Project description:Brd4 deficient and WT GP33-tetramer+ cells were sorted from spleens on D8 of LCMV infection. Tamoxifen was administered on days 5-7 of infection to induce to deletion of Brd4. KLRG1hiCD127lo TE, KLRG1loCD127lo EEC, and KLRG1loCD127hi MP cells were sorted for RNAseq analysis.
Project description:P14 cells were transferred to naïve mice subsequently infected with LCMV. Mice were treated with JQ1 or vehicle on days 1-4 of infection. On day 5 of infection KLRG1loCD127lo EEC were sorted for RNAseq analysis. In a separate experiment, P14 cells were transduced with shBrd4a or shBrd4b and mixed with shCtrl transduced P14 cells, and then transferred into naïve mice subsequently infected with LCMV. On day 5 post-infection, transduced EEC were sorted for RNAseq.
Project description:LCMV infected mice were treated with JQ1 or vehicle on days 5-7 of infection. On day 8 of infection, KLRG1hiCD127lo TE, KLRG1loCD127lo EEC, and KLRG1loCD127hi MP cells were sorted for RNAseq analysis.
Project description:Understanding the response of memory CD8 T cells to persistent antigen re-stimulation and the role of CD4 T cell help is critical to the design of successful vaccines for chronic diseases. However, studies comparing the protective abilities and qualities of memory and naïve cells have been mostly performed in acute infections, and little is known about their roles during chronic infections. Herein, we show that memory cells dominate over naïve cells and are protective when present in large enough numbers to quickly reduce infection. In contrast, when infection is not rapidly reduced, memory cells are quickly lost, unlike naïve cells. This loss of memory cells is due to (i) an early block in cell proliferation, (ii) selective regulation by the inhibitory receptor 2B4, and (iii) increased reliance on CD4 T cell help. These findings have important implications towards the design of T cell vaccines against chronic infections and tumors. 16 samples are analyzed: 3 replicates of secondary effector CD8 P14 T cells at day 8 post-acute lymphocytic choriomeningitis virus (LCMV) infection; 4 replicates of secondary effector CD8 P14 T cells at day 8 post-chronic LCMV infection; 4 replicates of primary effector CD8 P14 T cells at day 8 post-acute LCMV infection; and 5 replicates of primary effector CD8 P14 T cells at day 8 post-chronic LCMV infection.
Project description:We performed RNA-seq, ATAC-seq, and H3K27Ac ChIP-seq on P14 CD8 T cells during acute infection with LCMV Armstrong on days 0 (naïve cells), 9 (memory precursor effector cells (MPEC) and short-lived effector cells (SLECs)), and 40+ (memory cells) post infection.
Project description:Altered CD8 T cell differentiation and functional exhaustion prevent control of chronic virus infection and cancer. Yet, how fate commitment and exhaustion are determined and dynamically modulated throughout persistent infection are unclear. We compared the activation and differentiation of LCMV GP33-specific CD8 TCR transgenic cells (P14) primed at the onset versus in the midst of established persistent LCMV-Clone 13 viral infection. LCMV GP33-specific CD8 TCR transgenic (P14) cells were injected into naïve mice immediately infected with LCMV-Cl13 (Early priming) or into mice that had been infected 21 days earlier with LCMV-Cl13 (Late Priming). Sixty hours post-priming P14 cells were sorted from mice and subjected to RNA seq. We show early primed cells very rapidly exhibit a transcriptional profile of robust activation, effector differentiation and dysfunction, while late primed cells have increased expression of genes involved in memory differentiation and maintenance.
Project description:We performed RNA-seq, ATAC-seq, and H3K27Ac ChIP-seq on P14 CD8 T cells during acute infection with LCMV Armstrong on days 0 (naïve cells), 9 (memory precursor effector cells (MPEC) and short-lived effector cells (SLECs)), and 40+ (memory cells) post infection.
Project description:We performed RNA-seq, ATAC-seq, and H3K27Ac ChIP-seq on P14 CD8 T cells during acute infection with LCMV Armstrong on days 0 (naïve cells), 9 (memory precursor effector cells (MPEC) and short-lived effector cells (SLECs)), and 40+ (memory cells) post infection.
