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CD103+ dendritic cell–fibroblast crosstalk via TLR9, TDO2, and AHR signaling drives lung fibrogenesis
Hannah Carter, Rita Medina Costa, Taylor S. Adams, Talon M. Gilchrist, Claire E. Emch, Monica Bame, Justin M. Oldham, Steven K. Huang, Angela L. Linderholm, Imre Noth, Naftali Kaminski, Bethany B. Moore, Stephen J. Gurczynski
Hannah Carter, Rita Medina Costa, Taylor S. Adams, Talon M. Gilchrist, Claire E. Emch, Monica Bame, Justin M. Oldham, Steven K. Huang, Angela L. Linderholm, Imre Noth, Naftali Kaminski, Bethany B. Moore, Stephen J. Gurczynski
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Research Article Immunology Pulmonology

CD103+ dendritic cell–fibroblast crosstalk via TLR9, TDO2, and AHR signaling drives lung fibrogenesis

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Abstract

Idiopathic pulmonary fibrosis (IPF) is characterized by progressive scarring and loss of lung function. With limited treatment options, patients die from the disease within 2–5 years. The molecular pathogenesis underlying the immunologic changes that occur in IPF is poorly understood. We characterize noncanonical aryl-hydrocarbon receptor (ncAHR) signaling in DCs as playing a role in the production of IL-6 and increased IL-17+ cells, promoting fibrosis. TLR9 signaling in myofibroblasts is shown to regulate production of TDO2, which converts tryptophan into the endogenous AHR ligand kynurenine. Mice with augmented ncAHR signaling were created by crossing mice harboring a floxed AHR exon 2 deletion (AHRΔex2) with mice harboring a CD11c-Cre. Bleomycin (blm) was used to study fibrotic pathogenesis. Isolated CD11c+ cells and primary fibroblasts were treated ex vivo with relevant TLR agonists and AHR-modulating compounds to study how AHR signaling influenced inflammatory cytokine production. Human datasets were also interrogated. Inhibition of all AHR signaling rescued fibrosis; however, AHRΔex2 mice treated with blm developed more fibrosis, and DCs from these mice were hyperinflammatory and profibrotic upon adoptive transfer. Treatment of fibrotic fibroblasts with TLR9 agonist increased expression of TDO2, and fibrotic fibroblasts activated IL-6 production in CD103+ DCs. Study of human samples corroborated the relevance of these findings in patients with IPF. We also show, for the first time to our knowledge, that AHR exon 2 floxed mice retain the capacity for ncAHR signaling.

Authors

Hannah Carter, Rita Medina Costa, Taylor S. Adams, Talon M. Gilchrist, Claire E. Emch, Monica Bame, Justin M. Oldham, Steven K. Huang, Angela L. Linderholm, Imre Noth, Naftali Kaminski, Bethany B. Moore, Stephen J. Gurczynski

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Figure 3

Deletion of AHR exon 2 reduces canonical AHR signaling in DCs, but AHR expression is retained and augments inflammatory ncAHR signaling.

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Deletion of AHR exon 2 reduces canonical AHR signaling in DCs, but AHR e...
(A) Schematic of murine AHR depicting deletion of AHR exon 2 containing the DNA-binding basic helix-loop-helix (bHLH) domain. Numbered boxes correlate to individual exons. (B and C) iCD103 DCs were generated from WT B6 mice or AHRΔex2 mice and treated with 200 μM kynurenine (Kyn) or 10 μM CH223191 (CH223). Eighteen hours after treatment, RNA was harvested, and expression of the canonical AHR gene Cyp1b1 (A) or AHR (B) was analyzed via qRT-PCR. (D) iCD103 DCs from AHRΔex2 mice were analyzed via flow cytometry for expression of CD11c and CD103, as well as intracellular expression of AHR. (E) Representative histogram showing AHR expression in WT or AHRΔex2 iCD103 DCs analyzed via flow cytometry. (F and G) Mice (n = 5 per group) were treated with 0.75 U/kg blm. At 10 days after blm treatment, we administered CH223191 (5 mg/kg) or vehicle alone to the groups of mice daily until 18 days after blm treatment. Lungs were harvested at 21 days after blm, and collagen content was quantified via hydroxyproline assay (F); and lung fibrosis was examined via histopathological examination of fixed lung sections (scale bars: 100 μM in G). All data are representative of at least 3 independent experiments; statistical significance was determined via ANOVA (*P < 0.05, **P < 0.01, ***P < 0.001, ****P < 0.0001).

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