Abstract

Abstract Methods used to engineer cells for adoptive cell therapies (ACT) utilizing receptors that are constant across many patients (CAR or shared Ag TCRs) typically rely on Lenti-, retro-, or adeno-associated virus to deliver specificity-altering sequences to T cells. However, for personalized therapies such as the generation of neoepitope-specific TCR T cell therapies, use of viral vectors is not feasible due to long manufacturing timelines and prohibitive per-patient costs. PACT Pharma has developed a highly efficient, DNA-mediated (non-viral) proprietary precision genome engineering approach to engineer neoepitope-specific primary human T cells. This method can be widely utilized to generate T cells at research scale, as well as for ex vivo manufacturing. Briefly, genomes of individual primary human CD8 and CD4 T cells are engineered with site-specific nucleases in a single-step transfection process to yield efficient, targeted replacement of the endogenous TCR with the therapeutic neoTCR sequences. In this way, the expression of the endogenous TCR is abolished ensuring natural expression and regulation of the inserted neoTCR. The precision of neoTCR-T cell genome engineering was evaluated by Targeted Locus Amplification (TLA) for off-target integration hot spots or translocations, and by next generation sequencing based off-target cleavage assays and found to lack evidence of unintended outcomes. Engineered neoepitope-specific T cells are highly functional as demonstrated by antigen-specific proliferation, killing and cytokine production. Phenotype and detailed functional characterization of PACTs neoTCR-P1 T cells were performed and are described in a separate abstract. PACT’s precision genome engineering approach enables highly efficient generation of bespoke NeoTCR T cells for personalized adoptive cell therapy for patients with solid tumors. Furthermore, PACT precision genome engineering method is not restricted to the use in T cells and has also been applied successfully to other primary cell types, including natural killer and hematopoietic stem cells. Citation Format: Kyle Jacoby, Robert Moot, William Lu, Diana Nguyen, Barbara Sennino, Andrew Conroy, Bhamini Purandare, Adam J. Litterman, Fabrizia Urbinati, Susan P. Foy, Theresa Hunter, Albert Tai, Michael T. Bethune, Songming Peng, Olivier Dalmas, Alex Franzusoff, Stefanie J. Mandl. Highly efficient, non-viral precision genome engineering for the generation of personalized neoepitope-specific adoptive T cell therapies [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2019; 2019 Mar 29-Apr 3; Atlanta, GA. Philadelphia (PA): AACR; Cancer Res 2019;79(13 Suppl):Abstract nr 4783.

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