Project description:Chimeric antigen receptor (CAR)-T cell therapy is effective for hematologic malignancies; however, the response of solid tumors is limited because of the immunosuppressive tumor microenvironment, antigen heterogeneity, and lack of persistence of transferred T cells. To overcome these challenges, CAR-T cells expressing interleukin-7 and chemokine (C-C motif) ligand 19 (7 × 19 CAR-T) were generated to achieve potent antitumor efficacy through the recruitment and proliferation of CAR-T cells and endogenous immune cells. To elucidate the underlying mechanism of 7 × 19 CAR-T cells against solid tumors, we analyzed the cellular composition and gene expression profiles of host immune cells following CAR-T cell infusion in a murine solid tumor model. Antihuman CD20 7 × 19 CAR-T cells were prepared using Thy 1.1 congenic mice and administered to C57BL/6N mice bearing subcutaneous MC38 tumors expressing human CD20. The tumors were harvested 4 days postinfusion to capture early immune responses before overt tumor regression. CD90.1- recipient immune cells were subjected to flow cytometry analysis, and transcriptomics changes were determined using AmpliSeq and single-cell RNA seq. An increase in recipient CD8+ T cells and macrophages was observed in the tumor of mice treated with 7 × 19 CAR-T cells, but not with conventional CAR-T. The expression of chemokines and genes associated with the inflammatory pathway was upregulated only in recipient immune cells of the 7 × 19 CAR-T-treated mice. Single-cell RNA-seq analysis revealed upregulation of pro-inflammatory genes and chemokines in the dendritic cell and monocyte/macrophage populations. These results indicate that 7 × 19 CAR-T cells initiate the early recruitment and activation of host immune cells, which contributes to their superior antitumor activity compared with conventional CAR-T cells.

Project description:Poor tumor trafficking and the immunosuppressive tumor microenvironment (TME) limit chimeric antigen receptor (CAR) T cell efficacy in solid tumors, such as neuroblastoma. We previously optimized GPC2 CARs in human neuroblastoma xenografts leading to clinical translation, however, there have not been preclinical studies using immunocompetent models. Thus, here we generated murine GPC2 CAR T cells using the D3-GPC2-targeting single-chain variable fragment being utilized clinically (NCT05650749) and tested them in neuroblastoma syngeneic allografts. Immune profiling of GPC2 CAR T cell-treated tumors revealed significant reprogramming of the TME, most notably poor intra-tumor CAR T cell persistence being associated with increased recruitment of myeloid-derived suppressor cells (MDSCs), along with MDSC-recruiting CXCL1/2 chemokines. These tumor-infiltrating MDSCs directly inhibited GPC2 CAR T cell activation and proliferation ex vivo. To both capitalize on this chemokine gradient and mitigate MDSC-tumor trafficking, we engineered GPC2 CAR T cells to express the CXCL1/2 receptor, CXCR2. CXCR2-armored GPC2 CAR T cells migrated towards CXCL1/2 gradients, enhanced anti-neuroblastoma efficacy, and reduced the level of MDSCs in the TME. Together, these findings suggest CAR T cell studies in immunocompetent models are imperative to define mechanisms of solid tumor immune escape and rationally design armoring strategies that will lead to durable clinical efficacy.

Project description:CAR-T cell therapy is effective in hematologic malignancies but not in solid tumors. In breast and lung cancer patients, CAR-T cells targeting ROR1 infiltrated tumors poorly and became dysfunctional. To test strategies for enhancing efficacy, we induced ROR1+ lung tumors in KrasLSL-G12D/+;p53fl/f mice. Murine ROR1 CAR-T cells transferred after lymphodepletion with cyclophosphamide (Cy) transiently controlled tumor growth but infiltrated tumors poorly and lost function, as observed in patients. Adding oxaliplatin (Ox) to the lymphodepletion regimen activated tumor macrophages to express T cell-recruiting chemokines, resulting in improved CAR-T cell infiltration, remodeling of the tumor microenvironment, and increased tumor sensitivity to anti-PD-L1. Combination therapy with Ox/Cy and anti-PD-L1 synergistically improved CAR-T mediated tumor control and survival, providing a strategy to improve CAR-T cell efficacy in the clinic.

Project description:CAR-T cell therapy is effective in hematologic malignancies but not in solid tumors. In breast and lung cancer patients, CAR-T cells targeting ROR1 infiltrated tumors poorly and became dysfunctional. To test strategies for enhancing efficacy, we induced ROR1+ lung tumors in KrasLSL-G12D/+;p53fl/f mice. Murine ROR1 CAR-T cells transferred after lymphodepletion with cyclophosphamide (Cy) transiently controlled tumor growth but infiltrated tumors poorly and lost function, as observed in patients. Adding oxaliplatin (Ox) to the lymphodepletion regimen activated tumor macrophages to express T cell-recruiting chemokines, resulting in improved CAR-T cell infiltration, remodeling of the tumor microenvironment, and increased tumor sensitivity to anti-PD-L1. Combination therapy with Ox/Cy and anti-PD-L1 synergistically improved CAR-T mediated tumor control and survival, providing a strategy to improve CAR-T cell efficacy in the clinic.

