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Abstract

Chimeric antigen receptor (CAR) T cell immunotherapy for the treatment of cancer is now an approved treatment for B cell malignancies. However, the use of viral vectors to provide long-term CAR expression is associated with high production costs and cumbersome quality controls, impacting the final cost of CAR T cell therapies. Nonviral integrative vectors, such as Sleeping Beauty (SB) transposons, provide an alternative to modify primary T cells. Therefore, we developed a protocol to expand SB-transfected 19BBζ CAR T cells using a lymphoblastoid cell line, and evaluated T cell phenotype as well as function along the T cell expansion. Electroporation of PBMCs with transposon plasmid decreased cell viability on day 1 but had a minor impact on the frequency of memory subpopulations when compared to mock condition. CAR+ lymphocytes showed increased proliferation compared to mock control and high cytotoxic activity towards CD19+ cells without significant differences in exhaustion markers expression. Moreover, CAR+ lymphocytes showed an increased frequency by the end of the stimulation cycle compared with day 1, suggesting that CAR expression confers a selective proliferation advantage. Immunodeficient NOD scid gamma chain knockout (NSG) mice engrafted with the human pre-B leukemic cell line RS4;11 and treated with 19BBζ CAR T cells showed improved overall survival when compared to mock T cells treated animals. The results showed that electroporation using the SB system is a simple and affordable method for inducing long-term CAR expression in T lymphocytes. Expansion of gene-modified T cells with the lymphoblastoid cell line provided up to 2 cycles of stimulations, generating effective T cells against leukemia in vitro and in vivo.

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CAR T Cells Generated Using Sleeping Beauty Transposon Vectors and Expanded with an EBV-Transformed Lymphoblastoid Cell Line Display Antitumor Activity In Vitro and In Vivo

Abstract

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Supplementary Material