Project description:Even though T-cell receptor (TCR) stimulation together with co-stimulation is sufficient for the activation of both naïve and memory T cells, the memory cells are capable of producing lineage specific cytokines much more rapidly than the naïve cells. The mechanisms behind this rapid recall response of the memory cells are still not completely understood. Here, we performed epigenetic profiling of human resting naïve, central and effector memory T cells using ChIP-Seq and found that unlike the naïve cells, the regulatory elements of the cytokine genes in the memory T cells are marked by activating histone modifications even in the resting state. Therefore, the ability to induce expression of rapid recall genes upon activation is associated with the deposition of positive histone modifications during memory T cell differentiation. We propose a model of T cell memory, in which immunological memory state is encoded epigenetically, through poising and transcriptional memory.

Project description:Memory T cells are heterogeneous in terms of their phenotype and functional properties. We investigated the molecular profiles of human CD8 naïve (TN), central memory (TCM), effector memory (TEM), and effector memory RA (TEMRA) T cells using gene expression microarrays and phospho-protein-specific intracellular flow cytometry. We demonstrate that TCM have a gene expression and cytokine signaling signature that lies between that of TN and TEM or TEMRA cells, whereas TEM and TEMRA are closely related. Our data define the molecular basis for the different functional properties of central and effector memory subsets. We show that TEM and TEMRA cells strongly express genes with known importance in CD8 T cell effector function. In contrast, TCM are characterized by high basal and cytokine-induced STAT5 phosphorylation, reflecting their capacity for self-renewal. Altogether, our results distinguish TCM and TEM/TEMRA at the molecular level and are consistent with the concept that TCM represent memory stem cells.

Project description:Generating mouse model with predominant naïve or innate memory phenotype CD4+ T cells

Project description:The therapeutic use of regulatory T cells (Tregs) in patients with autoimmune disorders has been hampered by the biological variability of memory Treg populations in the peripheral blood. In this study, we reveal through a combination of quantitative proteomic, multiparametric flow cytometry, RNA-seq data analysis and functional assays, that CD49f is heterogeneously expressed among human Tregs and impacts their immunomodulatory function. High expression of CD49f defines a subset of dysfunctional Tregs in the human blood characterized by a Th17-like phenotype and impaired suppressive capacity. CD49f is similarly distributed between naïve and memory Tregs and impacts the expression of CD39, CTLA-4, FoxP3 and CCR6 specifically in the memory compartment. Accumulation of CD49f high memory Tregs in the blood of ulcerative colitis patients correlates with disease severity. Our results highlight important considerations for Treg immunotherapy design in patients with inflammatory bowel disease which could possibly extend to other autoimmune disorders.

Project description:Effector cells for adoptive immunotherapy can be generated by in vitro stimulation of naïve or memory subsets of CD8+ T cells. While the characteristics of CD8+ T cell subsets are well defined, the heritable influence of those populations on their effector cell progeny is not well understood. We studied effector cells generated from naïve or central memory CD8+ T cells and found that they retained distinct gene expression signatures and developmental programs. Effector cells derived from central memory cells tended to retain their CD62L+ phenotype, but also to acquire KLRG1, an indicator of cellular senescence. In contrast, the effector cell progeny of naïve cells displayed reduced terminal differentiation, and, following infusion, they displayed greater expansion, cytokine production, and tumor destruction. These data indicate that effector cells retain a gene expression imprint conferred by their naïve or central memory progenitors, and they suggest a strategy for enhancing cancer immunotherapy.

Project description:Naïve and activated T-cells has a different response to antigenic challenge. We examine whether a cytokine like IL-6 induces different responses through the Jak-STAT pathway to affect the functional characteristics of a given CD4 T‑cell subset. We isolated naïve and effector memory (Tem) CD4 T-cells to investigated STAT1 and STAT3 binding after 1-hour treatment with 20ng/ml IL-6 in the presence of anti-CD3/CD28.

