Project description:RNA-sequencing of in vitro differentiated T cells cultured with varying cytokine conditions: IL-12, IL-12+IL-21, IL-1b+IL-6+IL-23, and TGFb+IL-6
Project description:Using an experimental model of graft versus host disease (GVHD) to examine T cell-mediated inflammation within the colon, we identified a unique CD4+ T cell population that constitutively expresses the β2 integrin, CD11c, has a biased central memory phenotype and memory T cell transcriptional profile, possesses innate-like properties by gene expression analysis, and has increased expression of the gut-homing molecules, α4β7 and CCR9. Using a number of complementary GVHD mouse models, we show that adoptive transfer of these cells results in TH1-mediated proinflammatory cytokine production, augmented pathological damage in the colon, and increased mortality due to early accumulation of these cells in the GI tract. The pathogenic effects of this CD4+ T cell population was critically dependent upon co-expression of the IL-23 receptor which was required for maximal inflammatory effects. Colonic inflammation was regulated by IL-10 that was produced by non-Foxp3-expressing CD4+ T cells which attenuated lethality in the absence of functional CD4+ Foxp3+ T cells. Thus, coordinate expression of CD11c and the IL-23R defines a novel IL-10 regulated, colitogenic memory CD4+ T cell subset that is poised to initiate inflammation when there is loss of tolerance and breakdown of mucosal barriers as occurs in GVHD as well as other immune-mediated inflammatory bowel disorders.
Project description:Single-cell RNA-sequencing of in vitro differentiated T cells cultured with IL-12+IL-21+IL-23 (Th1 cell condition) or IL-1b+IL-6+IL-23 (pathogenic Th17 cell condition)
Project description:Th1 cells were adoptively transferred into RAG1 KO mice from either wildtype (Il23rwt/eGFP) or KO (Il23reGFP/eGFP) donors. At the peak of disease in recipients of wildtype cells, the animals were euthanized and intestinal T cells were isolated from the chosen recipients of both wildtype and KO cells for 10x massively parallel single-cell RNA-sequencing.
Project description:We found that IL-23R mediated HeLa cell apoptosis by characterizing the functional domains responsible for this event. For exploring apoptotic pathways activated by IL-23R, the altered transcriptomic profiles in responding to IL-23R over-expression was also revealed by RNAseq analysis.
Project description:Carbo2013 - Cytokine driven CD4+ T Cell differentiation and phenotype plasticity
CD4+ T cells can differentiate into different phenotypes
depending on the cytokine milieu. Here a computational and mathematical model with sixty ordinary differential equations representing a CD4+ T cell differentiating into either Th1, Th2, Th17 or iTreg cells, has been constructed.
The model includes cytokines,
nuclear receptors and transcription factors that define fate
and function of CD4+ T cells. Computational simulations
illustrate how a proinflammatory Th17 cell can undergo
reprogramming into an anti-inflammatory iTreg phenotype
following PPARc activation.
This model is described in the article:
Systems Modeling of Molecular Mechanisms Controlling Cytokine-driven CD4+ T Cell Differentiation and Phenotype Plasticity.
Carbo A, Hontecillas R, Kronsteiner B, Viladomiu M, Pedragosa M, Lu P, Philipson CW, Hoops S, Marathe M, Eubank S, Bisset K, Wendelsdorf K, Jarrah A, Mei Y, Bassaganya-Riera J
PLoS Computational Biology [2013, 9(4):e1003027]
Abstract:
Differentiation of CD4+ T cells into effector or regulatory phenotypes is tightly controlled by the cytokine milieu, complex intracellular signaling networks and numerous transcriptional regulators. We combined experimental approaches and computational modeling to investigate the mechanisms controlling differentiation and plasticity of CD4+ T cells in the gut of mice. Our computational model encompasses the major intracellular pathways involved in CD4+ T cell differentiation into T helper 1 (Th1), Th2, Th17 and induced regulatory T cells (iTreg). Our modeling efforts predicted a critical role for peroxisome proliferator-activated receptor gamma (PPARγ) in modulating plasticity between Th17 and iTreg cells. PPARγ regulates differentiation, activation and cytokine production, thereby controlling the induction of effector and regulatory responses, and is a promising therapeutic target for dysregulated immune responses and inflammation. Our modeling efforts predict that following PPARγ activation, Th17 cells undergo phenotype switch and become iTreg cells. This prediction was validated by results of adoptive transfer studies showing an increase of colonic iTreg and a decrease of Th17 cells in the gut mucosa of mice with colitis following pharmacological activation of PPARγ. Deletion of PPARγ in CD4+ T cells impaired mucosal iTreg and enhanced colitogenic Th17 responses in mice with CD4+ T cell-induced colitis. Thus, for the first time we provide novel molecular evidence in vivo demonstrating that PPARγ in addition to regulating CD4+ T cell differentiation also plays a major role controlling Th17 and iTreg plasticity in the gut mucosa.
Author's comment:
CD4+ T cell computational model (Version 1.4)
Steady state corrected. There was a problem in the internalization of IL-17 in its mathematical function.
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by: MODEL1304230001
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