ABSTRACTOur recent study presented evidence that Staphylococcus epidermidis (S. epidermidis) was the most frequently encountered microbiome component in healthy human nasal mucus and that S. epidermidis could induce interferon (IFN)-dependent innate immunity to control acute viral lung infection. The serine protease inhibitor Serpine1 was identified to inhibit influenza A virus (IAV) spread by inhibiting glycoprotein cleavage, and the current study supports an additional mechanism of Serpine1 induction in the nasal mucosa, which can be regulated through S. epidermidis and IFN signaling. The exposure of in vivo mice to human S. epidermidis increased IFN-λ secretion in nasal mucosa and prevented an increase in the burden of IAV in the lung. S. epidermidis-inoculated mice exhibited the significant induction of Serpine1 in vivo in the nasal mucosa, and by targeting airway protease, S. epidermidis-induced Serpine1 inhibited the intracellular invasion of IAV to the nasal epithelium and led to restriction of IAV spreading to the lung. Furthermore, IFN-λ secretion was involved in the regulation of Serpine1 in S. epidermidis-inoculated nasal epithelial cells and in vivo nasal mucosa, and this was biologically relevant for the role of Serpine1 as an interferon-stimulated gene in the upper airway. Together, our findings reveal that human nasal commensal S. epidermidis manipulates the suppression of serine protease in in vivo nasal mucosa through Serpine1 induction and protects the nasal mucosa from IAV invasion through IFN-λ signaling.IMPORTANCEPreviously, we proved that nasal microbiome could enhance IFN-related innate immune responses to protect the respiratory tract against influenza virus infection. The present study shows a great understanding of the intimate association of S. epidermidis-regulated IFN-lambda induction and serine protease inhibitor in nasal mucosa. Our data demonstrate that S. epidermidis-regulated Serpine1 suppresses the invasion of influenza virus through suppression of airway serine protease at the level of nasal mucosa and impedes IAV spread to the respiratory tract. Thus, human nasal commensal S. epidermidis represents a therapeutic potential for treating respiratory viral infections via the change of cellular environment in respiratory tract.
A Multi-Variant, Viral Dynamic Model of Genotype 1 HCV to Assess the in vivo Evolution of Protease-Inhibitor Resistant Variants
