Project description:Chimeric antigen receptor T-cell (CAR-T) therapy is at the forefront of cell immunotherapy. In this study, we generated an anti-CD19 CAR-Jurkat T cell line using a locally produced second-generation CD19 CAR construct, enabling us to analyze early proteomic changes crucial for understanding the signaling pathways and mechanisms of action of this CAR-T cell. SILAC-heavy tagged RAJI B-cells and anti-CD19 CAR-Jurkat T-cells were co-cultured for ten minutes. The proteomic profiles were obtained via DIA methodology on the Orbitrap Astral LC-MS/MS platform. The proteome was extensively covered, resulting in approximately 8800 protein identifications at 1% FDR. The effector CAR-Jurkat cells showed proteomic changes involving antigen presentation by CD74. The target RAJI B-cells exhibited more significant alterations, such as CD28, essential for T-cell survival and activation.

Project description:Chimeric antigen receptor (CAR) T-cells induce responses in patients with relapsed/refractory leukemia; however, long-term efficacy is frequently limited by post-CAR relapses. The inability to target antigen-low cells is an intrinsic vulnerability of second-generation CAR T-cells and underlies the majority of relapses following CD22BBz CAR T-cell therapy. We interrogated CD22BBz CAR signaling in response to low antigen and found inefficient phosphorylation of LAT, limiting downstream signaling. To overcome this, we designed the Adjunctive LAT-Activating CAR T-cell (ALA-CART) platform, pairing a second-generation CAR with a LAT-CAR incorporating the intracellular domain of LAT. ALA-CART cells demonstrated reduced differentiation during manufacturing and increased LAT phosphorylation, MAPK signaling and AP-1 activity. Consequently, ALA-CART cells showed improved cytotoxicity, proliferation, persistence and efficacy against antigen-low leukemias that were refractory to clinically-active CD22BBz CAR T-cells. These data suggest restoration of LAT signaling through the ALA-CART platform represents a promising strategy for overcoming multiple mechanisms of CAR T-cell failure.

Project description:Adoptive cell therapy, a subset of cancer immunotherapy, is collection of therapeutic approaches which aim to redirect the immune system by reprogramming patient T-cells to target antigenic molecules differentially and specifically expressed in certain cancers. One promising immunotherapy technique is CAR T-cell therapy, where cancer cells are targeted through the expression a chimeric antigen receptor (CAR), a synthetic trans- membrane receptor that functionally compensates for the T-cell receptor (TCR) but targets a tumor associated antigen on the cancer cell surface. While CAR T-cell therapy is promising with two clinically approved second-generation CARs (Kymriah and Yescarta), few studies have investigated the mechanism of signal propagation in T-cells and no studies have investigated the potential signaling response in the target cells. To gain further insight to CAR-based signaling, we stimulated third generation CD19 CAR-expressing Jurkat T-cells by co-culture with SILAC labeled CD19HI Raji B-cells and used two phosphoenrichment strategies coupled with liquid chromatography-tandem mass spec- trometry (LC-MS/MS) to detect and analyze global phosphorylation changes in both cell populations. Analysis of the phosphopeptides originating from the CD19-CAR T cells revealed an increase in many phosphorylation events necessary for canonical TCR signaling. We also observed for the first time a significant decrease in B-cell receptor- related phosphopeptide abundance in CD19HI Raji B-cells after co-culture with CD19-targetted CAR T-cells.

Project description:Chimeric antigen receptor (CAR) T cells have revolutionized the landscape of cancer therapy, demonstrating unprecedented success in treating relapsed or refractory blood cancers. Previous studies of the mechanisms underlying the interactions and responses of CAR T cells and their targets have focused on the activation of CAR T cells and attempted to optimize CAR design to increase efficacy, while ignoring tumors and their responses to CAR ligation. We evaluated the signaling of a second-generation, ligand-based CAR built from the colony-stimulating factor 1 (CSF1) ligand to target the CSF1 receptor (CSF1R) on CSF1R-expressing target cells, and compared it to a conventional single-chain variable fragment (scFv)–based CAR against the B-cell antigen CD19 using stable isotope labeling by amino acids in cell culture (SILAC) co-culture with phosphotyrosine (pY) enrichment and liquid chromatography–tandem mass spectrometry (LC–MS/MS).. We showed that ligation of CSF1R-expressing THP-1 cells with CSF1R-CAR T cells stimulated CSF1R-like signaling in the THP-1 cells, whereas no target cell signaling response was observed after the ligation of CD19-CAR T cells with target Raji cells. In experiments with small-molecule inhibitors of the tyrosine kinase Lck, actin polymerization, and CSF1R, we found that CAR-induced CSF1R signaling in THP-1 cells depended exclusively on the kinase activity of CSF1R with no participation from T cell activation. Consistently, CSF1R-CAR T cells promoted THP-1 cell growth at low effector-to-target (E:T) ratios but prevented THP-1 cell growth at high E:T ratios. Our data provide evidence for an unintended consequence of CARs: CAR-induced signaling in cancer cells. These data may have broad implications for the choice of CAR antigen for optimal clinical efficacy.

