CD19-directed CAR-T cells have recently been approved by the FDA for use in children and young adults with ALL and in adults with diffuse large B cell lymphoma (DLBCL) in the relapsed/refractory setting. CD22-directed CAR-T cells have shown efficacy against leukemia as well in a recent clinical trial, representing the first alternative CAR target to approach comparable efficacy to CD19 CAR-T cells. Standardization of toxicity grading and management, strategies to combat significant relapse rates after CAR-T therapy, and applicability of CAR-T cells to treat central nervous system (CNS) disease remain challenges in the field and represent priorities for continued research. CAR-T cells are a feasible, effective, and rapidly evolving therapy for patients with relapsed and refractory B cell malignancies.
Although tumors naturally prime adaptive immune responses, tolerance may limit the capacity to control progression and can compromise effectiveness of immune-based therapies for cancer. Post-proline cleaving enzymes (PPCE) modulate protein function through N-terminal dipeptide cleavage and inhibition of these enzymes has been shown to have anti-tumor activity. We investigated the mechanism by which Val-boroPro, a boronic dipeptide that inhibits post-proline cleaving enzymes, mediates tumor regression and tested whether this agent could serve as a novel immune adjuvant to dendritic cell vaccines in two different murine syngeneic murine tumors. In mice challenged with MB49, which expresses the HY antigen complex, T cell responses primed by the tumor with and without Val-boroPro were measured using interferon gamma ELISPOT. Antibody depletion and gene-deficient mice were used to establish the immune cell subsets required for tumor regression. We demonstrate that Val-boroPro mediates tumor eradication by accelerating the expansion of tumor-specific T cells. Interestingly, T cells primed by tumor during Val-boroPro treatment demonstrate increased capacity to reject tumors following adoptive transfer without further treatment of the recipient. Val-boroPro -mediated tumor regression requires dendritic cells and is associated with enhanced trafficking of dendritic cells to tumor draining lymph nodes. Finally, dendritic cell vaccination combined with Val-boroPro treatment results in complete regression of established tumors. Our findings demonstrate that Val-boroPro has antitumor activity and a novel mechanism of action that involves more robust DC trafficking with earlier priming of T cells. Finally, we show that Val-boroPro has potent adjuvant properties resulting in an effective therapeutic vaccine.
Adoptive transfer of patient-derived T cells modified to express chimeric antigen receptors (CARTs) has demonstrated dramatic success in relapsed/refractory pre-B-cell acute lymphoblastic leukemia (ALL), but response and durability of remission requires exponential CART expansion and persistence. Tumors are known to affect T-cell function, but this has not been well studied in ALL and in the context of chimeric antigen receptor (CAR) expression. Using TCF3/PBX1 and MLL-AF4-driven murine ALL models, we assessed the impact of progressive ALL on T-cell function in vivo. Vaccines protect against TCF3/PBX1.3 but were ineffective when administered after leukemia injection, suggesting immunosuppression induced early during ALL progression. T cells from leukemia-bearing mice exhibited increased expression of inhibitory receptors, including PD1, Tim3, and LAG3, and were dysfunctional following adoptive transfer in a model of T-cell receptor (TCR)-dependent leukemia clearance. Although expression of inhibitory receptors has been linked to TCR signaling, pre-B-cell ALL induced inhibitory receptor expression, at least in part, in a TCR-independent manner. Finally, introduction of a CAR into T cells generated from leukemia-bearing mice failed to fully reverse poor in vivo function.
Current multimodality therapy consisting of surgery, chemotherapy and radiation will fail in approximately 40% of patients with pediatric sarcomas and results in substantial long-term morbidity in those who are cured. Immunotherapeutic regimens for the treatment of solid tumors typically generate antigen-specific responses too weak to overcome considerable tumor burden and tumor suppressive mechanisms and are in need of adjuvant assistance. Previous work suggests that inhibitors of DASH (Dipeptidyl peptidase IV activity and/or structural homologues) enzymes can mediate tumor regression via immune-mediated mechanisms. Here we demonstrate that the DASH inhibitor, ARI-4175, can induce regression and eradication of well-established solid tumors, both as a single agent and as an adjuvant to a dendritic cell (DC) vaccine and adoptive cell therapy (ACT) in mice implanted with the M3-9-M rhabdomyosarcoma (RMS) cell line. Treatment with effective doses of ARI-4175 correlated with recruitment of myeloid (CD11b+) cells, particularly myeloid dendritic cells (DCs), to secondary lymphoid tissues and with reduced frequency of intratumoral monocytic (CD11b+Ly6-ChiLy6-Glo) myeloid-derived suppressor cells. In immunocompetent mice, combining ARI-4175 with a DC vaccine or ACT with tumor-primed T cells produced significant improvements in tumor responses against well-established M3-9-M tumors. In M3-9-M-bearing immunodeficient (Rag1-/-) mice, ACT combined with ARI-4175 produced greater tumor responses and significantly improved survival compared to either treatment alone. These studies warrant the clinical investigation of ARI-4175 for treatment of sarcomas and other malignancies particularly as an adjuvant to tumor vaccines and ACT.
