Project description:Chimeric antigen receptors (CARs) are synthetic receptors for antigen that reprogram T cell specificity, function and persistence. Patient-derived CAR T cells have demonstrated remarkable efficacy against a range of B-cell malignancies, and early trial results suggest activity in multiple myeloma. Despite high complete response rates, relapses occur in a large fraction of patients, some of which are antigen-negative and others antigen-low. Unlike mechanisms resulting in complete and permanent antigen loss, those leading to antigen-low tumour escape remain obscure. In murine leukaemia models, we show that CARs provoke reversible antigen loss through trogocytosis, an active process whereby target antigen is transferred to T cells, thereby decreasing target density on tumour cells and abating T cell activity by promoting fratricide killing and exhaustion. These mechanisms affect both CD28 and 4-1BB-based CARs, albeit differentially, depending on antigen density. They can be offset by cooperative killing and combinatorial targeting.

Project description:In this data set we include expression data from human CD4+ T cells isolated on day 0, 6, 11 and 24 follow anti-CD3/anti-CD28 magnetic bead stimulation and chimeric antigen receptor transduction. 30 samples were submitted. Samples represented three biological replicates of normal donors transduced with various CARs. CARs used were a cMet 28z specific CAR comprised of the IgG4 hinge, CD28 transmembrane and CD28 and CD3zeta intracellular domains. A CD19 CD28 CAR was specific to CD19, and was comprised of a CD8a hinge, CD28 transmembrane and CD28 and CD3zeta intracellular domain. A third CAR, the CD19 BBz, was used that was specific to CD19 was comprised of a CD8a hinge, CD8a transmembrane and 4-1BB and CD3zeta intracellular domains. Expression data was analyzied on day 0, 6, 11 and 24.

Project description:Adoptive transfer of chimeric antigen receptor (CAR)-T cells is expected to become the first line of treatment for multiple malignancies, following the enormous success of anti-CD19 therapies. However, their mechanism of action is not fully understood, and clear guidelines for the design of safe and efficient receptors are missing. We hereby describe a systematic analysis of the CAR “interactome” in human primary T cells, which allowed us to identify molecular traits that influence CAR-T cell efficacy. Interactome analysis was based on immunoprecipitation of CARs followed by protein identification by mass spectrometry.

Project description:Chimeric antigen receptors (CARs) are synthetic proteins that redirect T cell specificity by linking an extracellular ligand binding domain to intracellular T cell signaling domains. CAR-expressing T (CAR-T) cells have demonstrated significant efficacy for the treatment of refractory B cell malignancies and are being evaluated as immunotherapeutic reagents for many other cancers. CAR designs are based on the fundamental principles of TCR recognition and most CARs employ the T cell-activating CD3z endodomain alongside a costimulatory domain from CD28 or 4-1BB. However, emerging data suggest that CD28/CD3z and 4-1BB/CD3z signaling modules promote divergent metabolic pathways, gene expression programs, and cell fates. To determine how CAR phosphoprotein signaling drives these disparate cell fates, we analyzed CAR ligation-induced signaling networks in primary human T cells using shotgun mass spectrometry. We isolated CD8+CD62L+ T cells from healthy donors and introduced a CD28/CD3z or 4-1BB/CD3z CAR by lentiviral transduction. Transduced T cells were purified by FACS and expanded once in vitro. When the cells returned to a resting state, CD28/CD3z or 4-1BB/CD3z CAR-T cells were stimulated for 10 or 45 minutes with magnetic microbeads coated with a monoclonal antibody specific for a 9 amino acid tag in the CAR extracellular sequence. CAR-T cells were also left unstimulated for 10 or 45 minutes to serve as controls. Altogether, 8 unique conditions were tested in an experiment and three independent experiments were performed.

