Project description:Naïve T cells respond to antigen stimulation by exiting from quiescence into clonal expansion and functional differentiation, but the control mechanism is elusive. Here we describe that Raptor/mTORC1-dependent metabolic reprogramming is a central determinant of this transitional process. Loss of Raptor abrogates T cell priming and Th2 cell differentiation, although Raptor function is less important for continuous proliferation of actively cycling cells. mTORC1 coordinates multiple metabolic programs in T cells including glycolysis, lipid synthesis and oxidative phosphorylation to mediate antigen-triggered exit from quiescence. mTORC1 further links glucose metabolism to the initiation of Th2 differentiation by orchestrating cytokine receptor expression and cytokine responsiveness. Activation of Raptor/mTORC1 integrates T cell receptor (TCR) and CD28 co-stimulatory signals in antigen-stimulated T cells. Our studies identify a Raptor/mTORC1-dependent pathway linking signal-dependent metabolic reprogramming to quiescence exit, and this in turn coordinates lymphocyte activation and fate decisions in adaptive immunity. We used microarrays to explore the gene expression profiles differentially expressed in CD4+ T-cells from wild-type (WT) and CD4(cre) x Raptor(fl/fl) mice before and after stimulation with anti CD3/CD28 antibodies.

Project description:The mechanisms that regulate T cell quiescence are poorly understood. We report that tuberous sclerosis complex 1 (Tsc1) establishes a quiescent program in naïve T cells by controlling cell size, cell cycle entry, and responses to T cell receptor stimulation. Loss of quiescence predisposed Tsc1-deficient T cells to apoptosis that depleted conventional T cells and invariant natural killer T cells. Loss of Tsc1 function dampened in vivo immune responses to bacterial infection. Tsc1-deficient T cells exhibited increased mTORC1 but diminished mTORC2 activities, with mTORC1 activation essential for the disruption of immune homeostasis. Therefore, Tsc1-dependent control of mTOR is crucial in establishing naïve T cell quiescence to facilitate adaptive immune function.

Project description:The underlying mechanisms by which naïve T cells exit from quiescence after antigen stimulation remain elusive. Using multiplex isobaric labeling proteomics technology, we report unbiased, temporal profiling of whole proteome and phosphoproteome during the activation in the wild type and Rptor-/- T cells. TCR stimulation results in dynamic reprogramming of the proteome and phosphoproteome, with predominant upregulation of molecular machineries in protein translation and mitochondrial activation. Loss of mTORC1 disrupts TCR-induced mitochondrial functions including mitoribosome biogenesis, one-carbon metabolism and oxidative phosphorylation.

Project description:The underlying mechanisms by which naïve T cells exit from quiescence after antigen stimulation remain elusive. Using multiplex isobaric labeling proteomics technology, we report unbiased, temporal profiling of whole proteome (>8,000 proteins) and phosphoproteome (>13,000 phosphopeptides) during the activation in the wild type and Rptor-/- T cells. TCR stimulation results in dynamic reprogramming of the proteome and phosphoproteome, with predominant upregulation of molecular machineries in protein translation and mitochondrial activation. Loss of mTORC1 disrupts TCR-induced mitochondrial functions including mitoribosome biogenesis, one-carbon metabolism and oxidative phosphorylation.

Project description:Gene expression changes when naïve T-cells are stimulated with antigen. We have stimulated these cells with surrogate antigens (aCD3-aCD28 coated beads) for 48 hours, and then did microarray experiment to identify differentially exprssed genes in the two conditions CD4 naïve T-cells from C57/Bl6 mouse were stimulated (activated) with aCD3-aCD28 coated beads for 48 hours and used for microarray experiment

Project description:High-resolution quantitative mass-spectrometry reveals similarities and disparities in how murine naïve CD4 and CD8 T cells respond to immune activation and re-structure proteomes as they differentiate to effector cells. The data map core transcriptional, metabolic and protein synthesis machinery, nutrient transporters and environment sensing molecules and reveal differences in the biosynthetic capacity of CD4 and CD8 T cells. One key nutrient sensing kinase is mammalian target of rapamycin complex1 (mTORC1). The current study identifies common and distinct mTORC1 regulated processes and divergent outcomes of mTORC1 inhibition in naïve versus effector CD4 and CD8 T cell populations. The data provide a resource that maps how immune activation and mTORC1 reshape CD4 and CD8 T cell proteomes and highlights that a deep understanding of T cell phenotype requires modelling of the impact of immune regulators on protein copy number, cellular protein concentrations and the subunit stoichiometry of key protein complexes.

