Project description:CD4+ T cells are critical components in the human immune system. They produce cytokines to fight against pathogens and abnormal cells and stimulate other cells, such as B cells, macrophages, and neutrophils, to generate an immune response. Naive CD4+ T cells are precursor cells that can differentiate into T helper - 1, - 2, - 17 (Th1, Th2, Th17) and regulatory T cells (Tregs) subtypes based on the type of pathogens or disease. The naive CD4+ T cell model consists of 5179 reactions, 3153 metabolites, and 1055 genes. Together with Th1, Th2, and Th17 models, the naive CD4+ T cell model helped identify drug targets and repurposable drugs against autoimmune diseases.

Project description:CD4+ T cells are critical components in the human immune system. They produce cytokines to fight against pathogens and abnormal cells and stimulate other cells, such as B cells, macrophages, and neutrophils, to generate an immune response. T helper 2 (Th2) cells are subtype CD4+ T cells that differentiate from naive CD4+ T cells in a specific cytokine environment. The Th2 cell model consists of 5252 reactions, 3156 metabolites, and 1127 genes. CD4+ T cell models helped identify drug targets and repurposable drugs against autoimmune diseases.

Project description:CD4+ T cells are critical components in the human immune system. They produce cytokines to fight against pathogens and abnormal cells and stimulate other cells, such as B cells, macrophages, and neutrophils, to generate an immune response. T helper 1 (Th1) cells are subtypes of CD4+ T cells that differentiate from naive CD4+ T cells in a specific cytokine environment. The Th1 cell model consists of 3956 reactions, 2517 metabolites, and 1133 genes. CD4+ T cell models helped identify drug targets and repurposable drugs against autoimmune diseases.

Project description:Th17 cells are believed to be a critical cell population for driving autoimmune diseases. However, environmental factors that are directly related to the development of Th17 cells are largely unknown. High-salt (NaCl) concentrations enhance Th17 differentiation of human naive CD4+ T cells in vitro. The aim of the study was to analyse the changes in gene expression induced by high-salt conditions during Th17 differentiation. Naive human CD4+ T cells were in vitro differentiated into Th17 cells in the presence or absence of high-salt. We arrayed 2 different donors for each condition (control & high-salt).

Project description:In this study we determined whole genome gene expression of murine naive CD4+ T cells, in vitro differentiated Th17 cells, and CD4+ T cells isolated from experimental autoimmune encephalitomyelitis (EAE)-affected animals either after adoptive transfer of Th17 cells or after immunization with MOG35-55-peptide. The overall goal was to identify candidate genes involved in T cell pathology, encephalitogenicity and plasticity. These findings could then be correlated to multiple sclerosis pathology. Naive CD4+ T cells were isolated from B6.2d2 transgenic mice with MOG-specific T cell receptors and differentiated in vitro into Th17 cells. These Th17 cells were adoptively transferred into lymphopenic RAG1-/- mice to induce EAE. Further, EAE was induced by immunizing wild-type C57BL/6 mice with MOG35-55 peptide. RNA was extracted from naive CD4+ T cells, Th17 cells, and from CD4+ T cells isolated from the CNS of EAE-affected mice for gene expression analysis. Replicates from three independent experiments were analyzed.

Project description:<p>We use next generation sequencing to investigate the different transcriptomes of closely related CD4+ T-cells from healthy human donors to elucidate the genetic programs that underlie their specialized immune functions. Six cell types were included: Regulatory T-cells (CD25hiCD127low/neg with &#62;95% FOXP3+ purity), regulatory T-cells activated using PMA/ionomycin, CD25-CD45RA+ (&#39;naive&#39; helper T-cells), CD25-CD45RO+ (&#39;memory&#39; helper T-cells), activated Th17 cells (&#62;98% IL17A+ purity) and activated IL17-CD4+ T-cells (called &#39;ThPI&#39;). Poly-T capture beads were used to isolate mRNA from total RNA, and fragment sizes of ~200 were sequenced from both ends on Illumina&#39;s genome analyzer. We confirm many of the canonical signature genes of T-cell populations, but also discover new genes whose expression is limited to specific CD4 T-cell lineages, including long non-coding RNAs. Additionally, we find that genes encoded at loci linked to multiple human autoimmune diseases are enriched for preferential expression upon T-cell activation, suggesting that an aberrant response to T-cell activation is fundamental to pathogenesis.</p>