Tumor-targeted vaccines represent a strategy to enhance the graft-versus-leukemia effect following allogeneic blood or marrow transplantation (alloBMT). We have previously shown that GVHD can negatively impact quantitative responses to vaccines. Using a minor histocompatibility antigen (mHA)-mismatched BMT (B6 → B6 × C3H.SW) followed by adoptive transfer of HY-specific T cells and HY-expressing dendritic cells we assessed whether GVHD induced by donor lymphocyte infusion (DLI) affects the persistence, proliferation and survival of vaccine-responding, nonalloantigen reactive T cells. Both CD8+ and CD4+ HY-specific T cells undergo less vaccine-driven proliferation in allogeneic recipients with GVHD. While vaccine responding CD8+ T cells show decreased gamma interferon and CD107a production, CD4+ T cells exhibit increased PD-1 and TIM3 expression. In addition, the degree of apoptosis in vaccine-responding CD8+ T cells was higher in the presence of GVHD, but there was no difference in CD4+ T cell apoptosis. Using Fas ligand-deficient or TRAIL-deficient DLI had no impact on apoptosis of HY-specific T cells. However, perforin-deficient alloreactive DLI induced significantly less apoptosis of vaccine-responding CD8+ T cells, and resulted in enhanced tumor protection. Thus, diminished vaccine responses during GVHD result from impaired proliferation of CD8+ and CD4+ T cells responding to vaccination, with an additional contribution from perforin-mediated CD8+ T cell apoptosis. These results provide important insights towards optimizing vaccine responses after alloBMT.
Recent studies have suggested that pan inhibitors of dipeptidyl peptidase-4 activity and/or structure homologs (DASH), including ARI-4175, can mediate tumor regression by immune-mediated mechanisms. This study assessed the potential of combining ARI-4175 with cancer vaccines. We evaluated ARI-4175's effect on immunogenic modulation, ability to sensitize tumor cells to antigen-specific CTL killing, effect on immune-cell subsets and function, and antitumor activity in 2 tumor models, both as a monotherapy and in combination with a recombinant viral or dendritic cell (DC)-based tumor-cell vaccine. ARI-4175's effects on the growth, surface phenotype, and antigen-specific CTL-mediated lysis of murine and human carcinoma cell lines were assessed in vitro. In vivo, C57BL-6 mice were treated orally with ARI-4175, after which splenocytes were assessed by flow cytometry and functional assays. Antitumor studies were performed in murine models of colon carcinoma (MC38-CEA+ in CEA-transgenic C57BL-6 mice) and rhabdomyosarcoma (M3-9-M in C57BL-6 mice). Mice received oral ARI-4175 alone or in combination with a vaccine consisting of recombinant vaccinia/fowlpox CEA-TRICOM (colon model) or a DC-based tumor-cell vaccine (rhabdomyosarcoma model). Exposure to ARI-4175 had no effect on the proliferation or viability of carcinoma cells in vitro; however, it did alter tumor phenotype, making murine and human tumor cells more sensitive to antigen-specific CTL killing. Assessment of immune-cell subsets and function indicated that ARI-4175 increased levels of natural killer cells and DCs. Detrimental immune effects, including reduced T effector cells and increased immunosuppressive cells (Tregs, MDSCs), were normalized when treatment stopped, suggesting that scheduling is critical when combining this agent with vaccine. As a monotherapy, ARI-4175 had potent antitumor activity in both tumor models, and had even greater effects when combined with a vaccine (either DC-based or poxviral vector based). These findings provide the rationale for the combined use of cancer immunotherapy with DASH enzyme inhibitors such as ARI-4175.
BackgroundThere has been a dramatic increase in T cell receptor (TCR) sequencing spurred, in part, by the widespread adoption of this technology across academic medical centers and by the rapid commercialization of TCR sequencing. While the raw TCR sequencing data has increased, there has been little in the way of approaches to parse the data in a biologically meaningful fashion. The ability to parse this new type of 'big data' quickly and efficiently to understand the T cell repertoire in a structurally relevant manner has the potential to open the way to new discoveries about how the immune system is able to respond to insults such as cancer and infectious diseases.
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