Project description:The physiological function of the immune system and the response to therapeutic immunomodulators may be sensitive to combinatorial cytokine micro-environments that shape the responses of specific immune cells. Previous work shows that paracrine cytokines released by virus-infected human dendritic cells (DC) can dictate the maturation state of naïve DCs. To understand the effects of paracrine signaling, we systematically studied the effects of combinations cytokines in this complex mixture in generating an antiviral state. After naïve DCs were exposed to either IFNβ or to paracrine signaling released by DCs infected by Newcastle Disease Virus (NDV), microarray analysis revealed a large number of genes that were differently regulated by the DC-secreted paracrine signaling. In order to identify the cytokine mechanisms involved, we identified 20 cytokines secreted by NDV infected DCs for which the corresponding receptor gene is expressed in naïve DCs. By exposing cells to all combinations of 19 cytokines (leave-one-out studies) we identified 5 cytokines (IFNβ, TNFα, IL-1, TNFSF15 and IL28) as candidates for regulating DC maturation markers. Subsequent experiments identified IFNβ, TNFα and IL1 as the major synergistic contributors to this antiviral state. This finding was supported by infection studies in vitro, by T cell activation studies and by in vivo infection studies in mouse. Combination of cytokines can cause response states in DCs that differ from those achieved by the individual cytokines alone. These results suggest that the cytokine microenvironment may act via a combinatorial code to direct the response state of specific immune cells. Further elucidation of this code may provide insight into responses to infection and neoplasia as well as guide the development of combinatorial cytokine immunomodulation for infectious, autoimmune and immunosurveillance-related diseases.

Project description:A microarray study performed in iTreg of miR-31fl/fl/CD4Cre and control mice to identify genes that are regulated by the miR-31. CD4+ naM-CM-/ve T cells from miR-31fl/fl mice and miR-31fl/flCD4Cre mice were used to induce iTreg in vitro. Four independent experiments were performed. MiR-31fl/fl/CD4Cre mice (6 wk old) and age-matched control mice were sacrificed, and the spleen were removed and teased into cell-single suspensions and filtered through a 40 M-NM-<m cell strainer. NaM-CM-/ve CD4+CD25-Foxp3gfp-CD62Lhi T cells were sorted by FACSAria III (BD bioscience).The medium used for T cell cultures was RPMI-1640 (Gibco) supplemented with 10% heat-inactivated FBS (Gibco), 2 mM L-glutamine (Gibco), 100 U/ml penicillin, 100 M-NM-<g/ml streptomycin, and 5 mM M-NM-2-mercaptoethanol (Gibco). The CD4+ NaM-CM-/ve T cells were stimulated with plate-bound anti-CD3 (5 M-NM-<g/ml) plus soluble anti-CD28 (2 M-NM-<g/ml) under iTreg cell differentiation conditions (mTGF-M-NM-21, 5 ng/ml and rmIL-2, 40 ng/ml; R&D Systems). After 4 days, harvested cell ,the RNA was extracted in Trizol and then purified using the miRNeasy Micro Kit (Qiagen). This submission shows the data obtained from 3 individual miR-31fl/fl/CD4Cre mice mice measured against 3 control mice.

Project description:Psoriasis and atopic dermatitis (AD) are characterized by polarized CD4+ T cell responses. During the polarization of naM-CM-/ve CD4+ T cells, DNA methylation plays an important role in the regulation of gene transcription. In this study, we profiled the genome-wide DNA methylation status of naM-CM-/ve CD4+ T cells in patients with psoriasis or AD and healthy controls using a ChIP-seq method. As a result, twenty-six regions in the genome ranging in size from 10 to 70 kb were markedly hypomethylated in patients with psoriasis. These regions were mostly pericentromeric on 10 different chromosomes and overlapped with various strong epigenomic signals, such as histone modifications and transcription factor binding sites, that were observed in the ENCODE project. Gene-centric analysis indicated that the promoter regions of 124 genes on the X chromosome had dramatically elevated methylation levels in patients with psoriasis as compared to those from healthy controls (> 4-fold). Moreover, immune-related genes on the X chromosome had higher hypermethylation than other genes (P < 0.05). These findings imply that methylation changes in naM-CM-/ve CD4+ T cells may affect CD4+ T cell polarization, especially in the pathogenesis of psoriasis. Keywords: Psoriasis, Atopic dermatitis, DNA methylation, naM-CM-/ve CD4+ T cells Sample submission examines DNA methylation from human naive CD4+ T cells in patients with psoriasis and atopic dermatitis. Note: Raw data available only for Sample GSM871288.