Project description:We compared the methylated and non-methylated regions in the genome of ex vivo-isolated naive CD4+ T cells, Th1 cells, Th17 cells and regulatory T cells by methyl-CpG binding domain protein sequencing (MBD-seq). Naive T cells and Th1 cells share more methylated regions than naive T cells and Th17 cells or Th1 and Th17 cells. However, analysis of the non-methylated regions revealed the highest similarity between Th1 and Th17 cells. Another aim was the analysis of the Th17 lineage on the basis of the methylome. We searched for regions absent in the methylome of Th17 but present in naive T cells, Th1 cells and regulatory T cells. Here, we identified differential methylation in the loci of Il17a, Chn2, Dpp4 and Dclk1. CD4+ T effector cells were prepared ex vivo, stimulated with PMA/Ionomycin, subjected to a comercially available cytokine secretion kit (IL-17A and IFNg), stained by adding fluorescence-labeled antibodies against CD3, CD4 and CD45RB and sorted by flow cytometry. We sorted naive CD4+ T cells (CD3+CD4+CD45RB_high), Th1 cells (CD3+CD4+CD45RB_low_IFNg+IL17A-), Th17 cells (CD3+CD4+CD45RB_low_IFNg-IL17A+) and regulatory T cells (CD3+CD4+CD25++).

Project description:In this study, we examined differential gene expression in naïve human CD4+ T cells, as well as in effector Th1, Th17-negative and Th17-enriched CD4- T cell subsets. We observed a marked enrichment for increased gene expression in effector CD4+ T cells compared to naive CD4+ among immune-mediated disease oci genes. Within effector T cells, expression of disease-associated genes was increased in Th17-enriched compared to Th17-negative cells. We used microarray to examine the gene expresssion profile and level of human naïve, Th1 and effector T cell subsets. Human PBMCs were isolated and sorted to naïve, CD161-CCR6- and CD161+CCR6+ memory T cells. Naïve T cells were differentiatied to Th1 cells, and CD161-CCR6- and CD161+CCR6+ memory T cells were in vitro expanded for Th17-negative and Th17-enriched effector T cells. The gene profile was compared among naive, Th1, Th17-negative, and Th17-enriched cell subsets.

Project description:Foxp3 is indispensable for Treg suppressive function, but the stability of Foxp3 has been controversial. In autoimmune arthritis, Th17 cells play a critically important pathological role, but the origin of Th17 cells remains unknown We used microarrays to detail the global programme of gene expression of Th17 cells originated from Foxp3+T cells compared to conventional naive CD4+T cells derived Th17 cells. We also take samples of Treg cells and Th0 cells for the experimetnatl control. Each T cell subset after the culture was subjected to RNA extraction and hybridization on Affymetrix microarrays.

Project description:Interleukin (IL)-17-producing T helper (Th17) cells are crucial for host defense against extracellular microbes and pathogenesis of autoimmune diseases. Here we show that the AP-1 transcription factor JunB is required for Th17 cell development. Junb-deficient CD4+ T cells are able to develop in vitro into various helper T subsets except Th17. The RNA-seq transcriptome analysis reveals that JunB is crucial for the Th17-specific gene expression program. Junb-deficient mice are completely resistant to experimental autoimmune encephalomyelitis, a Th17-mediated inflammatory disease, and naive T helper cells from such mice fail to differentiate into Th17 cells. JunB appears to activate Th17 signature genes by forming a heterodimer with BATF, another AP-1 factor essential for Th17 differentiation. The mechanism whereby JunB controls Th17 cell development likely involves activation of the genes for the Th17 lineage-specifying orphan receptors RORt and ROR and reduced expression of Foxp3, a transcription factor known to antagonize RORt function.