Feedback control of AHR signalling regulates intestinal immunity

The aryl hydrocarbon receptor (AHR) recognizes xenobiotics as well as natural compounds such as tryptophan metabolites, dietary components and microbiota-derived factors, and it is important for maintenance of homeostasis at mucosal surfaces. AHR activation induces cytochrome P4501 (CYP1) enzymes, which oxygenate AHR ligands, leading to their metabolic clearance and detoxification. Thus, CYP1 enzymes have an important feedback role that curtails the duration of AHR signalling, but it remains unclear whether they also regulate AHR ligand availability in vivo. Here we show that dysregulated expression of Cyp1a1 in mice depletes the reservoir of natural AHR ligands, generating a quasi AHR-deficient state. Constitutive expression of Cyp1a1 throughout the body or restricted specifically to intestinal epithelial cells resulted in loss of AHR-dependent type 3 innate lymphoid cells and T helper 17 cells and increased susceptibility to enteric infection. The deleterious effects of excessive AHR ligand degradation on intestinal immune functions could be counter-balanced by increasing the intake of AHR ligands in the diet. Thus, our data indicate that intestinal epithelial cells serve as gatekeepers for the supply of AHR ligands to the host and emphasize the importance of feedback control in modulating AHR pathway activation

Identification of the cellular and molecular mechanisms of IL-23 driven intestinal inflammation

IL-23 is an essential mediator of chronic intestinal inflammation in experimental models of colitis. Polymorphisms in the IL23R locus are associated with IBD susceptibility in humans. The biological activity of IL-23 has been linked to Th17 cells but little is known about the cellular and molecular mechanism by which IL-23 drives intestinal inflammation. The work presented herein has identified that direct IL-23 signalling into CD4+ T cells was not only required for the accumulation of Th17 cells in the intestine but also modulated their phenotype. Through direct cell intrinsic effects on T cells, IL-23 drove the emergence of an IL-17A+IFN-γ+ population of T cells that co-expressed RORγ and T-bet. Interestingly, we found that expression of RORγ but not T-bet by T cells was required for the development of intestinal inflammation. Furthermore, colitis induced by T-bet deficient T cells was dependent on IL-17A, and showed a unique inflammatory phenotype, thus demonstrating that pathogenic intestinal Th17 responses can develop independently of T-bet. In addition, using transcriptional profiling we identified a core set of genes that is regulated by direct cell-intrinsic IL-23 signals into intestinal CD4+ T cells. This revealed a previously unrecognised role for IL-23 in suppressing Th2 associated genes, such as GATA3 and IL-33R. Functional experiments demonstrated that expression of GATA3 in CD4+ T cells limited their colitogenic potential, suggesting that IL-23-mediated inhibition of GATA3 might contribute to the development of intestinal inflammation. Finally, we described a novel function for IL-33 as a factor that promotes Foxp3+ iTreg differentiation in vitro and in vivo through direct effects on T cells. This activity of IL-33 was inhibited in the presence of IL-23, providing a mechanistic link for the known role of IL-23 in restraining iTreg generation. Collectively, these data suggest that IL-23 promotes acquisition of a pathogenic effector T cell phenotype through multiple mechanisms. This indicates that therapeutic blockade of IL-23 is likely to reduce pro-inflammatory mediators while also facilitating the expansion of regulatory pathways that might help to re-establish intestinal homeostasis.</p

Identification of the cellular and molecular mechanisms of IL-23 driven intestinal inflammation

IL-23 is an essential mediator of chronic intestinal inflammation in experimental models of colitis. Polymorphisms in the IL23R locus are associated with IBD susceptibility in humans. The biological activity of IL-23 has been linked to Th17 cells but little is known about the cellular and molecular mechanism by which IL-23 drives intestinal inflammation. The work presented herein has identified that direct IL-23 signalling into CD4+ T cells was not only required for the accumulation of Th17 cells in the intestine but also modulated their phenotype. Through direct cell intrinsic effects on T cells, IL-23 drove the emergence of an IL-17A+IFN-γ+ population of T cells that co-expressed RORγ and T-bet. Interestingly, we found that expression of RORγ but not T-bet by T cells was required for the development of intestinal inflammation. Furthermore, colitis induced by T-bet deficient T cells was dependent on IL-17A, and showed a unique inflammatory phenotype, thus demonstrating that pathogenic intestinal Th17 responses can develop independently of T-bet. In addition, using transcriptional profiling we identified a core set of genes that is regulated by direct cell-intrinsic IL-23 signals into intestinal CD4+ T cells. This revealed a previously unrecognised role for IL-23 in suppressing Th2 associated genes, such as GATA3 and IL-33R. Functional experiments demonstrated that expression of GATA3 in CD4+ T cells limited their colitogenic potential, suggesting that IL-23-mediated inhibition of GATA3 might contribute to the development of intestinal inflammation. Finally, we described a novel function for IL-33 as a factor that promotes Foxp3+ iTreg differentiation in vitro and in vivo through direct effects on T cells. This activity of IL-33 was inhibited in the presence of IL-23, providing a mechanistic link for the known role of IL-23 in restraining iTreg generation. Collectively, these data suggest that IL-23 promotes acquisition of a pathogenic effector T cell phenotype through multiple mechanisms. This indicates that therapeutic blockade of IL-23 is likely to reduce pro-inflammatory mediators while also facilitating the expansion of regulatory pathways that might help to re-establish intestinal homeostasis.This thesis is not currently available in ORA

Universal expression and dual function of the atypical chemokine receptor D6 on innate-like B cells in mice