Project description:NaM-CM-/ve, liver- and gut-activated CD8 OT-I T cells show differential migration behaviour. To analyze which genes could be responsible for different migration patterns, naM-CM-/ve, liver-activated and gut-activated CD8 T cells were isolated and compared for their gene expression profile. Gene expression profiles of naM-CM-/ve CD8 OT-I T cells versus liver-activated T cells and gut-activated T cells, respectively. NaM-CM-/ve CD8 OT-I T cells were isolated from lymph nodes and spleens of OT-I mice. CD8 OT-I T cells activated by liver-derived and gut-derived antigen for three days in vivo, positive for CFSE were sorted from livers of TF-OVA mice or from mesenteric lymph nodes of iFABP-OVA mice. After total RNA extraction, reverse transcription, cDNA extraction, the biotinylated cRNA was transcribed, fragmented, and 15 M-BM-5g cRNA hybridized in duplicates for each of the three groups to the GeneChip arrays. Group1: naM-CM-/ve, Group2: liver-activated Group3: gut-activated. Lists of differentially regulated genes were created using High Performance Chip Data Analysis (HPCDA) with Bioretis database (http://www.bioretis-analysis.de). Worldwide data sharing is possible via Bioretis, please ask the authors.

Project description:In this study we identify Mettl3, an m6A RNA modification writer, as a critical regulator for terminating naM-CM-/ve pluripotency and a positive maintainer of primed pluripotency in vitro and in vivo. Remarkably, Mettl3 knockout pre-implantation epiblasts and naM-CM-/ve ES cells, entirely lack m6A on coding mRNAs and are viable. Yet, they fail to adequately terminate the naM-CM-/ve pluripotent state, and subsequently undergo aberrant priming and early lineage commitment at the post-implantation stage. A comprehensive functional and genomic analysis involving profiling of m6A, RNA transcription and translation in Mettl3 wild-type and knockout pluripotent and differentiated cells, identified m6A as a critical determinant that destabilizes secondary naM-CM-/ve specific pluripotency genes Esrrb, Klf4 and Nanog, and restrains their transcript stability and translation efficiency. In summary, our findings provide for the first time evidence for a critical role for an mRNA epigenetic modification in early mammalian development in vivo, and identify a mechanism that functionally regulates mouse naM-CM-/ve and primed pluripotency in an opposing manner. m6A-seq was measured from total RNA in mouse embryonic stem cells (ESCs), embroid bodies (EBs) and embronic fibroblasts (MEF). 3 biological replicates are available from BVSC ESC line and EBs, and two biological replicates are available for MEFs. Each sample consist of IP to m6A and control input

Project description:Senescence can be transmitted in a paracrine way from cells undergoing Oncogene Induced Senescence (OIS) to naM-CM-/ve normal cells. We define this phenomenon as M-bM-^@M-^\paracrine senescenceM-bM-^@M-^] We used microarrays to compare the trancriptome of cells undergoing paracrine senescence to the transcriptome of cells suffering OIS to unveil the common signatures defining both events and the similarities between them IMR90 cells were co-cultured with IMR90 ER:RAS undergoing OIS or IMR90-Vector control cells using 0.2 M-NM-<m pore transwell (anopore) to allow communication of soluble factors but physical separation of the two cell populations. The total mRNA of IMR90, IMR90 ER:RAS or IMR90 cells cultured in Transwells together with IMR90 vector or IMR90 ER:RAS cells during 7 days in the presence of 200 nM 4OHT and 0.5 % FBS was extracted and hybridized on Affymetrix microarrays to compare paracrine senescence to OIS.

