Chagas disease, caused by the intracellular protozoan Trypanosoma cruzi, affects 8–10 million people worldwide and represents a major public health challenge. There is no effective treatment or vaccine to control the disease that is characterized by a mild acute phase followed by a chronic life-long infection. Approximately 30% of chronically infected individuals develop cardiac and/or digestive pathologies. T. cruzi can invade a wide variety of nucleated cells, but only persists at specific tissues in the host. However, the mechanisms that determine tissue tropism and the progression of the infection have not been fully described. Identification of infection niches in animal models has been difficult due to the limited quantity of parasite-infected cells and their focal distribution in tissues during the chronic phase. To better understand the course of chronic infections and parasite dissemination, we developed a bioluminescence imaging system based on the use of transgenic T. cruzi Colombiana strain parasites expressing nanoluciferase. Swiss Webster mice were infected with luminescent trypomastigotes and monitored for 126 days. Whole animal in vivo imaging showed parasites predominantly distributed in the abdominal cavity and surrounding areas throughout the infection. Bioluminescence signal reached a peak between 14 to 21 days post infection (dpi) and decreased progressively over time. Total animal luminescence could still be measured 126 dpi while parasites remained undetectable in blood by microscopy in most animals. Ex vivo imaging of specific tissues and organs dissected post-mortem at 126 dpi revealed a widespread parasite distribution in the skeletal muscle, heart, intestines and mesenteric fat. Parasites were also detected in lungs and liver. This noninvasive imaging model represents a novel tool to study host-parasite interactions and to identify parasite reservoirs of chronic Chagas Disease.
Chagas disease, caused by Trypanosoma cruzi, is responsible for producing significant morbidity and mortality throughout Latin America. The disease has recently become a public health concern to nonendemic regions like the U.S. and Europe. Currently there are no fully effective drugs or vaccine available to treat the disease. The mucin-associated surface proteins (MASPs) are glycosylphosphatidylinositol (GPI)-anchored glycoproteins encoded by a multigene family with hundreds of members. MASPs are among the most abundant antigens found on the surface of the infective trypomastigote stage of T. cruzi, thus representing an attractive target for vaccine development. Here we used immunoinformatics to select a 20-mer peptide with several predicted overlapping B-cell, MHC-I, and MHC-II epitopes, from a MASP family member expressed on mammal-dwelling stages of T. cruzi. The synthetic MASP peptide conjugated to keyhole limpet hemocyanin (MASPpep-KLH) was tested in presence or not of an adjuvant (alum, Al) as a vaccine candidate in the C3H/HeNsd murine model of T. cruzi infection. In considerable contrast to the control groups receiving placebo, Al, or KLH alone or the group immunized with MASPpep-KLH/Al, the group immunized with MASPpep-KLH showed 86% survival rate after challenge with a highly lethal dose of trypomastigotes. As evaluated by quantitative real-time polymerase chain reaction, MASPpep-KLH-immunized animals had much lower parasite load in the heart, liver, and spleen than control animals. Moreover, protected animals produced trypanolytic, protective antibodies, and a cytokine profile conducive to resistance against parasite infection. Finally, in vivo depletion of either CD4+ or CD8+T cells indicated that the latter are critical for protection in mice immunized with MASPpep-KLH. In summary, this new peptide-based vaccine with overlapping B- and T-cell epitopes is able to control T. cruzi infection in mice by priming both humoral and cellular immunity.
BackgroundInterleukin-12 (IL-12) is a potent, proinflammatory cytokine that holds promise for cancer immunotherapy, but its clinical use has been limited by its toxicity. To minimize systemic exposure and potential toxicity while maintaining the beneficial effects of IL-12, we developed a novel IL-12-based therapeutic system that combines tumor-specific T-cell-mediated delivery of IL-12 with membrane-restricted IL-12 localization and inducible IL-12 expression.MethodsTherapeutic T cells targeting a tumor antigen were genetically engineered to express membrane-anchored IL-12 (aIL-12). Expression, function, and shedding of the aIL-12 molecule was assessed in vitro. Tumor treatment efficacy was assessed in vivo with T cell receptor (TCR) transgenic murine tumor models and a tumor xenograft model. Key outcomes were change in tumor size, circulating levels of IL-12 and other cytokines, and survival. Toxicity was assessed via change in body weight. Tumor growth curve measurements were compared using repeated-measures two-way analyses of variance.ResultsRetroviral gene transfer resulted in cell membrane expression of aIL-12 by transduced T cells. In each of two transgenic murine tumor models, tumor-specific T cells constitutively expressing aIL-12 demonstrated increased antitumor efficacy, low circulating IL-12 and interferon-γ, and no weight loss. Expression of aIL-12 via aNFAT-inducible promoter resulted in coordinate expression of aIL-12 with T cell activation. In an OT-I TCR transgenic murine tumor model, theNFAT-inducible aIL-12 molecule improved tumor treatment and did not result in detectable levels of IL-12 in serum or in weight loss. In a human tumor xenograft model, theNFAT-inducible aIL-12 molecule improved antitumor responses by human T cells coexpressing a tumor-specific engineered TCR. Serum IL-12 levels were undetectable with theNFAT-inducible construct in both models.ConclusionExpression of aIL-12 by tumor-targeting therapeutic T cells demonstrated low systemic exposure and improved efficacy. This treatment strategy may have broad applications to cellular therapy with tumor-infiltrating lymphocytes, chimeric antigen receptor T cells, and TCR T cells.
