Project description:<p>The adoptive transfer of autologous T cells genetically modified to express a CD19-specific, 4-1BB/CD3zeta-signaling chimeric antigen receptor (CAR; CTL019) has shown remarkable activity in patients with B acute lymphoblastic leukemia. Similar therapy can induce long-term remissions for relapsed/refractory chronic lymphocytic leukemia (CLL) patients, but in only a small subset of subjects. The determinants of response and resistance to CTL019 therapy of CLL are not fully understood. We employed next generation sequencing of RNA (RNA-seq) to identify predictive indicators of response to CTL019 treatment. We performed RNA-seq on leukapheresis and manufactured infusion product T cells from patients with heavily pre-treated and high-risk disease. To characterize potency, we also performed RNA-seq on the cellular infusion product after CAR-specific stimulation. Our findings indicate that durable remission in CLL is associated with gene expression signatures of early memory T cell differentiation (e.g., STAT3), while T cells from poorly- or non-responding patients exhibited elevated expression of key regulators of late memory as well as effector T cell differentiation, apoptosis, aerobic glycolysis, hypoxia and exhaustion. These gene expression signatures, along with additional immunological biomarkers, may be used to identify which patients are most likely to respond to cellular therapies and suggest manufacturing modifications that might potentiate the generation of maximally efficacious infusion products.</p>

Project description:We observed self-activation of SKM-CAR-T cells which target novel mesothelioma antigen. CAR-T with CD28 costimulatory domain showed signs of exhaustion while those with 4-1BB costimulatory domain did not. To elucidate molecules responsible for self-activation-induced exhaustion, we performed RNA-seq analysis of SKM-CAR-T cells with CD28 or 4-1BB and CD19-CAR-T cells with CD28 or 4-1BB.

Project description:We report 101,326 single cell transcriptomes and surface protein landscape from the Chimeric antigen receptor-modified (CAR) T infusion products of 12 pediatric ALL patients upon CAR antigen-specific stimulation in comparison with TCR-mediated activation and controls.

Project description:Chimeric antigen receptor (CAR) T-cell expansion and persistence represent key factors to achieve complete responses and prevent relapses. These features are typical of early memory T cells, which can be highly enriched through optimized manufacturing protocols. Here, we investigated the efficacy and safety profiles of CAR T-cell products generated from pre-selected naive/stem memory T cells (TN/SCM), as compared to unselected T cells (TBULK). Notwithstanding their reduced effector signature in vitro, limiting CAR TN/SCM doses showed superior antitumor activity and the unique ability to counteract leukemia re-challenge in hematopoietic stem/precursor cell-humanized mice, featuring increased expansion rates and persistence, together with an ameliorated exhaustion and memory phenotype. Most relevantly, CAR TN/SCM proved to be intrinsically less prone to induce severe cytokine release syndrome, independently of the costimulatory endodomain employed. This safer profile was associated with milder T-cell activation, which translated in reduced monocyte activation and cytokine release. These data suggest that CAR TN/SCM are endowed with a wider therapeutic index compared to CAR TBULK.

Project description:Chimeric antigen receptor (CAR)-expressing T-cells induce durable remissions in patients with relapsed/refractory B-cell malignancies. CARs are artificial constructs introduced into mature T-cells conferring a second, non-MHC restricted specificity in addition to the endogenous T-cell receptor (TCR). The impact of TCR activation on CAR T-cell efficacy in vivo has important implications for clinical optimization of CAR T-cell therapy, but cannot be systematically evaluated in xenograft models. Using an immunocompetent, syngeneic murine model of CD19-targeted CAR T-cell therapy for pre-B cell ALL, we demonstrate loss of CD8 CAR T-cell mediated clearance of leukemia associated with T-cell exhaustion and apoptosis when TCR antigen is present. CD4 CAR T-cells demonstrate equivalent cytotoxicity, as compared to CD8 CAR T-cells, and in contrast, retain in vivo efficacy in the presence of TCR stimulation. Gene expression profiles confirm increased exhaustion and apoptosis of CAR8 upon dual receptor stimulation compared to CAR4, and indicate inherent differences in T-cell pathways. Chimeric antigen receptor (CAR) T cells express two activating receptors, the CAR and the endogenous T cell receptor (TCR). CAR T cells can be derived from either CD8 or CD4 T cells to generate CAR8 and CAR4 cells, respectively. In vivo, CAR8 and CAR4 cells respond differently when simultaneously stimulated through the CAR and TCR.

