric antigen receptor (CAR) T cell therapy against glioblastoma (GBM) is its immunosuppressive tumor microenvironment (TME), which is densely populated and supported by protumoral glioma-associated microglia and macrophages (GAMs). Targeting CD47, a don't-eat-me signal overexpressed by tumor cells, disrupts the CD47-SIRPalpha axis and induces GAM phagocytic function. However, antibody-mediated CD47 blockade monotherapy is associated with toxicity and low bioavailability in solid tumors. To overcome these limitations, we combined local CAR T cell therapy with paracrine GAM modulation to effectively eliminate GBM. To this end, we engineered a new CAR T cell against epidermal growth factor receptor variant III (EGFRvIII) that constitutively secretes a signal regulatory protein gamma (SIRPgamma)-related protein (SGRP) with high affinity to CD47. Anti-EGFRvIII-SGRP CAR T cells eliminated EGFRvIII+ GBM in a dose-dependent manner in vitro and eradicated orthotopically xenografted EGFRvIII-mosaic GBM by locoregional application in vivo. This resulted in significant tumor-free long-term survival, followed by partial tumor control upon tumor re-challenge. Combining anti-CD47 antibodies with anti-EGFRvIII CAR T cells failed to achieve a similar therapeutic effect, underscoring the importance of sustained paracrine GAM modulation. Multidimensional brain immunofluorescence microscopy and in-depth spectral flow cytometry on GBM-xenografted brains showed that anti-EGFRvIII-SGRP CAR T cells accelerated GBM clearance, increased CD68+ cell trafficking to tumor scar sites and promoted GAM-mediated tumor cell uptake. In a peripheral lymphoma mouse xenograft model, anti-CD19-SGRP CAR T cells had superior efficacy to conventional anti-CD19 CAR T cells. Validation on human GBM explants revealed that anti-EGFRvIII-SGRP CAR T cells had a similar tumor-killing capacity to anti-EGFRvIII CAR monotherapy but showed a slight improvement in the maintenance of tumor-infiltrated CD14+ cells. Thus, local anti-EGFRvIII-SGRP CAR T cell therapy combines the potent antitumor effect of engineered T cells with the modulation of the surrounding innate immune TME. This results in the additive elimination of bystander EGFRvIII- tumor cells in a manner that overcomes the main mechanisms of CAR T cell therapy resistance, including tumor innate immune suppression and antigen escape.

Project description:This study investigated the role of sympathetic denervation in enhancing CAR T cell anti-tumor efficacy in renal clear cell carcinoma. By blocking the NGF pathway with antibodies, we demonstrated reduced sympathetic nerve distribution and delayed tumor progression. Furthermore, CAR T cells engineered to secrete NGF scFv achieved tumor immunosympathectomy, leading to improved anti-tumor effects. RNA sequencing revealed that this enhancement was linked to reduced terminal exhaustion in CD8 T cells and inhibited macrophage polarization from M1 to M2, promoting a robust anti-tumor immune state. Additionally, splenic T cells exhibited a stronger immune effector phenotype following the infusion of NGF scFv-secreting CAR T cells. These findings suggest that immunosympathectomy may represent a novel strategy to mitigate tumor-induced immunosuppression and improve CAR T cell efficacy in solid tumors.

Project description:This study investigated the role of sympathetic denervation in enhancing CAR T cell anti-tumor efficacy in renal clear cell carcinoma. By blocking the NGF pathway with antibodies, we demonstrated reduced sympathetic nerve distribution and delayed tumor progression. Furthermore, CAR T cells engineered to secrete NGF scFv achieved tumor immunosympathectomy, leading to improved anti-tumor effects. RNA sequencing revealed that this enhancement was linked to reduced terminal exhaustion in CD8 T cells and inhibited macrophage polarization from M1 to M2, promoting a robust anti-tumor immune state. Additionally, splenic T cells exhibited a stronger immune effector phenotype following the infusion of NGF scFv-secreting CAR T cells. These findings suggest that immunosympathectomy may represent a novel strategy to mitigate tumor-induced immunosuppression and improve CAR T cell efficacy in solid tumors.

Project description:Primary chimeric antigen receptor (CAR) natural killer (NK) cells show strong cytotoxic efficacy against acute myeloid leukemia (AML) in vivo. However, NK cell-mediated tumor killing is often impaired by tumor-mediated immune cell inactivation. Here, we report a novel strategy to overcome NK cell inhibition caused by the immune checkpoint NKG2A, which interacts with HLA-E expressed on AML blasts. We generated AML-specific CD33-directed CAR (CAR33)-KLRC1ko-NK cells with CRISPR/Cas9-based gene editing of the NKG2A-encoding KLRC1 gene. Single-cell multi-omic analyses revealed a higher proportion of activated cells in CAR33-NK- and CAR33-KLRC1ko-NK pools, which were preserved following AML-cell contact. This activated state of the CAR33-KLRC1ko-NK cells has been translated into improved antileukemic activity in vitro and in vivo against AML cell lines and primary blasts. This dual modification of primary NK cells has the potential to bypass the suppressive effect not only of AML but also in a broad range of other cancer identities.

