RATIONALE: Chronic obstructive pulmonary disease (COPD) and influenza virus infections are major global health issues. Patients with COPD are more susceptible to infection, which exacerbates their condition and increases morbidity and mortality. The mechanisms of increased susceptibility remain poorly understood, and current preventions and treatments have substantial limitations. OBJECTIVES: To characterize the mechanisms of increased susceptibility to influenza virus infection in COPD and the potential for therapeutic targeting. METHODS: We used a combination of primary bronchial epithelial cells (pBECs) from COPD and healthy control subjects, a mouse model of cigarette smoke-induced experimental COPD, and influenza infection. The role of the phosphoinositide-3-kinase (PI3K) pathway was characterized using molecular methods, and its potential for targeting assessed using inhibitors. MEASUREMENTS AND MAIN RESULTS: COPD pBECs were susceptible to increased viral entry and replication. Infected mice with experimental COPD also had more severe infection (increased viral titer and pulmonary inflammation, and compromised lung function). These processes were associated with impaired antiviral immunity, reduced retinoic acid-inducible gene-I, and IFN/cytokine and chemokine responses. Increased PI3K-p110α levels and activity in COPD pBECs and/or mice were responsible for increased infection and reduced antiviral responses. Global PI3K, specific therapeutic p110α inhibitors, or exogenous IFN-β restored protective antiviral responses, suppressed infection, and improved lung function. CONCLUSIONS: The increased susceptibility of individuals with COPD to influenza likely results from impaired antiviral responses, which are mediated by increased PI3K-p110α activity. This pathway may be targeted therapeutically in COPD, or in healthy individuals, during seasonal or pandemic outbreaks to prevent and/or treat influenza.
RATIONALE: Chronic obstructive pulmonary disease (COPD) and influenza virus infections are major global health issues. Patients with COPD are more susceptible to infection, which exacerbates their condition and increases morbidity and mortality. The mechanisms of increased susceptibility remain poorly understood, and current preventions and treatments have substantial limitations. OBJECTIVES: To characterize the mechanisms of increased susceptibility to influenza virus infection in COPD and the potential for therapeutic targeting. METHODS: We used a combination of primary bronchial epithelial cells (pBECs) from COPD and healthy control subjects, a mouse model of cigarette smoke-induced experimental COPD, and influenza infection. The role of the phosphoinositide-3-kinase (PI3K) pathway was characterized using molecular methods, and its potential for targeting assessed using inhibitors. MEASUREMENTS AND MAIN RESULTS:COPD pBECs were susceptible to increased viral entry and replication. Infected mice with experimental COPD also had more severe infection (increased viral titer and pulmonary inflammation, and compromised lung function). These processes were associated with impaired antiviral immunity, reduced retinoic acid-inducible gene-I, and IFN/cytokine and chemokine responses. Increased PI3K-p110α levels and activity in COPD pBECs and/or mice were responsible for increased infection and reduced antiviral responses. Global PI3K, specific therapeutic p110α inhibitors, or exogenous IFN-β restored protective antiviral responses, suppressed infection, and improved lung function. CONCLUSIONS: The increased susceptibility of individuals with COPD to influenza likely results from impaired antiviral responses, which are mediated by increased PI3K-p110α activity. This pathway may be targeted therapeutically in COPD, or in healthy individuals, during seasonal or pandemic outbreaks to prevent and/or treat influenza.
Authors: Gang Liu; Marion A Cooley; Andrew G Jarnicki; Alan C-Y Hsu; Prema M Nair; Tatt Jhong Haw; Michael Fricker; Shaan L Gellatly; Richard Y Kim; Mark D Inman; Gavin Tjin; Peter A B Wark; Marjorie M Walker; Jay C Horvat; Brian G Oliver; W Scott Argraves; Darryl A Knight; Janette K Burgess; Philip M Hansbro Journal: JCI Insight Date: 2016-06-16
Authors: Alan C-Y Hsu; Kamal Dua; Malcolm R Starkey; Tatt-Jhong Haw; Prema M Nair; Kristy Nichol; Nathan Zammit; Shane T Grey; Katherine J Baines; Paul S Foster; Philip M Hansbro; Peter A Wark Journal: JCI Insight Date: 2017-04-06
Authors: Evelyn Tsantikos; Maverick Lau; Cassandra Mn Castelino; Mhairi J Maxwell; Samantha L Passey; Michelle J Hansen; Narelle E McGregor; Natalie A Sims; Daniel P Steinfort; Louis B Irving; Gary P Anderson; Margaret L Hibbs Journal: J Clin Invest Date: 2018-04-30 Impact factor: 14.808
Authors: A G Jarnicki; H Schilter; G Liu; K Wheeldon; A-T Essilfie; J S Foot; T T Yow; W Jarolimek; P M Hansbro Journal: Br J Pharmacol Date: 2016-10-12 Impact factor: 8.739
Authors: Malcolm R Starkey; Maximilian W Plank; Paolo Casolari; Alberto Papi; Stelios Pavlidis; Yike Guo; Guy J M Cameron; Tatt Jhong Haw; Anthony Tam; Ma'en Obiedat; Chantal Donovan; Nicole G Hansbro; Duc H Nguyen; Prema Mono Nair; Richard Y Kim; Jay C Horvat; Gerard E Kaiko; Scott K Durum; Peter A Wark; Don D Sin; Gaetano Caramori; Ian M Adcock; Paul S Foster; Philip M Hansbro Journal: Eur Respir J Date: 2019-07-18 Impact factor: 16.671
Authors: Gang Liu; Marion A Cooley; Andrew G Jarnicki; Theo Borghuis; Prema M Nair; Gavin Tjin; Alan C Hsu; Tatt Jhong Haw; Michael Fricker; Celeste L Harrison; Bernadette Jones; Nicole G Hansbro; Peter A Wark; Jay C Horvat; W Scott Argraves; Brian G Oliver; Darryl A Knight; Janette K Burgess; Philip M Hansbro Journal: JCI Insight Date: 2019-07-25
Authors: Michael Fricker; Bridie J Goggins; Sean Mateer; Bernadette Jones; Richard Y Kim; Shaan L Gellatly; Andrew G Jarnicki; Nicholas Powell; Brian G Oliver; Graham Radford-Smith; Nicholas J Talley; Marjorie M Walker; Simon Keely; Philip M Hansbro Journal: JCI Insight Date: 2018-02-08