Project description:Programming cell signaling during T-cell activation represents a simple strategy for improving the potency of therapeutic T-cell products. Stim-R™ technology (Lyell Immunopharma) is a customizable, degradable synthetic cell biomimetic that emulates physiologic, cell-like presentation of signal molecules to control T-cell activation. A breadth of Stim-R formulations with different anti-CD3/anti-CD28 (αCD3/αCD28) antibody densities and stoichiometries were screened for their effects on multiple metrics of T-cell function. We identified an optimized formulation that produced receptor tyrosine kinase-like orphan receptor 1 (ROR1)-targeted chimeric antigen receptor (CAR) T cells with enhanced persistence and polyfunctionality in vitro, as assessed in repeat-stimulation assays, compared with a benchmark product generated using a conventional T-cell–activating reagent. In transcriptomic analyses, CAR T cells activated with Stim-R technology showed downregulation of exhaustion-associated gene sets and retained a unique subset of stem-like cells with effector-associated gene signatures following repeated exposure to tumor cells. Compared with the benchmark product, CAR T cells activated using the optimized Stim-R technology formulation exhibited higher peak expansion, prolonged persistence, and improved tumor control in a solid tumor xenograft model. Enhancing T-cell products with Stim-R technology during T-cell activation may help improve therapeutic efficacy against solid tumors.

Project description:Programming cell signaling during T-cell activation represents a simple strategy for improving the potency of therapeutic T-cell products. Stim-R™ technology (Lyell Immunopharma) is a customizable, degradable synthetic cell biomimetic that emulates physiologic, cell-like presentation of signal molecules to control T-cell activation. A breadth of Stim-R formulations with different anti-CD3/anti-CD28 (αCD3/αCD28) antibody densities and stoichiometries were screened for their effects on multiple metrics of T-cell function. We identified an optimized formulation that produced receptor tyrosine kinase-like orphan receptor 1 (ROR1)-targeted chimeric antigen receptor (CAR) T cells with enhanced persistence and polyfunctionality in vitro, as assessed in repeat-stimulation assays, compared with a benchmark product generated using a conventional T-cell–activating reagent. In transcriptomic analyses, CAR T cells activated with Stim-R technology showed downregulation of exhaustion-associated gene sets and retained a unique subset of stem-like cells with effector-associated gene signatures following repeated exposure to tumor cells. Compared with the benchmark product, CAR T cells activated using the optimized Stim-R technology formulation exhibited higher peak expansion, prolonged persistence, and improved tumor control in a solid tumor xenograft model. Enhancing T-cell products with Stim-R technology during T-cell activation may help improve therapeutic efficacy against solid tumors.

Project description:Lymphodepletion chemotherapy followed by infusion of T cells modified to express a CD19-targeting chimeric antigen receptor (CAR) has produced remarkable anti-tumor responses in patients with B cell malignancies. However, little is known about the clonal composition and transcriptional heterogeneity of CAR-T cells in the infusion products (IP) and clonal kinetics after adoptive transfer. We performed single-cell RNA sequencing (scRNA-seq) on CD8+ CAR-T cells isolated from the IP and the blood of patients treated on a phase 1 clinical trial (NCT01865617) with lymphodepletion chemotherapy and a defined formulation of CD4+ and CD8+ CD19-specific CAR-T cells. Infused CD8+ CAR-T cells displayed transcriptional heterogeneity which declined after adoptive transfer, coincident with early expression of genes associated with activation. We identified four transcriptionally distinct CAR-T cell subsets in the IP and found that these subsets differed in their contributions to the CAR-T cell population detected in blood after infusion. Better understanding of the kinetics of clonal expansion of CAR-T cells after adoptive transfer may provide insight into strategies to improve CAR-T cell immunotherapy.

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:CD70 is an attractive target for chimeric antigen receptor (CAR) T-cell therapy for the treatment of both solid and liquid malignancies. However, the functionality of CD70-specific CAR T-cells is modest. We optimized a CD70-specific VHH-based CAR (nanoCAR). We evaluated the nanoCARs in clinically relevant models in vitro, using co-cultures of CD70-specific nanoCAR T-cells with malignant rhabdoid tumor organoids, and in vivo using a diffuse large B-cell lymphoma (DLBCL) patient-derived xenograft (PDX) model. Whereas the nanoCAR T-cells were highly efficient in organoid co-cultures, they showed only modest efficacy in the PDX model. Fratricide was not causing this loss in efficacy but rather CD70 interaction in cis with the nanoCAR, as validated by imaging flowcytometry, induces exhaustion. Knocking out CD70 expression in nanoCAR T-cells using CRISPR/Cas9, resulted in dramatically enhanced functionality in the DLBCL PDX model. Through single-cell transcriptomics, we obtained evidence that CD70 knock out (KO) CD70-specific nanoCAR T-cells were protected from antigen-induced exhaustion. In addition, we were able to demonstrate that WT CD70-specific nanoCAR T-cells already exhibit signs of exhaustion shortly after production. Their gene signature strongly overlapped with gene signatures of exhausted CAR T-cells. On the other hand, the gene signature of KO nanoCAR T-cells overlapped with the gene signature of CAR T-cell infusion products that led to complete responses in chronic lymphatic leukemia patients. Our data show that CARs targeting endogenous T-cell antigens, negatively affect CAR T-cell functionality by inducing an exhausted state, which can be overcome by knocking out the specific target, in this case CD70.