Project description:We previously developed human CAR macrophages (CAR-M) and demonstrated redirection of macrophage anti-tumor function leading to tumor control in immunodeficient xenograft models. Here, we developed clinically relevant fully immunocompetent syngeneic models to evaluate the potential for CAR-M to remodel the tumor microenvironment (TME), induce T cell anti-tumor immunity, and sensitize solid tumors to PD1/PDL1 checkpoint inhibition. In vivo, anti-HER2 CAR-M significantly reduced tumor burden, prolonged survival, remodeled the TME, increased intratumoral T cell and natural killer (NK) cell infiltration, and induced epitope spreading. CAR-M therapy protected against antigen-negative relapse in a T cell dependent fashion, confirming long-term anti-tumor immunity. In HER2+ solid tumors resistant to anti-PD1(aPD1) monotherapy, the combination of CAR-M and aPD1 significantly improved tumor growth control, survival, and remodeling of the TME. These results demonstrate synergy between CAR-M and T cell checkpoint blockade and provide a strategy to enhance response to aPD1 therapy for patients with non-responsive tumors.

Project description:Novel therapeutic strategies are needed to improve the efficacy of chimeric antigen receptor (CAR)-T cells in the treatment of solid tumors. Multiple tumor microenvironmental factors are thought to contribute to CAR-T cell therapy resistance in solid tumors, and appropriate model systems to identify and examine these factors using clinically relevant biospecimens are limited. Here, we examined the activity of B7-H3 (CD276) directed CAR-T (B7-H3.CAR-T) using 3D microfluidic cultures of patient-derived organotypic tumor spheroids (PDOTS) and confirmed activity of B7-H3.CAR-T in PDOTS. While B7-H3 expression in PDOTS was associated with B7-H3.CAR-T sensitivity, mechanistic studies revealed dynamic upregulation of co-inhibitory receptors on CAR-T cells following target cell encounter that led to CAR-T cell dysfunction and limited efficacy against B7-H3 expressing tumors. PD-1 blockade restored CAR-T activity in monotypic and organotypic tumor spheroids with improved tumor control and upregulation of effector cytokines. Given the emerging role of TANK-binding kinase 1 (TBK1) as an immune evasion gene, we examined the effect of TBK1 inhibition on CAR-T efficacy. Similar to PD-1 blockade, TBK1 inhibition restored CAR-T activity in monotypic and organotypic tumor spheroids, prevented CAR-T cell dysfunction, and enhanced T cell proliferation. Inhibition or deletion of TBK1 also enhanced sensitivity of cancer cells to immune-mediated killing. Taken together, our results demonstrate the feasibility and utility of ex vivo profiling of CAR-T cells using PDOTS and suggest that targeting TBK1 is a novel strategy to enhance CAR-T efficacy by overcoming tumor-intrinsic and -extrinsic resistance mechanisms.

Project description:Chimeric antigen receptor (CAR) T cell therapy has shown remarkable clinical success in the treatment of B-cell acute lymphoblastic leukemia (B-ALL), non-Hodgkin lymphoma (NHL), and multiple myeloma (MM), but its clinical efficacy in other hematologic tumors and solid tumors has been modest. Some of the major challenges that diminish the efficacy of CAR T cells against solid tumors are tumor-associated antigen heterogeneity and the immunosuppressive tumor microenvironment (TME). To overcome these problems, we developed CAR T cells overexpress with LIGHT (TNFSF14), which is a ligand of both LtβR (lymphotoxin beta receptor) on cancer cells and HVEM (herpes virus entry mediator) on immune cells. In addition to the cancer cell-directed cytotoxicity mediated by the CAR T cells themselves, the interaction of LIGHT with LTβR on tumor cells led to antigen-independent killing; moreover, LIGHT also provided immunostimulatory properties to the T cells. Hence, LIGHT-CAR T cells promoted, through multimodal and orthogonal mechanisms, an improved antitumor response through enhanced tumor killing and costimulatory potential. The antigen-independent killing of heterogeneous cancer cells was widely applicable across various cancer cell lines and was mediated by LIGHT CAR T cells in an LTβR-dependent manner. In addition, LIGHT-CAR T cells demonstrated higher proliferative capacity and proinflammatory cytokine secretion than non-LIGHT expressing CAR T cells. Furthermore, LIGHT-CAR T cells conferred significant tumor control and concomitant survival benefit as compared to non-LIGHT CAR T cells in xenograft models of solid tumors with a heterogeneous expression of the target antigen. The application of LIGHT-CAR T cell therapies may provide a novel therapeutic approach to the treatment of solid tumors in the context of antigen-heterogeneous disease thereby preventing outgrowth of antigen-negative populations leading to disease relapse.

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.