Background and purpose: Asthma is a chronic disease that displays heterogeneous clinical and molecular features. A phenotypic subset of late-onset severe asthmatics has debilitating fixed airflow obstruction, increased neutrophilic inflammation and a history of pneumonia. Influenza A virus (IAV) is an important viral cause of pneumonia and asthmatics are frequently hospitalised during IAV epidemics. This study aims to determine whether antagonising granulocyte colony stimulating factor receptor (G-CSFR) prevents pneumonia-associated severe asthma.
Experimental approach: Mice were sensitised to house dust mite (HDM) to establish allergic airway inflammation and subsequently infected with IAV (HKx31/H3N2 subtype). A neutralising monoclonal antibody against G-CSFR was therapeutically administered.
Key results: In IAV-infected mice with prior HDM sensitisation, a significant increase in airway fibrotic remodelling and airways hyper-reactivity was observed. A mixed granulocytic inflammatory profile consisting of neutrophils, macrophages and eosinophils was prominent and at a molecular level, G-CSF expression was significantly increased in HDMIAV-treated mice. Blockage of G-CSFR reduced neutrophilic inflammation in the bronchoalveolar and lungs by over 80% in HDMIAV-treated mice without altering viral clearance. Markers of NETosis (dsDNA and myeloperoxidase in bronchoalveolar), tissue injury (LDH activity in bronchoalveolar) and oedema (total bronchoalveolar-fluid protein) were also significantly reduced with anti-G-CSFR treatment. In addition, anti-G-CSFR antagonism significantly reduced bronchoalveolar gelatinase activity, active TFGβ lung levels, collagen lung expression, airways fibrosis and airways hyper-reactivity in HDMIAV-treated mice.
Conclusions and implications: We have shown that antagonising G-CSFR-dependent neutrophilic inflammation reduced pathological disruption of the mucosal barrier and airways fibrosis in an IAV-induced severe asthma model.
Keywords: G-CSF receptor; airway fibrosis; influenza A virus; neutrophilic inflammation; severe asthma.
© 2021 The British Pharmacological Society.