Alpha-1 antitrypsin deficiency impairs lung antibacterial immunity in mice
Lena Ostermann, Regina Maus, Jennifer Stolper, Lisanne Schütte, Konstantina Katsarou, Srinu Tumpara, Andreas Pich, Christian Mueller, Sabina Janciauskiene, Tobias Welte, Ulrich A. Maus
Lena Ostermann, Regina Maus, Jennifer Stolper, Lisanne Schütte, Konstantina Katsarou, Srinu Tumpara, Andreas Pich, Christian Mueller, Sabina Janciauskiene, Tobias Welte, Ulrich A. Maus
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Research Article Pulmonology

Alpha-1 antitrypsin deficiency impairs lung antibacterial immunity in mice

Abstract

Alpha-1 antitrypsin (AAT) is a major inhibitor of serine proteases in mammals. Therefore, its deficiency leads to protease–antiprotease imbalance and a risk for developing lung emphysema. Although therapy with human plasma-purified AAT attenuates AAT deficiency–related emphysema, its impact on lung antibacterial immunity is poorly defined. Here, we examined the effect of AAT therapy on lung protective immunity in AAT-deficient (KO) mice challenged with Streptococcus pneumoniae. AAT-KO mice were highly susceptible to S. pneumoniae, as determined by severe lobar pneumonia and early mortality. Mechanistically, we found that neutrophil-derived elastase (NE) degraded the opsonophagocytically important collectins, surfactant protein A (SP-A) and D (SP-D), which was accompanied by significantly impaired lung bacterial clearance in S. pneumoniae–infected AAT-KO mice. Treatment of S. pneumoniae–infected AAT-KO mice with human AAT protected SP-A and SP-D from NE-mediated degradation and corrected the pulmonary pathology observed in these mice. Likewise, treatment with Sivelestat, a specific inhibitor of NE, also protected collectins from degradation and significantly decreased bacterial loads in S. pneumoniae–infected AAT-KO mice. Our findings show that NE is responsible for the degradation of lung SP-A and SP-D in AAT-KO mice affecting lung protective immunity in AAT deficiency.

Authors

Lena Ostermann, Regina Maus, Jennifer Stolper, Lisanne Schütte, Konstantina Katsarou, Srinu Tumpara, Andreas Pich, Christian Mueller, Sabina Janciauskiene, Tobias Welte, Ulrich A. Maus

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Figure 4

Effect of AAT augmentation therapy with active or oxidized AAT on outcome in S. pneumoniae–infected AAT-KO and NE-KO mice.

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Effect of AAT augmentation therapy with active or oxidized AAT on outcom...
AAT-KO mice were treated with Respreeza (gray bars), vehicle (white bars), or oxidized Respreeza (black bars) i.p. at 6 hours prior to pneumococcal infection and at days 0 and 1 postinfection. (A and B) Bacterial loads in BALF (A) and lung tissue (B) were determined at 48 hours postinfection. Data are shown as mean ± SD of n = 6–8 mice per time point and treatment group and are representative of 2 independently performed experiments. NE-KO mice were treated with Respreeza (gray bars) or vehicle (white bars) i.p. starting 24 hours postinfection with S. pneumoniae. (C and D) Bacterial loads in BALF (C) and lung tissue (D) were determined at 48 hours postinfection. Data are shown as mean ± SD of n = 6–9 mice per time point and treatment group and are representative of 2 independently performed experiments. (EL) TNF-α, IL-1β, IL-6, and CXCL1 cytokine levels in BAL fluids and lung homogenate supernatants of NE-KO mice at day 2 postinfection, as indicated. Data are shown as mean ± SD of n = 8–11 mice per time point and treatment group and are representative of 2 independently performed experiments. **P ≤ 0.01, compared with vehicle-treated mice. (Mann-Whitney U test, log-rank test.)