Atlas-Guided Discovery of Transcription Factors for T Cell Programming Article Swipe

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Biology Transcription factor Computational biology Epigenetics T cell Cell Cellular differentiation CD8 Cell biology Immune system Genetics Gene

H. Kay Chung , Cong Liu , Alexander N. Jambor , Brian Riesenberg , Ming Sun , Eduardo Casillas , Brent Chick , Audrey Wang , Jun Wang , Shixin Ma , Bryan McDonald , Peixiang He , Qiyuan Yang , T.-S. Chen , Siva Karthik Varanasi , Michael LaPorte , Thomas H. Mann , Dan Chen , Filipe Araujo Hoffmann , Victoria Tripple , Josephine Ho , Jennifer L. Modliszewski , April E. Williams , Ukrae H Cho , Longwei Liu , Yingxiao Wang , Diana C. Hargreaves , Jessica E. Thaxton , Susan M. Kaech , Wei Wang ·

YOU? · · 2023 · Open Access · · DOI: https://doi.org/10.1101/2023.01.03.522354 · OA: W4313457186

CD8 + T cells differentiate into diverse states that shape immune outcomes in cancer and chronic infection 1–4 . To systematically define the transcription factors (TFs) driving these states, we built a comprehensive atlas integrating transcriptional and epigenetic data across nine CD8 + T cell states and inferred TF activity profiles. Our analysis catalogued TF activity fingerprints, uncovering regulatory mechanisms governing selective cell state differentiation. Leveraging this platform, we focused on two transcriptionally similar but functionally opposing states critical in tumor and viral contexts: terminally exhausted T cells (TEX term ), which are dysfunctional 5–8 , and tissue-resident memory T cells (T RM ), which are protective 9–13 . Global TF community analysis revealed distinct biological pathways and TF-driven networks underlying protective versus dysfunctional states. Through in vivo CRISPR screening integrated with single-cell RNA sequencing ( in vivo Perturb-seq), we delineated several TFs that selectively govern TEX term differentiation. We also identified HIC1 and GFI1 as shared regulators of TEX term and T RM differentiation and KLF6 as a unique regulator of T RM . Importantly, we discovered novel TEX term - selective TFs, including ZSCAN20 and JDP2, with no prior known function in T cells. Targeted deletion of these TFs enhanced tumor control and synergized with immune checkpoint blockade but did not interfere with T RM formation. Consistently, their depletion in human T cells reduces the expression of inhibitory receptors and improves effector function. By decoupling exhaustion T EX -selective from protective T RM programs, our platform enables more precise engineering of T cell states, accelerating the rational design of more effective cellular immunotherapies.