Project description:The dendritic cell (DC) is a master regulator of immune responses. Pathogenic viruses subvert normal immune function in DCs through the expression of immune antagonists. Understanding how these antagonists interact with the host immune system requires knowledge of the underlying genetic regulatory network that operates during an uninhibited antiviral response. In order to isolate and identify this network, we studied DCs infected with Newcastle Disease Virus (NDV), which is able to stimulate innate immunity and DC maturation through activation of RIG-I signaling, but lacks the ability to evade the human interferon response. To analyze this experimental model, we developed a new approach integrating genome-wide expression kinetics and time-dependent promoter analysis. We found that the genetic program underlying the antiviral cell state transition during the first 18-hours post-infection could be explained by a single regulatory network. Gene expression changes were driven by a step-wise multi-factor cascading control mechanism, where the specific transcription factors controlling expression changed over time. Within this network, most individual genes are regulated by multiple factors, indicating robustness against virus-encoded immune evasion genes. In addition to effectively recapitulating current biological knowledge, we predicted, and validated experimentally, antiviral roles for several novel transcription factors. More generally, our results show how a genetic program can be temporally controlled through a single regulatory network to achieve the large-scale genetic reprogramming characteristic of cell state transitions. Total RNA from Monocyte-derived conventional DCs of 2 different donors were infected with Newcastle disease virus (NDV) or as control with allantoic fluid (AF) alon. DC were then harvested at : 0, 1, 2, 6, 10 and 18 hour for control and 1, 2, 4, 6, 8, 10, 12, 14, 16 and 18 hours for NDV infection. Replicates were performed for each of the donors at all timepoints.

Project description:BALB/c mice develop peripheral arthritis (PGIA) and spondyloarthropathy (PGIS) upon repeated intraperitoneal injections of human cartilage proteoglycan (PG) aggrecan. The aim of the present study was to identify spondylitis-specific genes by comparing intervertebral disc (IVD) RNA samples from spondyloarthropathic and naM-CM-/ve BALB/c mice. Keywords: Genetic modification We compared the gene expression data of 5 spondyloarthropathic and 3 naM-CM-/ve (control) mice.

Project description:Global gene expression profile of Tet1 knocout cortex or hippocampus is compared to wild-type cortex or hippocampus. All mice used are naM-CM-/ve and of mixed 129 C57BL6 backgound. Tet1 KO in brain cortex and hippocampus

Project description:Memory T cells respond to stimulation with more rapid expression of effector cell functions than their naM-CM-/ve counterparts, yet the gene expression signature underlying this enhanced recall response is not known. Therefore, we performed comprehensive, whole-genome expression profiling of murine memory CD8 T cells before and shortly after ex vivo stimulation. We compared this differential expression profile to its counterpart from stimulated naive cells. Given that memory cells arise from naive cells, the quiescent state of both cell populations prior to stimulation, and the early time point analyzed (four hours post-stimulation), it was possible that the stimulation-induced changes in gene expression were identical between the two populations. While there was a high degree of overlap, we found that the majority of up-regulated genes were more highly induced following stimulation of memory cells. This more robust increase in transcript levels was observed for a functionally diverse set of genes, including cytokines, chemokines, amino acid metabolic enzymes and transporters, transcription factors and regulators of RNA processing. We also identified the unique, stimulation-induced signatures of naive and memory CD8 T cells and found that the former was enriched for factors involved in regulating chromatin modifications. Specifically, we found that Hdac 5,7 and 8 transcript levels were rapidly down-regulated following stimulation of naive cells, which correlated with an increase in their total level of acetylated histone H3 (AcH3). This was in contrast to stimulated memory cells, which had higher levels of total AcH3 ex vivo that did not change following short-term stimulation. Furthermore, the unique stimulation-induced expression profile of memory cells was enriched for factors involved in regulating transport of molecules between the nucleus and cytoplasm, including multiple members of the nuclear pore complex. Together, these results support a model whereby the chromatin modifications that occur during the differentiation of naM-CM-/ve cells into memory cells are preserved in resting memory populations, facilitating their more robust re-activation of a functionally diverse set of genes that contribute to rapid recall of effector functions. NaM-CM-/ve (CD44lo) and memory phenotype (CD44hi) CD8 T cells from 7-wk old female B6 mice were FACS-purified and cultured in vitro for four hours in the presence or absence of PMA and ionomycin. Total RNA was purified from un-stimulated (resting) naM-CM-/ve, resting memory, stimulated naive, and stimulated memory cells and hybridized to individual single-color arrays. This purification and stimulation protocol was performed four independent times.