Project description:Chronic obstructive pulmonary disease (COPD) is associated with airway inflammation and microbiota dysbiosis. However, the function of lung microbiome alteration in early COPD remains unclear. This study is the first to characterize the lower respiratory tract microbiota in early COPD patients via bronchoalveolar lavage fluid (BALF) samples. By using full-length 16S sequencing, we found that the lung microbiome of early COPD patients had lower bacterial richness and significant compositional differences than did that of the healthy smoker controls. Streptococcus was the most robustly distinguished genus in early COPD patients and was associated with decreased lung function and increased host local inflammation. Furthermore, a murine cigarette smoke model of early COPD revealed that Streptococcus mitis promotes the progression of early COPD. Single-cell transcriptomics revealed that Streptococcus mitis increased emphysematous destruction of the lung parenchyma in a mouse early COPD model by regulating the function of alveolar type II (AT2) cells and macrophages. Therefore, targeting the lower airway microbiota in combination with smoking cessation may be a potential therapeutic approach for early COPD.

Project description:Upper/lower respiratory tract microbiome changes patients with COPD

Project description:Respiratory microbiota in COPD patients

Project description:Lower respiratory tract microbiota Raw sequence reads

Project description:Lower respiratory tract microbiome in critically ill patients

Project description:Respiratory microbiota in children with severe lower respiratory tract infections.

Project description:Respiratory microbiota in children with severe lower respiratory tract infections.

Project description:Bovine respiratory epithelial cells have different susceptibility to bovine respiratory syncytial virus infection. The cells derived from the lower respiratory tract were significantly more susceptible to the virus than those derived from the upper respiratory tract. Pre-infection with virus of lower respiratory tract with increased adherence of P. multocida; this was not the case for upper tract. However, the molecular mechanisms of enhanced bacterial adherence are not completely understood. To investigate whether virus infection regulates the cellular adherence receptor on bovine trachea-, bronchus- and lung-epithelial cells, we performed proteomic analyses.

Project description:Characterization of the microbiota in the lower respiratory tract of Influenza A patients

Project description:Microbiome in Lower Respiratory Tract of community-acquired pneumonia with or without COPD