Project description:The study aimed to elucidate the transcriptional changes introduced by genetic engineering of CAR T cells to stably express the homeostatic chemokine receptor CCR7. In vitro killing assays hinted to a higher cytolytic capacity that could be tied to an altered cytoskeletal rearrangement. Human CAR and CAR.CCR7 T cells were generated by retroviral transduction and enriched by FACS at the end of the expansion phase (day 10), either without or with a previous over-night co-culture with target Jeko1 tumor cells that express the CAR target antigen CXCR5. Enriched cells were immediately processed for bulk mRNA Seq

Project description:Immunotherapy using CD19-directed chimeric antigen receptor (CAR)-T cells has shown excellent results for treatment of B-cell leukaemia and lymphoma. To produce CAR-T cells, the patient’s own T cells are isolated from the blood and modified in a laboratory with a genetic vector to express a tumor antigen-directed CAR on its surface. The CAR-T cells are then expanded in numbers and given back to the patient with the aim to eradicate the tumors. However, some patients display primary resistance to CAR-T treatment while others relapse quickly after CAR-T treatment. In this experiment, we seek to understand whether the quality of the individual CAR-T cell product the patients were given can predict outcome to the therapy. We investigate the transcriptional profile of the individual CAR-T infusion products using single-cell RNA sequencing. In this dataset, we identified a T cell subset correlating with response that could be used as an indicator for clinical outcome. Targeted RNA and protein single-cell libraries were obtained using the BD Rhapsody platform (BD Biosciences). In total four separate targeted libraries were produced with 6 patients per library. Sequencing was performed on NovaSeq 6000 S1 sequencer at the SNP&SEQ Technology Platform (Uppsala, Sweden). The raw scRNA-seq data was pre-processed by BD Biosciences using the Rhapsody Analysis pipeline to convert the raw reads into Unique Molecular Identifier (UMI) counts. UMIs are further adjusted within Rhapsody by applying BD’s Recursive Substitution Error Correction (RSEC) and Distribution-Based Error Correction (DBEC) in order to remove false UMIs caused by sequencing or library preparation errors. Pooled samples were deconvoluted using Sample-tag reads. The scRNA-seq and AbSeq counts were loaded, processed and used for clustering and differential gene expression with Seurat v. 4.0.0.

Project description:Analysis of TH17 cells redirected with chimeric antigen receptors (CAR) expressing various signaling domains (including CD28, 4-1BB and ICOS) after surrogate antigen stimulation. Our results showed that T cells redirected with an ICOS-based CAR specifically retained a genotype of TH17 cells with expression of Il17a, Il17f, Il1r1, Ccl20, Rorc, and in the absence of Foxp3 CAR-redirected TH17 cells from three different human normal donors were stimulated with immobilized recombinant mesothelin. Gene expression levels were determined prior to stimulation (day 0) and 4, 8, 24 and 96 hours upon antigen recognition.

Project description:Long-lived, self-renewing, multipotent T memory stem cells (TSCM) can trigger profound and sustained tumor regression but their rareness poses a major hurdle to their clinical application. Presently, clinically compliant procedures to generate relevant numbers of this T cell population are undefined. Here, we provide a strategy for deriving large numbers of clinical grade tumor-redirected TSCM cells starting from naïve precursors. CD8+CD62L+CD45RA+ naïve T cells enriched by streptamer-based serial positive selection were activated by CD3/CD28 engagement in the presence of IL-7, IL-21 and the glycogen synthase-3β inhibitor TWS119, and genetically engineered to express a CD19-specific chimeric antigen receptor (CD19-CAR). These conditions allowed for the generation of CD19-CAR modified TSCM cells that were phenotypically, functionally and transcriptomically equivalent to their naturally occurring counterpart. Compared with T cell products currently under clinical investigation, CD19-CAR modified TSCM cells exhibit enhanced metabolic fitness, persistence and anti-tumor activity against systemic acute lymphoblastic leukemia xenografts. Based on these findings, we have initiated a phase 1 clinical study to evaluate the activity of CD19-CAR modified TSCM in patients with B-cell malignancies refractory to prior allogeneic hematopoietic stem cell transplantation. Three healthy human blood donors provided lymphocyte-enriched apheresis blood for this study after informed consent. From all samples, total RNA was isolated using an miRNeasy Mini Kit (Qiagen), processed by Ambionâ??s WT expression kit, fragmented and labeled with a WT Terminal Labeling Kit (Affymetrix), hybridized to WT Human Gene 1.0 ST arrays (Affymetrix) and stained on a Genechip Fluidics Station 450 (Affymetrix), all according to the respective manufacturer's instructions. Samples represent exon-level and gene-level analyses.

Project description:To characterize transfer of molecules from target cells into CAR T cells via trogocytosis we cultured NALM-6 leukemia cell line expressing a CD19-mCherry fusion protein with CAR T cells. NALM6-CD19-mCherry were loaded with heavy amino acid and cocultured with CAR T cells for 1 hour. CAR T cells were next sorted into two fractions, mCherry-positive (TrogPos), and -negative (TrogNeg). Proteomics analysis revealed the presence of targeted antigen (CD19) in the TrogPos only.

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.