CAR-T cells targeting IL-1RAP produced in a closed semiautomatic system are ready for the first phase I clinical investigation in humans.

PURPOSE OF THE STUDY: The use of chimeric antigen receptor (CAR)-T cells has demonstrated excellent results in B-lymphoid malignancies. The Advanced Therapy Medicinal Products (ATMP) status and good manufacturing practice (GMP) of CAR-T cells require particular conditions of production performed in a pharmaceutical establishment. Our team developed a new medical drug candidate for acute myeloid leukemia (AML), a CAR targeting interleukin-1 receptor accessory protein (IL-1RAP) expressed by leukemia stem cells, which will need to be evaluated in a phase I-IIa clinical trial. During the preclinical development phase, we produced IL-1RAP CAR-T cells in a semi-automated closed system (CliniMACSࣨ Prodigy) using research grade lentiviral particles. PATIENTS AND THE METHODS: The purpose of this work was to validate our production process and to characterize our preclinical GMP-like medicinal product. IL-1RAP CAR-T cells were produced from healthy donors in 9 days, either in an semi-automated closed system (with GMP-like compliant conditions) or according to another research protocols, which was used as a reference. RESULTS: Based on phenotypic, functional and metabolic analyses, we were able to show that the final product is ready for clinical use. Finally, in a xenograft AML murine model, we demonstrated that the IL-1RAP CAR-T cells generated in a GMP-like environment could eliminate tumor cells and increase overall survival. CONCLUSION: We demonstrated that our IL-1RAP CAR-T cell preclinical GMP-like production process meets standard regulatory requirements in terms of CAR-T cell number, subpopulation phenotype and cytotoxic functionality. Our CAR-T cell production process was validated and can be used to produce medicinal IL-1RAP CAR-T cells for the first phase I clinical trial.

Performance of Pyridylthiourea-Polyethylenimine Polyplex for siRNA-Mediated Liver Cancer Therapy in Cell Monolayer, Spheroid, and Tumor Xenograft Models.

Medical application of siRNAs relies on methods for delivering nucleic acids into the cytosol. Synthetic carriers, which assemble with nucleic acids into delivery systems, show promises for cancer therapy but efficiency remains to be improved. In here, the effectiveness of pyridylthiourea-polyethylenimine (πPEI), a siRNA carrier that favors both polyplex disassembly and endosome rupture upon sensing the acidic endosomal environment, in 3 experimental models of hepatocellular cancer is tested. The πPEI-assisted delivery of a siRNA targeting the polo-like kinase 1 into Huh-7 monolayer produces a 90% cell death via a demonstrated RNA interference mechanism. Incubation of polyplex with Huh-7 spheroids leads to siRNA delivery into the superficial first cell layer and a 60% reduction in spheroid growth compared to untreated controls. Administration of polyplexes into mice bearing subcutaneous implanted Huh-7Luc tumors results in a reduced tumor progression, similar to the one observed in the spheroid model. Altogether, these results support the in vivo use of synthetic and dedicated polymers for increasing siRNA-mediated gene knockdown, and their clinical promise in cancer therapeutics.