The house dust mite (HDM) represents a major cause of allergic rhinitis and asthma. We tested whether HDM-induced aeroallergen exposure sensitivity is caused by the innate-immune response in small airway epithelial cells. HDM exposure rapidly activates NFkB/RelA in the Secretoglobin (Scgb1a1+) lineage and upregulates markers of epithelial plasticity. To determine the effect of epithelial NFkB signaling, NFkB was depleted in a tamoxifen (TMX)-inducible Scgb1a1-CreERTM mouse within a CL57B/L6 background. Corn oil or TMX-treated/RelA-depleted (RelA KD) mice were repetitively exposed to airway HDM challenges to induce airway hyperresponsiveness (AHR). Strikingly, we observed that HDM induces hallmarks of epithelial plasticity through upregulation of the mesenchymal core factors SNAI1 and ZEB1 and production of MMP9 that are RelA dependent. Downstream, HDM-induced mucous metaplasia, Th2 polarization, allergen sensitivity and airway hyperreactivity were all reduced in the RelA-depleted mice. Mechanistically, HDM-induced functional and structural barrier disruption was dependent on RelA signaling and associated with active MMP secretion into the bronchoalveolar lavage fluid. To establish the role of MMP2/9 in barrier disruption, we observe that a small-molecule MMP inhibitor (SB-3CT) blocked HDM-induced barrier disruption and activation of plasticity in naïve wild-type mice. Loss of functional barrier was associated with MMP disruption of ZO-1 containing adherens junctions. Overall, this data indicates that host innate signaling in the Scgb1a1+ progenitors is directly linked to epithelial plasticity, MMP9 secretion, and enhanced barrier permeability which allows allergen penetration, sensitization producing allergic asthma (AA) in vivo. We propose that maintenance of epithelial integrity may reduce allergic sensitization and AA.
Keywords: barrier function; innate immunity; matrix metalloproteinases; plasticity; sensitization.