Project description:CAR‑T cell therapy is effective in hematologic malignancies but remains challenging in solid tumors owing to antigen heterogeneity and tumor microenvironment‑induced exhaustion. Here, gene editing of the nuclear receptor NR2F6 restores CAR‑T cell functionality, sustaining a TCF1⁺ progenitor‑exhausted T cell phenotype, enhancing metabolic fitness, and preserving cytotoxic potency under chronic antigen exposure. In immunocompetent models, Nr2f6‑deficient CAR‑T cells suppress solid tumor growth and induce robust, polyclonal host antitumor responses, as shown by protection in tumor re‑challenge experiments. Although infused CAR‑T cells disappear within 2 weeks, durable tumor control coincides with epitope spreading and secondary immune responses, likely via dendritic and other antigen‑presenting cell reactivation. Protection against antigen‑negative tumors and transferable immunity reveal a dual mode of direct cytotoxicity followed by durable immune reprogramming. This broadened host immunity may offset immune escape driven by antigen loss and tumor heterogeneity, establishing NR2F6 inhibition as a promising CAR‑T engineering strategy for durable, antigen‑agnostic solid‑tumor immunotherapy.

Project description:Vδ1T cells, a rare subset of γδT cells, hold promise for treating solid tumors. Unlike conventional T cells, they recognize tumor antigens independently of the MHC antigen-presentation pathway, making them a potential “off-the-shelf” cell therapy product. However, isolation and activation of Vδ1T cells is challenging, which has limited their clinical investigation. Here, we developed a large-scale clinical-grade manufacturing process for Vδ1T cells and validated the therapeutic potential of B7-H3-CAR-modified Vδ1T cells in treating solid tumors. Co-expression of interleukin-2 with the B7-H3-CAR led to durable anti-tumor activity of Vδ1T cells in vitro and in vivo. In multiple subcutaneous and orthotopic mouse xenograft tumor models, a single intravenous administration of the CAR-Vδ1T cells resulted in complete tumor regression. These modified cells demonstrated significant in vivo expansion and robust homing ability to tumors, akin to natural tissue-resident immune cells.Additionally, the B7-H3-CAR-Vδ1T cells exhibited a favorable safety profile. In conclusion, B7-H3-CAR-modified Vδ1T cells represent a promising strategy for treating solid tumors.

Project description:Chimeric Antigen Receptor (CAR) T-cell therapy can be effective in treating human cancer but, loss/downregulation of the antigen recognized by the CAR poses a major obstacle to tumor eradication. Here, we report an approach for vaccine boosting CAR T-cells, which triggers engagement of the endogenous immune system to stop antigen-negative tumor escape. Vaccine boosting enhanced CAR T-cell polyfunctionality, increased tumor antigen uptake by dendritic cells, and elicited priming of endogenous anti-tumor T cells (antigen spreading). This process required vaccine-induced enhancements in CAR T IFN-γ production and a metabolic shift in CAR T-cells toward oxidative phosphorylation. Antigen spreading induced by vaccine-boosted CAR-T therapy enabled control of solid tumors with substantial pre-existing heterogeneity, which was further enhanced by genetically amplifying CAR T IFN-γ expression. Thus, CAR T cell-derived IFN-γ plays a critical role in promoting endogenous anti-tumor immunity, and vaccine boosting provides a clinically-translatable strategy to drive such responses against solid tumors.

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:Immunosuppressive microenvironments, the lack of immune infiltration, and antigen heterogeneity pose challenges for chimeric antigen receptor (CAR)-T cell therapies applied to solid tumors. Previously, CAR-T cells were armored with immunostimulatory molecules, such as interleukin-12 (IL-12), to overcome this issue, but faced high toxicity. Here, we show that collagen-binding domain-fused IL-12 (CBD-IL-12) secreted from CAR-T cells to target human six transmembrane epithelial antigen of the prostate 1 (STEAP1) is retained within murine prostate tumors. This leads to high intratumoral interferon-γ levels, without hepatotoxicity and infiltration of T cells into non-target organs compared with unmodified IL-12. Both innate and adaptive immune compartments are activated and recognize diverse tumor antigens after CBD-IL-12-armored CAR-T cell treatment. Combination of CBD-IL-12-armored CAR-T cells and immune checkpoint inhibitors eradicated large tumors in an established prostate cancer mouse model. Additionally, human CBD-IL-12-armored CAR-T cells showed potent anti-tumor efficacy in an 22Rv1 xenograft while reducing circulating IL-12 levels compared with unmodified IL-12-armored CAR-T cells. CBD-fusion to potent payloads of CAR-T therapy may remove obstacles to their clinical translation towards elimination of solid tumors.

Project description:Despite its proven efficacy for hematologic malignancies, chimeric antigen receptor (CAR) T cell therapy has met with limited success in treating solid tumors. While this represents a significant clinical challenge in cancer immunotherapy, preclinical efforts to assess and improve the efficacy and safety of CAR T therapy are hindered by our limited ability to model, probe, and modulate the complexity of cancer-immune interactions in solid tumors. Here, we present a microengineered platform for in vitro reproduction, real-time imaging, and in-depth analysis of malignant human solid tumors during CAR T therapy. Using a compartmentalized device with an externally accessible interface, this system makes it possible to engineer three-dimensional organotypic constructs composed of human tumor explants that can be vascularized and perfused with blood-borne immune cells in a controlled manner. We first present a microphysiological model of adenocarcinoma tumors in the human lung infused with CAR-T cells to demonstrate its capabilities to reproduce the three essential steps of targeting solid tumors, including CAR T cell recognition of tumor-associated antigens, infiltration, and survival and effector function in the tumor microenvironment. Using flow cytometry and single-cell RNA sequencing, we probe how the phenotype of CAR T cells changes during their recruitment and persistence. Furthermore, we use the sequencing data to discover a therapeutic target that can be pharmacologically inhibited in our model to significantly increase CAR T cell trafficking and their anti-tumor effects, for which we also present specific biomarkers identified by untargeted metabolomics analysis. This work provides a potentially powerful approach for mechanistic studies and preclinical screening of adoptive cell therapies for cancer and other complex diseases.