Project description:Memory T cells mount an accelerated response upon antigen re-challenge but are heterogeneous in phenotype and function. Therefore, traditionally memory T cells were classified into central memory (TCM), effector memory (TEM) and terminally differentiated effector memory (TEMRA) cells based on the expression of lymph node homing receptors and CD45 splice variants. However, findings on functional heterogeneity even within these subsets demonstrated the need for more suitable markers to match phenotype and function during T cell differentiation. To improve functional classification of human CD4+ memory T cells we applied bulk and single gene expression profiling and identified a set of surface markers, KLRB1, KLRG1, GPR56 and KLRF1, which facilitate classification into subsets with “low”, “high” or “exhausted” cytokine production. Highest level production of multiple cytokines was observed in T cells co-expressing KLRB1 with KLRG1 and/or GPR56 while additional KLRF1 expression was associated with a decline in cytokine production. The superiority of using KLRF1 expression to define exhausted cytokine producers compared to classical TEMRA identification was best exemplified for intrahepatic T cells in patients with inflammatory liver diseases. These data open up new opportunities for monitoring and treatment of chronic inflammatory diseases driven by cytokine producing CD4+ memory T cells.

Project description:The events controlling transition of T cells from effector to memory remain poorly understood. Herein, we defined two types of effectors on the basis of cell division, expression of activation markers and production of effector cytokines and investigated their potential for memory generation. The results indicated that the moderately activated early effectors readily transit to memory while highly activated late effectors develop minimal memory. Boosting with antigen-free adjuvant, however, rescues the late effectors from cell death and sustains both survival and cytokine responses through toll-like receptor function. Also, the genome-wide microarray analysis among early and late effectors pointed to a set og defined as well as less known genes that may play a role in transition to memory. CFSE-labeled DO11.10 CD4 naïve T cells were transferred into Balb/c mice and the hosts were immunized with OVA peptide in CFA. Within 3 days, the lymph node cells were harvested and each effector division (from division 2 to 8) was sorted based on CFSE dilution and then they were either transferred into naive hosts to generate memory cells or their RNAs were extracted to perform genome-wide microarray analysis. To correlate gene expression with memory potential, division 4 (D4), which readily transit to memory, and divisions 3 (D3), 6 (D6) and 8 (D8), which display reduced potential for memory transition, were included. The data were derived from 3 independent experiments (3 samples per division, 12 samples total).

Project description:Profiling of miRNA transcriptome in Human mature B cells from similar populations Profiling of miRNA transcriptome in Human Normal and Malignant B cells, 8 normal samples corresponding to Naïve, Germinal Center, Plasma and Memory B cells and 23 samples derived from B cell malignancy

Project description:An early-differentiated CD8+ memory T cell subset with stem cell-like properties (TSCM) can be identified within the naïve-like T cell population by the expression of CD95/Fas. Based on experiments including exon- and gene-level expression analysis, we provide evidence that this subset of antigen-specific cells represents an early precursor of conventional central (TCM) and effector (TEM) memory CD8+ T cells with enhanced self-renewal capacity and proliferative potential. We identified 900 genes differentially expressed between major T cell subsets defined along with memory T cell commitment. Based on the analysis of these genes, CD95+ naïve T cells (TSCM) cluster closer to the CD8+ T memory compartment than to classical (CD95-) naïve T (TN) cells, and display an intermittent phenotype between classical TN and TCM cells in terms of all major T cell differentiation markers analyzed. Three healthy human blood donors provided lymphocyte-enriched apheresis blood for this study after informed consent. From all samples, total RNA was isolated using an RNEasy Micro kit (Qiagen), processed by Ambion’s WT expression kit, fragmented and labeled with a WT Terminal Labeling Kit (Affymetrix), hybridized to WT Human Gene 1.0 ST arrays (Affymetrix) and stained on a Genechip Fluidics Station 450 (Affymetrix), all according to the respective manufacturer's instructions. Samples represent "exon-level" and "gene-level" analyses.