Project description:Mutations in RNA splicing factors are prevalent across cancers and generate recurrently mis-spliced mRNA isoforms. Here we identified a series of bona fide neoantigens translated from highly stereotyped splicing alterations promoted by neomorphic, leukemia-associated somatic mutations in the splicing machinery. We utilized feature-barcoded peptide-MHC dextramers to isolate neoantigen-specific T cell receptors (TCR) from both healthy donors and patients with leukemia. While circulating neoantigen-specific CD8+ T cells were identified in patients with active disease, they were dysfunctional with reduced inflammatory response gene signatures. In contrast, donor CD8+ T cells with tumor-reactive TCRs were present following curative allogeneic hematopoietic cell transplant. T cells engineered with TCRs recognizing an SRSF2 mutant-induced neoantigen in CLK3 resulted in specific recognition and cytotoxicity of SRSF2 mutant leukemia. These data identify RNA mis-splicing derived neoantigens and neoantigen-specific TCRs across patients and provide proof-of-concept to genetically redirect T cells to public mis-splicing derived neoantigens in myeloid leukemias.

Project description:The success of cancer immunotherapy depends in part on the strength of antigen recognition by T cells. We characterized the T cell receptor (TCR) functional (antigen sensitivity) and structural (monomeric pMHC-TCR off-rates) avidities of 371 CD8 T cell clones specific for neoantigens, tumor-associated antigens (TAAs) or viral antigens isolated from tumors or blood of patients and healthy subjects. T cells from tumors exhibit stronger functional and structural avidity than their blood counterparts. Relative to TAA, neoantigen-specific T cells are of higher structural avidity and, consistently, are preferentially detected in tumors. Effective tumor infiltration in mice models is associated with high structural avidity and CXCR3 expression. Based on TCRs biophysicochemical properties, we derived and applied an in silico model predicting TCR structural avidity and validated the enrichment in high avidity T cells in patients’ tumors. These observations indicate a direct relationship between neoantigen recognition, T cell functionality and tumor infiltration. These results delineate a rational approach to identify potent T cells for personalized cancer immunotherapy.

Project description:The success of cancer immunotherapy depends in part on the strength of antigen recognition by T cells. We characterized the T cell receptor (TCR) functional (antigen sensitivity) and structural (monomeric pMHC-TCR off-rates) avidities of 371 CD8 T cell clones specific for neoantigens, tumor-associated antigens (TAAs) or viral antigens isolated from tumors or blood of patients and healthy subjects. T cells from tumors exhibit stronger functional and structural avidity than their blood counterparts. Relative to TAA, neoantigen-specific T cells are of higher structural avidity and, consistently, are preferentially detected in tumors. Effective tumor infiltration in mice models is associated with high structural avidity and CXCR3 expression. Based on TCRs biophysicochemical properties, we derived and applied an in silico model predicting TCR structural avidity and validated the enrichment in high avidity T cells in patients’ tumors. These observations indicate a direct relationship between neoantigen recognition, T cell functionality and tumor infiltration. These results delineate a rational approach to identify potent T cells for personalized cancer immunotherapy.

Project description:Chimeric antigen receptor-modified (CAR) T cell therapy targeting highly expressed lineage antigens is effective for B cell malignancies. Achieving durable efficacy for hematological malignancies and extending this therapeutic approach to solid tumors will require T cell recognition and elimination of tumor cells that may express lower levels of the CAR target antigen. Realizing this goal is challenging because current approaches to CAR design are largely empiric and detailed information on CAR signaling is only beginning to emerge. Synthetic CARs typically require hundreds of molecules on the target cell to initiate signaling, whereas natural T cell receptors (TCRs) can recognize less than ten peptide-MHC (pMHC) antigen complexes. We reasoned that in depth comparison of TCR and CAR stimulation-induced signaling events in primary T cells might guide rationale adaptations to CAR design that would improve antigen sensitivity. Bi-specific T cells possessing an endogenous TCR and exogenous CAR of defined specificity were formulated from healthy HLA-B8+ Epstein-Barr virus-seropositive donors. Bi-specific T cells were stimulated with magnetic microbeads coated with recombinant TCR or CAR antigen for 10, 45, or 90 minutes. Some bi-specific T cells were also left unstimulated and harvested at each timepoint to serve as controls. Altogether, 9 unique conditions were tested in an experiment and three independent experiments were performed.

Project description:Chimeric antigen receptor T (CAR-T) cell therapies for B cell malignancies demonstrate high response rate and durable disease control. However, in the case of solid tumors, CAR-T cells have shown dysfunction ascribed to some intrinsic defects in CAR signaling. Here, we construct a multi-chain chimeric receptor, termed as Synthetic T Cell Receptor and Antigen Receptor (STAR), which incorporates antigen-recognition domain of antibody and engages entire CD3 signaling machinery of T cell receptor (TCR). In multiple solid tumor models, STAR-T cells prominently outperform CAR-T cells without notable toxicity. STAR triggers strong and sensitive TCR-like signaling upon antigen stimulation. We compared the transcriptional profiles of STAR/CAR/TCR-T cells after stimulation for different time points (0, 6, 24, 72 hours), in order to figure out whether signaling difference of these receptors led to distinct gene expression. Our results showd that STAR activation phencopied TCR, while CAR drove a different program, displayed as various pathways related to effector function, cytokine response and cell survival were altered.

