A small molecule neutrophil elastase inhibitor, KRP-109, inhibits cystic fibrosis mucin degradation.

BACKGROUND: Neutrophil elastase (NE) rapidly degrades gel-forming airway mucins in cystic fibrosis (CF) sputum. We hypothesized that KRP-109, a small molecule NE inhibitor, would inhibit CF mucin degradation in vitro. METHODS: Sputa were collected from CF patients (n=5) chronically or intermittently infected with Pseudomonas aeruginosa (P.a.). Mucin degradation was analyzed using western blot. Protease inhibitor studies were performed using alpha1-proteinase inhibitor (A1-PI Prolastin®) and KRP-109. Elastase activity assays were performed using spectrophotometry. RESULTS: There were significant differences in the amount of active NE in different CF sputum samples. KRP-109 decreased the NE driven mucin degradation in vitro. Pseudomonas elastases appeared to blunt elastase inhibition by A1-PI or KRP-109. CONCLUSION: Inhibitors of neutrophil and Pseudomonas-derived elastases might rescue mucus clearance and reverse airway obstruction in CF

Altered protease and antiprotease balance during a COPD exacerbation contributes to mucus obstruction.

Proteases have been shown to degrade airway mucin proteins and to damage the epithelium impairing mucociliary clearance. There are increased proteases in the COPD airway but changes in protease-antiprotease balance and mucin degradation have not been investigated during the course of a COPD exacerbation. We hypothesized that increased protease levels would lead to mucin degradation in acute COPD exacerbations. Methods: We measured neutrophil elastase (NE) and alpha 1 protease inhibitor (A1-PI) levels using immunoblotting, and conducted protease inhibitor studies, zymograms, elastin substrate assays and cigarette smoke condensate experiments to evaluate the stability of the gel-forming mucins, MUC5AC and MUC5B, before and 5-6 weeks after an acute pulmonary exacerbation of COPD (n=9 subjects). Results: Unexpectedly, mucin concentration and mucin stability were highest at the start of the exacerbation and restored to baseline after 6 weeks. Consistent with these data, immunoblots and zymograms confirmed decreased NE concentration and activity and increased A1-PI at the start of the exacerbation. After recovery there was an increase in NE activity and a decrease in A1-PI levels. In vitro, protease inhibitor studies demonstrated that serine proteases played a key role in mucin degradation. Mucin stability was further enhanced upon treating with cigarette smoke condensate (CSC). Conclusion: There appears to be rapid consumption of secreted proteases due to an increase in antiproteases, at the start of a COPD exacerbation. This leads to increased mucin gel stability which may be important in trapping and clearing infectious and inflammatory mediators, but this may also contribute acutely to mucus retention