The hostile tumor microenvironment (TME) is a major challenge for the treatment of solid tumors with T-cell receptor (TCR)-modified T-cells (TCR-Ts), as it negatively influences T-cell efficacy, fitness, and persistence. These negative influences are caused, among others, by the inhibitory checkpoint PD-1/PD-L1 axis. The Preferentially Expressed Antigen in Melanoma (PRAME) is a highly relevant cancer/testis antigen for TCR-T immunotherapy due to broad expression in multiple solid cancer indications. A TCR with high specificity and sensitivity for PRAME was isolated from non-tolerized T-cell repertoires and introduced into T-cells alongside a chimeric PD1-41BB receptor, consisting of the natural extracellular domain of PD-1 and the intracellular signaling domain of 4-1BB, turning an inhibitory pathway into a T-cell co-stimulatory pathway. The addition of PD1-41BB to CD8+ T-cells expressing the transgenic PRAME-TCR enhanced IFN-γ secretion, improved cytotoxic capacity, and prevented exhaustion upon repetitive re-challenge with tumor cells in vitro without altering the in vitro safety profile. Furthermore, a single dose of TCR-Ts co-expressing PD1-41BB was sufficient to clear a hard-to-treat melanoma xenograft in a mouse model, whereas TCR-Ts without PD1-41BB could not eradicate the PD-L1-positive tumors. This cutting-edge strategy supports development efforts to provide more effective TCR-T immunotherapies for the treatment of solid tumors.
Elevated p130Cas (Crk-associated substrate) levels are found in aggressive breast tumors and are associated with poor prognosis and resistance to standard therapeutics in patients. p130Cas signals majorly through its phosphorylated substrate domain (SD) that contains 15 tyrosine motifs (YxxP) which recruit effector molecules. Tyrosine phosphorylation of p130Cas is important for mediating migration, invasion, tumor promotion, and metastasis. We previously developed a Src*/SD fusion molecule approach, where the SD is constitutively phosphorylated. In a polyoma middle T-antigen (PyMT)/Src*/SD double-transgenic mouse model, Src*/SD accelerates PyMT-induced tumor growth and promotes a more aggressive phenotype. To test whether Src*/SD also drives metastasis and which of the YxxP motifs are involved in this process, full-length and truncated SD molecules fused to Src* were expressed in breast cancer cells. The functionality of the Src*/SD fragments was analyzed in vitro, and the active proteins were tested in vivo in an orthotopic mouse model. Breast cancer cells expressing the full-length SD and the functional smaller SD fragment (spanning SD motifs 6-10) were injected into the mammary fat pads of mice. The tumor progression was monitored by bioluminescence imaging and caliper measurements. Compared with control animals, the complete SD promoted primary tumor growth and an earlier onset of metastases. Importantly, both the complete and truncated SD significantly increased the occurrence of metastases to multiple organs. These studies provide strong evidence that the phosphorylated p130Cas SD motifs 6-10 (Y236, Y249, Y267, Y287, and Y306) are important for driving mammary carcinoma progression.
Cancer immunotherapy has transformed the oncology landscape and shown promising therapeutic results in the clinic but it is also clearly facing multiple limitations. So far, the focus of immunotherapies has mainly been on the modulation of T-cells. Natural killer (NK) cells offer promising perspectives for immunotherapies as they directly kill tumor cells and produce pro-inflammatory cytokines to activate and recruit T-cells and other immune cells. Thus, NK cells are considered key players in the anti-tumor immune response that can make a “cold” tumor “hot”. However, in the tumor microenvironment (TME) of cancer patients, the low numbers of NK cells present and their exhaustion due to local immunosuppression often limit tumor cell killing. The development of NK based cell therapy products can overcome these limitations, either as single therapy or in combination with biologics such as e.g. NK cell engagers or monoclonal antibodies for boosting ADCC (antibody dependent cell cytotoxicity). To overcome the main hurdle of current autologous cell therapies, the EVOcells Oncology platform aims at developing a streamlined manufacturing process for iPSC-derived immune effector cells. The goal is to develop “off-the-shelf” cell therapy products for clinical use in large patient populations. We are currently establishing a multi-asset portfolio combining multiple immune effector cell types with different genetic editing strategies that serve to optimize this approach further. iPSC-derived NK cells (iNK cells) offer an attractive option for improving both therapeutic efficacy and safety of CAR cell therapies. Our robust, feeder-free production protocol produces iNK cells that can be reliably frozen with good recovery rates. We have generated multiple genetically modified iNK cells and have validated that the genetic modifications boost iNK function. At the end of the production process, iNK cells show phenotypic properties and single cell RNA sequencing profiles comparable to blood-derived NK cells. Importantly, iNK cells are fully functional with the ability to produce key pro-inflammatory cytokines and to form lytic immunological synapses leading to efficient killing of cancer cell lines. In addition to the killing of established tumor cell lines, we also evaluated the ability of iNK cells to kill primary leukemia cells ex vivo by using blood samples from B-cell chronic lymphocytic leukemia patients. In combination with a standard of care anti-CD20 antibody, iNK cells demonstrated the ability to kill primary leukemia cells via ADCC. Taken together, these promising results obtained with iNK cells show the potential of the EVOcells Oncology platform to deliver the next generation of cell therapies in oncology paving the way to develop a portfolio of iPSC-derived immune effector cells. Citation Format: Michael Esquerré, Audrey Holtzinger, Mélanie Pichery, Stefanie Pfaender, Saniye Yumlu, Mandy Richter, Delphine Betous, Oriane Bombarde, Mylène Gador, Nadja Sailer, Michael Paillasse, Loïc Ysebaert, Fabien Despas, Matthias Austen, Andreas Scheel, Markus Dangl. iPSC-derived natural killer cells as the front-runner program of the EVOcells Oncology platform: From inception to translational validation using patient samples [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2022; 2022 Apr 8-13. Philadelphia (PA): AACR; Cancer Res 2022;82(12_Suppl):Abstract nr 2749.
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