Project description:Studies employing antigen-presenting systems at the ensemble or single cell level can provide complementary insights into T-cell activation and signaling. However, synthetic material toolkits that probe T cells at both levels are lacking, although they would be essential in advancing basic immunology and immunotherapy. Here, we develop a biomimetic antigen-presenting system (bAPS) using hexapod heterostructures (i.e., a sub-micrometer hematite core, and nanostructured silica branches with diverse surface modifications) for single-cell, single-molecule stimulation and ensemble modulation of T-cell signaling. We report with single molecule resolution of: T-cell sensing/activation by a single agonist peptide-major histocompatibility complex; distinct T-cell receptor (TCR) responses to discriminate structurally similar peptides that differ by just one amino acid; and the superior sensitivity of TCR antigen recognition compared to chimeric antigen receptors (CARs). We also show that magnetic field-induced piconewton×micrometer-level torques on the hexapods amplify immune responses in suspension T and CAR-T cells. Furthermore, by using our bAPS, we have developed a reliable and high-throughput new method for identifying neoantigen-specific TCRs at the single-cell level. The multimodal hexapod bAPS presents an unexplored, nanotechnology-based biointerface tool for investigating recognition, signaling, and the biochemical/mechanical dual sensitivity of T cells and beyond.

Project description:Neoantigens derived from non-synonymous somatic mutations, especially gene fusion mutation, are restricted to tumor cells and thus considered ideal targets for T-cell receptor-engineering T-cells (TCR-T) immunotherapy. Adoptive transfer of neoantigen-specific TCR-T cells preferentially exhibit potent cytotoxicity preferentially to tumor cells, and has shown promising efficacy in several preclinical human cancer models. However, most neoantigens are unique to individual patient, which hinders the application of TCR-T cell therapy. In this study, we first discovered a paired / TCR repertoire, Tcr-1, that specifically targeted STY-SSX fusion neoantigen shared by almost all synovial sarcomas. Engineered T-cell expressing Tcr-1 (Tcr-T1) exhibited antigen-specific HLA-A*2402-restricted antitumoral activity against synovial sarcomas cell both in vitro and in vivo. Furthermore, to furtherly extend its application beyond synovial sarcomas, we innovatively developed a cooperative therapeutic modality, in which exogenous SYT-SSX fusion neoantigen was loaded into enzyme-responsive nanoparticles (NPs) formed by mPEG-PVGLIG-PCL copolymers (FNeo-AgNPs) for tumor targeting delivery. As expected, FNeo-AgNPs were proven of great tumor penetration, and local release. In situ modification was able to direct engineered Tcr-T1 against to other malignant gastric cancer cell line with significant antigen-specific HLA-A*2402-restricted cytotoxicity resulting in remarkable tumor regression and prolonging survival in both subcutaneous and peritoneally disseminated preclinical models, despite of their inherent mutation profiles. With these favorable data, our established cooperative therapeutic modality has a great potential for further clinical investigation, and provide a now insight for future TCR-T cell therapy development.

Project description:Neoantigen-reactive cytotoxic T lymphocytes play a vital role in precise cancer cell elimination. In this study, we demonstrate the effectiveness of personalized neoantigen-based T cell therapy in inducing tumor regression in two patients suffering from heavily-burdened metastatic ovarian cancer. Our approach involved the development of a robust pipeline for ex vivo expansion of neoantigen-reactive T lymphocytes. Neoantigen peptides were designed and synthesized based on the somatic mutations of the tumors and their predicted HLA binding affinities. These peptides were then presented to T lymphocytes through co-culture with neoantigen-loaded dendritic cells for ex vivo expansion. Subsequent to cell therapy, both patients exhibited significant reductions in tumor marker levels and experienced substantial tumor regression. One patient achieved repeated cancer regression through infusions of T cell products generated from newly identified neoantigens. Transcriptomic analyses revealed a remarkable increase in neoantigen-reactive cytotoxic lymphocytes in the peripheral blood of the patients following cell therapy. These cytotoxic T lymphocytes expressed polyclonal T cell receptors (TCR) against neoantigens, along with abundant cytotoxic proteins and pro-inflammatory cytokines. The efficacy of neoantigen targeting was significantly associated with the immunogenicity and TCR polyclonality. Notably, the neoantigen-specific TCR clonotypes persisted in the peripheral blood after cell therapy. Our findings indicate that personalized neoantigen-based T cell therapy triggers cytotoxic lymphocytes expressing polyclonal TCR against ovarian cancer, suggesting its promising potential in cancer immunotherapy.

Project description:T Cell Receptor-mimic STAR Conveys Superior Sensitivity over CAR in Targeting Tumors with Low-density Neoantigens

Project description:Approaches to analyze and cluster T-cell receptor (TCR) repertoires to reflect antigen specificity are critical for the diagnosis and prognosis of immune-related diseases and the development of personalized therapies. Sequence-based approaches showed success but remain restrictive, especially when the amount of experimental data used for the training is scarce. Structure-based approaches which represent powerful alternatives, notably to optimize TCRs affinity toward specific epitopes, show limitations for large-scale predictions. To handle these challenges, TCRpcDist is presented, a 3D-based approach that calculates similarities between TCRs using a metric related to the physico-chemical properties of the loop residues predicted to interact with the epitope. By exploiting private and public datasets and comparing TCRpcDist with competing approaches, it is demonstrated that TCRpcDist can accurately identify groups of TCRs that are likely to bind the same epitopes. Importantly, the ability of TCRpcDist is experimentally validated to determine antigen specificities (neoantigens and tumor-associated antigens) of orphan tumor-infiltrating lymphocytes (TILs) in cancer patients. TCRpcDist is thus a promising approach to support TCR repertoire analysis and TCR deorphanization for individualized treatments including cancer immunotherapies.