Project description:Understanding T cell fate requires precise knowledge of antigen reactivity. For CD4+ T cells, conventional identification of antigen reactivity by peptide restimulation relies on cellular activation, but thereby also introduces a phenotypic bias. However, by performing single-cell RNA and TCR sequencing on both antigen-stimulated and unstimulated samples, clonotypes can be tracked across conditions to identify antigen-reactive CD4+ T cells and simultaneously assess their phenotypes in the unperturbed state. Using this “reverse phenotyping” strategy, complemented by DNA-barcoded peptide–HLA class II multimers, we here investigated the longitudinal phenotypic evolution of SARS-CoV-2 spike–reactive CD4+ T cells after repeated mRNA vaccination. Without stimulation, reactive clones showed more Th-neutral features and less of an activated Th1-like state than would be assessed after antigen restimulation, yet retained a distinct transcriptional state into the memory phase. These results uncover durable imprints in antigen-reactive CD4+ T cells and highlight that cell state classification can differ fundamentally when judged by phenotype versus function.

Project description:Antigen-reactive CD4 T cells after SARS-CoV-2 vaccination show divergent phenotypic states with or without restimulation [mixed samples]

Project description:Antigen-reactive CD4 T cells after SARS-CoV-2 vaccination show divergent phenotypic states with or without restimulation [separate samples]

Project description:The in vivo phenotypic profile of T cells reactive to severe acute respiratory syndrome (SARS)-CoV-2 antigens remains poorly understood. Conventional methods to detect antigen-reactive T cells require in vitro antigenic re-stimulation or highly individualized peptide-human leukocyte antigen (pHLA) multimers. Here, we used single-cell RNA sequencing to identify and profile SARS-CoV-2-reactive T cells from Coronavirus Disease 2019 (COVID-19) patients. To do so, we induce transcriptional shifts by antigenic stimulation in vitro and take advantage of natural T cell receptor (TCR) sequences of clonally expanded T cells as barcodes for 'reverse phenotyping'. This allows identification of SARS-CoV-2-reactive TCRs and reveals phenotypic effects introduced by antigen-specific stimulation. We characterize transcriptional signatures of currently and previously activated SARS-CoV-2-reactive T cells, and show correspondence with phenotypes of T cells from the respiratory tract of patients with severe disease in the presence or absence of virus in independent cohorts. Reverse phenotyping is a powerful tool to provide an integrated insight into cellular states of SARS-CoV-2-reactive T cells across tissues and activation states.

Project description:CD4 T cells from human donors were sorted with peptide-MHC multimers based on specific epitopes. For each donor the alpha and beta chains were sequenced separately

Project description:During infections, Foxp3+ regulatory T (Treg) cells must control autoreactive conventional T (Tconv) cell responses against self-peptide antigens while permitting those against pathogen-derived “nonself” peptides. We sought to define the basis of this selectivity using mice in which Tregs reactive to a single prostate-specific self-peptide/MHC (self-pMHC) antigen, termed "C4", were selectively depleted ("C4ΔTEC" mice). We demonstrated that Tregs reactive to the C4 peptide were dispensable for the control of Tconv cells of matched antigen specificity at homeostasis but were required to control such Tconv cells and prevent fulminant prostatic autoimmunity following infection with the pathogen L monocytogenes engineered to express the C4 peptide ("Lm[C4]"). We performed the experiment outlined here to understand how the absence of C4-specific Treg cells in C4ΔTEC mice changes the phenotypic state of the C4-specific Tconv cells following Lm[C4] infection to drive autoimmunity. We found that C4-specific Tconv cells adopted preferential and differential cell states in both C4ΔTEC mice and wild-type mice that have C4-specific Treg cells. Specifically, gene expesion data revealed that C4-specific Tconv cells in wild-type mice preferentially adopted a non-proliferating effector state, while C4-specific Tconv in C4ΔTEC mice appeared as proliferating effector cells and proliferating central-memory cells.

Project description:Magnetically enriched lysosomal fractions from MEFs were prepared from cells in three different conditions: full media (control), 1 h amino acid starvation and 30 min amino acid restimulation.

Project description:Antigen-specific CD4 T cells immuno-exhausted transcriptional profile after local antigen reactivity in the liver.

Project description:Autoimmune peptide antigen reactivity in normal B6 mice Pepperchip 2.0

Project description:Antigen-multimers are high-avidity CAR-staining reagents. We reported the specificity of antigen-multimers in distinguishing CAR-T from non-CAR-T cells from patient biospecimens by performing paired single-cell RNA- and TCR-sequencing on sorted CAR-T patient samples.