A versatile CRISPR-Cas13d platform for multiplexed transcriptomic regulation and metabolic engineering in primary human T cells.

CRISPR technologies have begun to revolutionize T cell therapies; however, conventional CRISPR-Cas9 genome-editing tools are limited in their safety, efficacy, and scope. To address these challenges, we developed multiplexed effector guide arrays (MEGA), a platform for programmable and scalable regulation of the T cell transcriptome using the RNA-guided, RNA-targeting activity of CRISPR-Cas13d. MEGA enables quantitative, reversible, and massively multiplexed gene knockdown in primary human T cells without targeting or cutting genomic DNA. Applying MEGA to a model of CAR T cell exhaustion, we robustly suppressed inhibitory receptor upregulation and uncovered paired regulators of T cell function through combinatorial CRISPR screening. We additionally implemented druggable regulation of MEGA to control CAR activation in a receptor-independent manner. Lastly, MEGA enabled multiplexed disruption of immunoregulatory metabolic pathways to enhance CAR T cell fitness and anti-tumor activity in vitro and in vivo. MEGA offers a versatile synthetic toolkit for applications in cancer immunotherapy and beyond.

Enhanced T cell effector activity by targeting the Mediator kinase module.

T cells are the major arm of the immune system responsible for controlling and regressing cancers. To identify genes limiting T cell function, we conducted genome-wide CRISPR knockout screens in human chimeric antigen receptor (CAR) T cells. Top hits were MED12 and CCNC, components of the Mediator kinase module. Targeted MED12 deletion enhanced antitumor activity and sustained the effector phenotype in CAR- and T cell receptor-engineered T cells, and inhibition of CDK8/19 kinase activity increased expansion of nonengineered T cells. MED12-deficient T cells manifested increased core Meditator chromatin occupancy at transcriptionally active enhancers-most notably for STAT and AP-1 transcription factors-and increased IL2RA expression and interleukin-2 sensitivity. These results implicate Mediator in T cell effector programming and identify the kinase module as a target for enhancing potency of antitumor T cell responses.

c-Jun overexpression in CAR T cells induces exhaustion resistance.

Chimeric antigen receptor (CAR) T cells mediate anti-tumour effects in a small subset of patients with cancer1-3, but dysfunction due to T cell exhaustion is an important barrier to progress4-6. To investigate the biology of exhaustion in human T cells expressing CAR receptors, we used a model system with a tonically signaling CAR, which induces hallmark features of exhaustion6. Exhaustion was associated with a profound defect in the production of IL-2, along with increased chromatin accessibility of AP-1 transcription factor motifs and overexpression of the bZIP and IRF transcription factors that have been implicated in mediating dysfunction in exhausted T cells7-10. Here we show that CAR T cells engineered to overexpress the canonical AP-1 factor c-Jun have enhanced expansion potential, increased functional capacity, diminished terminal differentiation and improved anti-tumour potency in five different mouse tumour models in vivo. We conclude that a functional deficiency in c-Jun mediates dysfunction in exhausted human T cells, and that engineering CAR T cells to overexpress c-Jun renders them resistant to exhaustion, thereby addressing a major barrier to progress for this emerging class of therapeutic agents.

Development of Cationic Quaternary Ammonium Sulfonamide Amino Lipids for Nucleic Acid Delivery.

Lipid nanoparticles (LNPs) currently comprise the most effective carrier class for the delivery of small RNAs. Among lipid carriers, charge-unbalanced lipids are relatively unexplored synthetically. Herein, we developed and evaluated a novel collection of compounds for small interfering RNA (siRNA) delivery, termed cationic quaternary ammonium sulfonamide amino lipids (CSALs). The formulated CSAL LNPs containing cholesterol, 1,2-distearoyl-sn-glycero-3-phosphocholine, and lipid poly(ethylene glycol) exhibited biophysical property trends directly related to the CSAL chemical structure. Lead CSAL LNPs were identified using an siRNA delivery screen. Further chemical synthesis using a rational structure-guided design showed that the head group structure could alter the pKa and other physical properties that modulated delivery efficacy. Shorter-chained dimethylamino head groups, acetate side chains, and higher tail carbon numbers were favorable for delivery. This led to a further study of A3-OAc-C2Me LNPs, which enabled in vivo delivery to normal mouse lungs and subcutaneous and orthotopic lung tumors. Incorporation of CSALs into liver-targeting formulations shifted the in vivo delivery of these carriers to the lungs. This study highlights the importance of the cationic lipid structure in LNPs and provides further design guidelines for nucleic acid carriers.