Project description:Vγ9Vδ2 T cells are an attractive cell platform for the off-the-shelf cancer immunotherapy due to their lack of alloreactivity and inherent multi-pronged cytotoxicity, which could be further amplified with chimeric antigen receptors (CARs). In this study, we sought to enhance the in vivo longevity of CAR-Vδ2 T cells by modulating ex vivo manufacturing conditions and selecting an optimal CAR costimulatory domain. Specifically, we compared the anti-tumor activity of Vδ2 T cells expressing anti-CD19 CARs with costimulatory endodomains derived from CD28, 4-1BB or CD27 and generated in either standard fetal bovine serum (FBS)- or human platelet lysate (HPL)-supplemented medium. We found that HPL supported greater expansion of CAR-Vδ2 T cells with comparable in vitro cytotoxicity and cytokine secretion to FBS-expanded CAR-Vδ2 T cells. HPL-expanded CAR-Vδ2 T cells showed enhanced in vivo anti-tumor activity with longer T cell persistence compared to FBS counterparts, with 4-1BB costimulated CAR showing the greatest activity. Mechanistically, HPL-expanded CAR Vδ2 T cells exhibited reduced apoptosis and senescence transcriptional pathways compared to FBS-expanded CAR-Vδ2 T cells and increased telomerase activity. This study supports enhancement of therapeutic potency of CAR-Vδ2 T cells through a manufacturing improvement.

Project description:Phosphopeptides of CARs in 14g2a-based anti-GD2, Leu16 anti-CD20, rituximab anti-CD20, and RFR-LCDR anti-CD20 CAR-T cells without antigen stimulation

Project description:Adoptive T cell therapy with gene-modified T cells expressing chimeric antigen receptor (CAR) is a rapidly growing field of translational medicine and recently has shown dramatic therapeutic success in the treatment of B-cell malignancies. However, challenges to achieve similar response in patients harboring solid tumour are still considerable. To achieve anti-tumor efficacy, these cells must survive, expand and persist after infusion into patients. An important lesson has been derived from clinical trials using CAR technologies: the relevance of the CAR design to enhance signaling and sustain T cell proliferation and survival. Here, we prove that third generation CARs specific for GD2 antigen incorporating CD28.4-1BB costimulatory domains improves T cell immunotherapy in a neuroblastoma (NB) pre-clinical model, as compared to a CAR with the same specificity but including CD28.OX40 costimulation. Indeed, we test the anti-tumor activity of polyclonal T cells genetically modified with third generation CAR.GD2 incorporating either CD28.4-1BB or CD28.OX40 in frame with the safety switch inducible Caspase 9 (iC9). We prove a significant in vitro and in vivo amelioration of the approach by the presence of 4.1BB signaling in terms of: 1) less T cell exhaustion, 2) lower basal T cell activation, 3) higher in vivo tumor control and 4) T cell persistence. In addition, the fine tuning of T cell culture conditions with the use of IL7 and IL15 show to be synergic with the third generation CAR.GD2 design to optimize CAR T immunotherapy for NB. Our results provide a proof-of-concept for the need to optimize not only CAR construct design but also T cell culture conditions in order to boost T cell activity in vivo.

Project description:Six transmembrane epithelial antigen of the prostate 1 (STEAP1) is a compelling tumor-associated cell surface antigen for therapeutic targeting in solid tumors. Here, we identified broad expression of STEAP1 relative to the established theranostic target prostate-specific membrane antigen (PSMA) in a series of lethal metastatic prostate cancers which prompted the development of a STEAP1-directed chimeric antigen receptor (CAR) T cell therapy. STEAP1 CAR T cells demonstrated reactivity in low antigen density, antitumor activity across multiple metastatic human and mouse prostate cancer models, and preliminary safety in a human STEAP1 knock-in mouse model. In human-in-mouse and mouse-in-mouse studies, STEAP1 CAR T cell therapy yielded effective tumor responses, but antigen escape was appreciated as a recurrent mechanism of treatment resistance and STEAP1 antigen loss was associated with diminished tumor antigen processing and presentation. The application of tumor-localized interleukin-12 (IL-12) therapy in the form of a collagen binding domain (CBD)-IL-12 fusion protein as an adjunct to STEAP1 CAR T cell therapy enhanced antitumor efficacy by remodeling the immunologically cold tumor microenvironment of prostate cancer and combating STEAP1 antigen escape through the engagement of host immunity and epitope spreading. In summary, we describe the extent of STEAP1 expression in treatment-refractory metastatic prostate cancer, characterize a STEAP1 CAR T cell therapy with preclinical evidence of potency and safety, and nominate a combinatorial immunotherapy strategy to overcome barriers to the efficacy of CAR T cell therapy in advanced prostate cancer.

