Plasticity of clonal memory CD8 T cell differentiation

Abstract

Abstract Memory CD8 T cells provide highly specific and long-lasting protection against previously experienced pathogens. This potent protection is mediated by hundreds to thousands of unique clones with distinct T cell receptors (TCRs). Higher T cell clonal diversity and recognition of a wider range of pathogen antigens are associated with improved host protection. Therefore, understanding how clonal responses are organized is important for improving T cell function in a range of diseases. To comprehensively test the range of clonal memory T cell differentiation capacity, we deeply profiled polyclonal mouse memory CD8 T cells from acute lymphocytic choriomeningitis virus (LCMV) infection before and after viral rechallenge by paired single cell RNA and TCR sequencing. We found that individual memory T cell clone expansion and differentiation at the peak of the rechallenge response is highly variable. Clones are spread across various patterns of unique phenotypes ranging from highly cytotoxic to stem-like memory states. To quantify clonal differentiation plasticity, we transferred memory T cells into multiple new congenic recipients. Clonal progeny in different hosts acquired highly similar differentiation states suggesting that emergent memory clone behavior is imprinted by events during the primary infection. Indeed, transcriptional state of clones prior to rechallenge was sufficient to predict clone behavior upon rechallenge. This work provides a platform for understanding the mechanisms by which memory T cells make decisions and future studies will aim to perturb clones to elicit specific functions during a memory response. Supported by grants from the Burroughs Wellcome Fund (Career Award for Medical Scientists [ATS]), Cancer Research Institute (Technology Impact Award, Lloyd J. Old STAR Award [ATS]), American Society of Hematology (ASH Scholar Award [ATS]), Parker Institute for Cancer Immunotherapy (ATS), Stanford School of Medicine (Propel Postdoctoral Scholarship [KHG]), National Institutes of Health (5T32AI007290-38 [CJR])