Lower Airway Dysbiosis Augments Lung Inflammatory Injury in Mild-to-Moderate Chronic Obstructive Pulmonary Disease

Overview

Journal Am J Respir Crit Care Med

Specialty Critical Care

Date 2023 Sep 7

PMID 37677136

Authors

Imran Sulaiman

Benjamin G Wu

Matthew Chung

Bradley Isaacs

Jun-Chieh J Tsay

Meredith Holub

Clea R Barnett

Benjamin Kwok

Matthias C Kugler

Jake G Natalini

Shivani Singh

Yonghua Li

Rosemary Schluger

Joseph Carpenito

Destiny Collazo

Luisanny Perez

Yaa Kyeremateng

Miao Chang

Christina D Campbell

Philip M Hansbro

Beno W Oppenheimer

Kenneth I Berger

Roberta M Goldring

Sergei B Koralov

Michael D Weiden

Rui Xiao

Jeanine DArmiento

Jose C Clemente

Elodie Ghedin

Leopoldo N Segal

Affiliations

Soon will be listed here.

Abstract

Chronic obstructive pulmonary disease (COPD) is associated with high morbidity, mortality, and healthcare costs. Cigarette smoke is a causative factor; however, not all heavy smokers develop COPD. Microbial colonization and infections are contributing factors to disease progression in advanced stages. We investigated whether lower airway dysbiosis occurs in mild-to-moderate COPD and analyzed possible mechanistic contributions to COPD pathogenesis. We recruited 57 patients with a >10 pack-year smoking history: 26 had physiological evidence of COPD, and 31 had normal lung function (smoker control subjects). Bronchoscopy sampled the upper airways, lower airways, and environmental background. Samples were analyzed by 16S rRNA gene sequencing, whole genome, RNA metatranscriptome, and host RNA transcriptome. A preclinical mouse model was used to evaluate the contributions of cigarette smoke and dysbiosis on lower airway inflammatory injury. Compared with smoker control subjects, microbiome analyses showed that the lower airways of subjects with COPD were enriched with common oral commensals. The lower airway host transcriptomics demonstrated differences in markers of inflammation and tumorigenesis, such as upregulation of IL-17, IL-6, ERK/MAPK, PI3K, MUC1, and MUC4 in mild-to-moderate COPD. Finally, in a preclinical murine model exposed to cigarette smoke, lower airway dysbiosis with common oral commensals augments the inflammatory injury, revealing transcriptomic signatures similar to those observed in human subjects with COPD. Lower airway dysbiosis in the setting of smoke exposure contributes to inflammatory injury early in COPD. Targeting the lower airway microbiome in combination with smoking cessation may be of potential therapeutic relevance.

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