Project description:Six transmembrane epithelial antigen of the prostate 1 (STEAP1) is a compelling tumor-associated cell surface antigen for therapeutic targeting in solid tumors. Here, we identified broad expression of STEAP1 relative to the established theranostic target prostate-specific membrane antigen (PSMA) in a series of lethal metastatic prostate cancers which prompted the development of a STEAP1-directed chimeric antigen receptor (CAR) T cell therapy. STEAP1 CAR T cells demonstrated reactivity in low antigen density, antitumor activity across multiple metastatic human and mouse prostate cancer models, and preliminary safety in a human STEAP1 knock-in mouse model. In human-in-mouse and mouse-in-mouse studies, STEAP1 CAR T cell therapy yielded effective tumor responses, but antigen escape was appreciated as a recurrent mechanism of treatment resistance and STEAP1 antigen loss was associated with diminished tumor antigen processing and presentation. The application of tumor-localized interleukin-12 (IL-12) therapy in the form of a collagen binding domain (CBD)-IL-12 fusion protein as an adjunct to STEAP1 CAR T cell therapy enhanced antitumor efficacy by remodeling the immunologically cold tumor microenvironment of prostate cancer and combating STEAP1 antigen escape through the engagement of host immunity and epitope spreading. In summary, we describe the extent of STEAP1 expression in treatment-refractory metastatic prostate cancer, characterize a STEAP1 CAR T cell therapy with preclinical evidence of potency and safety, and nominate a combinatorial immunotherapy strategy to overcome barriers to the efficacy of CAR T cell therapy in advanced prostate cancer.

Project description:Six transmembrane epithelial antigen of the prostate 1 (STEAP1) is a compelling tumor-associated cell surface antigen for therapeutic targeting in solid tumors. Here, we identified broad expression of STEAP1 relative to the established theranostic target prostate-specific membrane antigen (PSMA) in a series of lethal metastatic prostate cancers which prompted the development of a STEAP1-directed chimeric antigen receptor (CAR) T cell therapy. STEAP1 CAR T cells demonstrated reactivity in low antigen density, antitumor activity across multiple metastatic human and mouse prostate cancer models, and preliminary safety in a human STEAP1 knock-in mouse model. In human-in-mouse and mouse-in-mouse studies, STEAP1 CAR T cell therapy yielded effective tumor responses, but antigen escape was appreciated as a recurrent mechanism of treatment resistance and STEAP1 antigen loss was associated with diminished tumor antigen processing and presentation. The application of tumor-localized interleukin-12 (IL-12) therapy in the form of a collagen binding domain (CBD)-IL-12 fusion protein as an adjunct to STEAP1 CAR T cell therapy enhanced antitumor efficacy by remodeling the immunologically cold tumor microenvironment of prostate cancer and combating STEAP1 antigen escape through the engagement of host immunity and epitope spreading. In summary, we describe the extent of STEAP1 expression in treatment-refractory metastatic prostate cancer, characterize a STEAP1 CAR T cell therapy with preclinical evidence of potency and safety, and nominate a combinatorial immunotherapy strategy to overcome barriers to the efficacy of CAR T cell therapy in advanced prostate cancer.