Efficient nonviral integration of large transgenes into human T cells using Cas9-CLIPT.

CRISPR-Cas9 ribonucleoproteins (RNPs) combined with a nucleic acid template encoding a chimeric antigen receptor (CAR) transgene can edit human cells to produce CAR T cells with precise CAR insertion at a single locus. However, many human cells have adverse innate immune responses to foreign nucleic acids, particularly circular double-stranded DNA (dsDNA). Here, we introduce Cleaved, LInearized with Protein Template (Cas9-CLIPT), a circular plasmid containing a single target sequence for the Cas9 RNP, such that during manufacturing, Cas9-RNP binds and cleaves the plasmid to linearize the dsDNA in vitro. Cas9-RNP remains bound to the linearized template and is delivered to cells to promote precise knock-in via homology-directed repair with Cas9-CLIPT. Cas9-CLIPT Nanoplasmids generate up to 1.7-fold higher rates of precise knock-in relative to linearized dsDNA, reaching efficiencies up to 60% with non-homologous end joining inhibition. Cas9-CLIPT-manufactured GD2 TRAC-CAR T cells are potent against GD2⁺ neuroblastoma cells and exhibit an enriched stem cell memory phenotype. On several electroporation instruments and approaching clinically relevant yields, we successfully manufactured TRAC-CAR T cells using Cas9-CLIPT plasmids containing large (2-6 kb) transgenes. Cas9-CLIPT strategies have the potential to simplify donor template production and integrate large transgenes, allowing for more efficient nonviral manufacturing of multifunctional, genome-edited immune cell therapies.