Mapping variant effects on anti-tumor hallmarks of primary human T cells with base-editing screens.
Zachary H WalshParin ShahNeeharika KothapalliShivem B ShahGergő NikolényiD Zack BrodtmanGiuseppe LeuzziMeri RogavaMichael MuPatricia HoSinan AbuzaidNeil VasanMohammed AlQuraishiJoshua D MilnerAlberto CicciaJohannes C MelmsBenjamin IzarPublished in: Nature biotechnology (2024)
Single-nucleotide variants (SNVs) in key T cell genes can drive clinical pathologies and could be repurposed to improve cellular cancer immunotherapies. Here, we perform massively parallel base-editing screens to generate thousands of variants at gene loci annotated with known or potential clinical relevance. We discover a broad landscape of putative gain-of-function (GOF) and loss-of-function (LOF) mutations, including in PIK3CD and the gene encoding its regulatory subunit, PIK3R1, LCK, SOS1, AKT1 and RHOA. Base editing of PIK3CD and PIK3R1 variants in T cells with an engineered T cell receptor specific to a melanoma epitope or in different generations of CD19 chimeric antigen receptor (CAR) T cells demonstrates that discovered GOF variants, but not LOF or silent mutation controls, enhanced signaling, cytokine production and lysis of cognate melanoma and leukemia cell models, respectively. Additionally, we show that generations of CD19 CAR T cells engineered with PIK3CD GOF mutations demonstrate enhanced antigen-specific signaling, cytokine production and leukemia cell killing, including when benchmarked against other recent strategies.