T cell receptor (TCR) gene-engineered T cells have shown promise in the treatment of melanoma and synovial cell sarcoma, but their application to epithelial cancers has been limited. The identification of novel therapeutic TCRs for the targeting of these tumors is important for the development of new treatments. Here, we describe the preclinical characterization of a TCR directed against Kita-Kyushu Lung Cancer Antigen-1 (KK-LC-1, encoded by CT83 ), a cancer germline antigen with frequent expression in human epithelial malignancies including gastric cancer, breast cancer, and lung cancer. Gene-engineered T cells expressing the KK-LC-1 TCR (KK-LC-1 TCR-Ts) demonstrated recognition of CT83 + tumor lines in vitro and mediated regression of established CT83+ xenograft tumors in immunodeficient mouse models. Cross-reactivity studies based on experimental determination of the recognition motifs for the target epitope did not demonstrate cross-reactivity against other human proteins. CT83 gene expression studies in 51 non-neural tissues and 24 neural tissues showed expression restricted exclusively to germ cells. CT83 was however expressed by a range of epithelial cancers, with the highest expression noted in gastric cancer. Collectively, these findings support the further investigation and clinical testing of KK-LC-1 TCR-Ts for gastric cancer and possibly other malignancies. Electronic supplementary material The online version of this article (10.1186/s40425-019-0678-x) contains supplementary material, which is available to authorized users.
BackgroundCell therapy has shown promise in the treatment of certain solid tumors, but its efficacy may be limited by inhibition of therapeutic T cells by the programmed cell death protein-1 (PD-1) receptor. Clinical trials are testing cell therapy in combination with PDCD1 disruption or PD-1-axis blockade. However, preclinical data to support these approaches and to guide the treatment design are lacking.MethodsMechanisms of tumor regression and interaction between cell therapy and PD-1 blockade were investigated in congenic murine tumor models based on targeting established, solid tumors with T-cell receptor T cells directed against tumor-restricted, non-self antigens (ie, tumor neoantigens).ResultsIn solid tumor models of cell therapy, PD-1 blockade mediated a reproducible but non-synergistic increase in tumor regression following adoptive T-cell transfer. Tumor regression was associated with increased tumor infiltration by endogenous T cells but not by transferred T cells. The effect was independent of PD-1 receptor expression by transferred T cells and was dependent on the endogenous T-cell repertoire and on tumor antigenicity. PD-1 blockade primarily induced cell state changes in endogenous tumor-antigen-specific T cells rather than transferred T cells.ConclusionsTogether, these findings support the concept that PD-1 blockade acts primarily through endogenous rather than transferred T cells to mediate a non-synergistic antitumor effect in solid tumor cell therapy. These findings have important implications for strategies to leverage PD-1 receptor disruption or blockade to enhance the efficacy of cell therapy.
T cell receptor (TCR)–engineered T cell therapy using high-affinity TCRs is a promising treatment modality for cancer. Discovery of high-affinity TCRs especially against self-antigens can require approaches that circumvent central tolerance, which may increase the risk of cross-reactivity. Despite the potential for toxicity, no standardized approach to screen cross-reactivity has been established in the context of preclinical safety evaluation. Here, we describe a practical framework to prospectively detect clinically prohibitive cross-reactivity of therapeutic TCR candidates. Cross-reactivity screening consisted of multifaceted series of assays including assessment of p-MHC tetramer binding, cell line recognition, and reactivity against candidate peptide libraries. Peptide libraries were generated using conventional contact residue motif–guided search, amino acid substitution matrix–based search unguided by motif information, and combinatorial peptide library scan–guided search. We demonstrate the additive nature of a layered approach, which efficiently identifies unsafe cross-reactivity including one undetected by conventional motif-guided search. These findings have important implications for the safe development of TCR-based therapies.
Adoptive T cell therapy (ACT) has yielded promising clinical results but improvements are needed. Cell therapy efficacy may be improved by blockade of the inhibitory receptor PD1. Independent T cell models demonstrated cooperation between ACT and α-PD1. The cooperative effect of α-PD1 was abolished in three separate hosts devoid of polyclonal T cells (Rag1-KO, Trac-KO and irrelevant TCRtg hosts). Moreover, endogenous CD4 and CD8 T cells in the tumor increased and transferred T cells decreased in number following α-PD1 treatment. Efficacy of ACT was not improved when transferred cells were engineered with PD1-targeting miRNA or over-expression of PD1 without the cytoplasmic signaling domain. However, ACT with PD1-KO T cells was improved with the combination of α-PD1. Additionally, transferred T cells did not respond to α-PD1 when they were repeatedly stimulated until high co-expression of PD1+LAG3+TIM3+ (85% vs 34%) prior to transfer, when they were allowed prolonged in vivo tumor engagement prior to α-PD1 administration, or when they were targeting tumors with enforced expression of PDL1. Lastly, α-PD1 therapy showed no efficacy during the treatment of less immunogenic tumors, engineered with ubiquitin-tagged antigen constructs rather than RFP-antigen constructs. This finding established that PD1-sensitive endogenous T cells targeted immunogenic antigens within RFP. The role of endogenous T cells was further corroborated by TCR clonotype skewing when α-PD1 was administered. These data demonstrated that blocking the PD1 axis did not directly benefit adoptively transferred T cells. Rather, the benefit of α-PD1 was dependent on the presence of endogenous T cells specific for immunogenic tumor antigens.
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