Mouse innate-like B cells are a heterogeneous collection of multifunctional cells that control infection, play housekeeping roles, contribute to adaptive immunity, and suppress inflammation. We show that, among leukocytes, chemokine internalization by the D6 receptor is a unique and universal feature of all known innate-like B-cell populations and, to our knowledge, the most effective unifying marker of these cells. Moreover, we identify novel D6(active) B1-cell subsets, including those we term B1d, which lack CD5 and CD11b but exhibit typical B1-cell properties, including spontaneous ex vivo production of IgM, IL-10, and anti-phosphorylcholine antibody. The unprecedented opportunity to examine D6 on primary cells has allowed us to clarify its ligand specificity and show that, consistent with a scavenging role, D6 internalizes chemokines but cannot induce Ca2+ fluxes or chemotaxis. Unexpectedly, however, D6 can also suppress the function of CXCR5, a critical chemokine receptor in innate-like B-cell biology. This is associated with a reduction in B1 cells and circulating classswitched anti-phosphorylcholine antibody in D6-deficient mice. Therefore, in the present study, we identify a unifying marker of innate-like B cells, describe novel B1-cell subsets, reveal a dual role for D6, and provide the first evidence of defects in resting D6-deficient mice. (Blood. 2011;117(20):5413-5424

Tumors hamper the immunogenic competence of CD4+ T cell-directed dendritic cell vaccination

Dendritic cells loaded with tumor-derived peptides induce protective CTL responses and are under evaluation in clinical trails. We report in this study that prophylactic administration of dendritic cells loaded with a MHC class II-restricted peptide derived from a model tumor Ag (Leishmania receptor for activated C kinase (LACK)) confers protection against LACK-expressing TS/A tumors, whereas therapeutic vaccination fails to cure tumor-bearing mice. Although CD4+ T cell-directed dendritic cell vaccination primed effector-like (CD44(high)CD62L(low), IL-2(+), IFN-gamma(+)) and central memory-like lymphocytes (CD44(high)CD62L(high), only IL-2(+)) in tumor-free mice, this was not the case in tumor-bearing animals in which both priming and persistence of CD4+ T cell memory were suppressed. Suppression was specific for the tumor-associated Ag LACK, and did not depend on CD25+ T cells. Because T cell help is needed for protective immunity, we speculate that the ability of tumors to limit vaccine-induced CD4+ T cell memory could provide a partial explanation for the limited efficacy of current strategies

Defining the microbial transcriptional response to colitis through integrated host and microbiome profiling

The gut microbiome is significantly altered in inflammatory bowel diseases, but the basis of these changes is not well understood. We have combined metagenomic and metatranscriptomic profiling of the gut microbiome to assess modifications to both bacterial community structure and transcriptional activity in a mouse model of colitis. By using transcriptomic analysis of colonic tissue and luminal RNA derived from the host, we have also characterised how host transcription relates to the microbial transcriptional response in inflammation. In colitis, increased abundance and transcription of diverse microbial gene families involved in responses to nutrient deprivation, antimicrobial peptide production and oxidative stress support an adaptation of multiple commensal genera to withstand a diverse set of environmental stressors in the inflammatory environment. These data are supported by a transcriptional signature of activated macrophages and granulocytes in the gut lumen during colitis, a signature that includes the transcription of the key antimicrobial genes S100a8 and S100a9 (calprotectin). Genes involved in microbial resistance to oxidative stress, including Dps/ferritin, Fe-dependent peroxidase and glutathione S-transferase were identified as changing to a greater extent at the level of transcription than would be predicted by DNA abundance changes, implicating a role for increased oxygen tension and/or host-derived reactive oxygen species in driving transcriptional changes in commensal microbes

Correction: Defining the microbial transcriptional response to colitis through integrated host and microbiome profiling

Correction to: The ISME Journal https://doi.org/10.1038/ismej.2016.40 Since publication of the original paper the authors realised the following funding body was missing from the article’s Acknowledgements: "FP and this work was also supported by the European Research Council (ERC, Advanced Grant Ares(2013)3687660)". The authors apologise for any inconvenience caused

The Oxford Democrat : Vol. 65. No. 15 - April 19,1898

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Regulation of Foxp3+ Inducible Regulatory T Cell Stability by SOCS2

Suppressor of cytokine signaling (SOCS) proteins are key regulators of CD4(+) T cell differentiation, and in particular, we have recently shown that SOCS2 inhibits the development of Th2 cells and allergic immune responses. Interestingly, transcriptome analyses have identified SOCS2 as being preferentially expressed in both natural regulatory T cells (Tregs) and inducible Tregs (iTregs); however, the role of SOCS2 in Foxp3(+) Treg function or development has not been fully elucidated. In this study, we show that despite having no effect on natural Treg development or function, SOCS2 is highly expressed in iTregs and required for the stable expression of Foxp3 in iTregs in vitro and in vivo. Indeed, SOCS2-deficient CD4(+) T cells upregulated Foxp3 following in vitro TGF-β stimulation, but failed to maintain stable expression of Foxp3. Moreover, in vivo generation of iTregs following OVA feeding was impaired in the absence of SOCS2 and could be rescued in the presence of IL-4 neutralizing Ab. Following IL-4 stimulation, SOCS2-deficient Foxp3(+) iTregs secreted elevated IFN-γ and IL-13 levels and displayed enhanced STAT6 phosphorylation. Therefore, we propose that SOCS2 regulates iTreg stability by downregulating IL-4 signaling. Moreover, SOCS2 is essential to maintain the anti-inflammatory phenotype of iTregs by preventing the secretion of proinflammatory cytokines. Collectively, these results suggest that SOCS2 may prevent IL-4–induced Foxp3(+) iTreg instability. Foxp3(+) iTregs are key regulators of immune responses at mucosal surfaces; therefore, this dual role of SOCS2 in both Th2 and Foxp3(+) iTregs reinforces SOCS2 as a potential therapeutic target for Th2-biased diseases