Project description:Regulatory T cells (Treg) prevent the emergence of autoimmune disease. Prototypic natural Treg (nTreg) are programmed by Forkhead-box P3 (FOXP3) and can be reliably identified by demethylation at the FOXP3 locus. To explore the nTreg methylation landscape we performed genome-wide methylation studies on human naïve resting nTreg (rTreg) and conventional naïve CD4+ T cells (Naïve). We detected 2,315 differentially methylated CpGs between these two cell types, many of which clustered into 127 regions of differential methylation (RDMs). T cell activation induced changes in 466 individual CpGs and 18 RDMs in naïve CD4+ T cells, but did not alter DNA methylation in rTreg. Expression of mRNA for TIGIT, an immune suppressive receptor demethylated in rTreg, was upregulated in nTreg and reduced in peripheral blood mononuclear cells of individuals at risk for autoimmune (type 1) diabetes. Gene-set testing of the 127 RDMs revealed enrichment of common Treg signature genes, FOXP3 bound genes and genes directly upregulated by FOXP3, which was primarily driven by the subset of demethylated RDMs. A putative Forkhead-binding motif overrepresented in promoter-associated RDMs suggests methylation regulates gene expression by influencing FOXP3 binding. Our findings provide new insights into epigenetic regulation of human nTreg and the potential to exploit differential methylation as an immune biomarker in human diseases. Naïve and rTreg cells were sorted from buffy coats of 3 healthy male donors (M28, 29, 30) and then activated for 6 days with anti-CD3 and anti-CD28 antibodies, supplemented with IL-2 at day 4. DNA was harvested and bisulfite converted for methylation analysis on illumina HM450 array from 2-3 biological replicates of each cell type: rTreg (M28, M30), naïve (M28, M29, M30), Act-naïve (M28, M29, M30) and Act-rTreg (M29, M30).

Project description:Memory T cells are primed for rapid responses to antigen; however, the molecular mechanisms responsible for priming remain incompletely defined. CpG methylation in promoters is an epigenetic modification, which regulates gene transcription. Using targeted bisulfite sequencing, we examined methylation of 2100 genes (56,000 CpG) mapped by deep sequencing to T cell activation in human naïve and memory CD4 T cells. 466 CpGs (132 genes) displayed differential methylation between naïve and memory cells. 21 genes exhibited both differential methylation and gene expression before activation, linking promoter DNA methylation states to gene regulation; 6 genes encode proteins closely studied in T cells while 15 genes represent novel targets for further study. 39 genes exhibited reduced methylation in memory cells coupled with increased gene expression with activation compared to naïve cells, revealing specific genes more rapidly expressed in memory compared to naïve cells and potentially regulated by DNA methylation. These findings define a DNA methylation signature unique to memory CD4 T cells and correlated with activation-induced gene expression. transcriptome of primary human naïve and memory CD4 T cells at rest and 48 hours post-activation.

Project description:Memory T cells are primed for rapid responses to antigen; however, the molecular mechanisms responsible for priming remain incompletely defined. CpG methylation in promoters is an epigenetic modification, which regulates gene transcription. Using targeted bisulfite sequencing, we examined methylation of 2100 genes (56,000 CpG) mapped by deep sequencing to T cell activation in human naïve and memory CD4 T cells. 466 CpGs (132 genes) displayed differential methylation between naïve and memory cells. 21 genes exhibited both differential methylation and gene expression before activation, linking promoter DNA methylation states to gene regulation; 6 genes encode proteins closely studied in T cells while 15 genes represent novel targets for further study. 39 genes exhibited reduced methylation in memory cells coupled with increased gene expression with activation compared to naïve cells, revealing specific genes more rapidly expressed in memory compared to naïve cells and potentially regulated by DNA methylation. These findings define a DNA methylation signature unique to memory CD4 T cells and correlated with activation-induced gene expression. RNA sequencing of primary human naïve and memory CD4 T cells at rest and 48 hours post-activation.

Project description:To test whether human in vitro primed Th9 cells recapitulate the core pathogenic Th2 cell phenotype, we differentiated naïve T cells into Th1 (IL-12), Th2 (IL-4), Th9 (IL-4+TGF-β), and iTreg (TGF-β). After 7 days transcriptomic profiling by bulk RNA-seq was performed.