Ramsheh Mohammadali Yavari, Haldar Koirobi, Esteve-Codina Anna, Purser Lillie F, Richardson Matthew, Müller-Quernheim Joachim, Greulich Timm, Nowinski Adam, Barta Imre, Stendardo Mariarita, Boschetto Piera, Korzybski Damian, Prasse Antje, Parr David G, Hohlfeld Jens M, Döme Balázs, Welte Tobias, Heath Simon, Gut Ivo, Morrissey Julie A, Ziegler-Heitbrock Loems, Barer Michael R, Singh Dave, Brightling Christopher E
Department of Respiratory Sciences, Institute for Lung Health, University of Leicester, and Leicester NIHR Biomedical Research Centre, Leicester, UK.
CNAG-CRG, Centre for Genomic Regulation, Barcelona Institute of Science and Technology and Universitat Pompeu Fabra, Barcelona, Spain.
Lancet Microbe. 2021 Jul;2(7):e300-e310. doi: 10.1016/S2666-5247(21)00035-5. Epub 2021 Apr 23.
Chronic obstructive pulmonary disease (COPD) is associated with airway inflammation and bacterial dysbiosis. The relationship between the airway microbiome and bronchial gene expression in COPD is poorly understood. We aimed to identify differences in the airway microbiome from bronchial brushings in patients with COPD and healthy individuals and to investigate whether any distinguishing bacteria are related to bronchial gene expression.
For this 16S rRNA gene sequencing and host transcriptomic analysis, individuals aged 45-75 years with mild-to-moderate COPD either receiving or not receiving inhaled corticosteroids and healthy individuals in the same age group were recruited as part of the Emphysema versus Airways Disease (EvA) consortium from nine centres in the UK, Germany, Italy, Poland, and Hungary. Individuals underwent clinical characterisation, spirometry, CT scans, and bronchoscopy. From bronchoscopic bronchial brush samples, we obtained the microbial profiles using 16S rRNA gene sequencing and gene expression using the RNA-Seq technique. We analysed bacterial genera relative abundance and the associations between genus abundance and clinical characteristics or between genus abundance and host lung transcriptional signals in patients with COPD versus healthy individuals, and in patients with COPD with versus without inhaled corticosteroids treatment.
Between February, 2009, and March, 2012, we obtained brush samples from 574 individuals. We used 546 of 574 samples for analysis, including 207 from healthy individuals and 339 from patients with COPD (192 with inhaled corticosteroids and 147 without). The bacterial genera that most strongly distinguished patients with COPD from healthy individuals were Prevotella (median relative abundance 33·5%, IQR 14·5-49·4, in patients with COPD vs 47·7%, 31·1-60·7, in healthy individuals; p<0·0001), Streptococcus (8·6%, 3·8-15·8, vs 5·3%, 3·0-10·1; p<0·0001), and Moraxella (0·05%, 0·02-0·14, vs 0·02%, 0-0·07; p<0·0001). Prevotella abundance was inversely related to COPD severity in terms of symptoms and positively related to lung function and exercise capacity. 446 samples had assessable RNA-seq data, 257 from patients with COPD (136 with inhaled corticosteroids and 121 without) and 189 from healthy individuals. No significant associations were observed between lung transcriptional signals from bronchial brushings and abundance of bacterial genera in patients with COPD without inhaled corticosteroids treatment and in healthy individuals. In patients with COPD treated with inhaled corticosteroids, Prevotella abundance was positively associated with expression of epithelial genes involved in tight junction promotion and Moraxella abundance was associated with expression of the IL-17 and TNF inflammatory pathways.
With increasing severity of COPD, the airway microbiome is associated with decreased abundance of Prevotella and increased abundance of Moraxella in concert with downregulation of genes promoting epithelial defence and upregulation of pro-inflammatory genes associated with inhaled corticosteroids use. Our work provides further insight in understanding the relationship between microbiome alteration and host inflammatory response, which might lead to novel therapeutic strategies for COPD.
EU Seventh Framework Programme, National Institute for Health Research.
慢性阻塞性肺疾病(COPD)与气道炎症和细菌生态失调有关。COPD患者气道微生物群与支气管基因表达之间的关系尚不清楚。我们旨在确定COPD患者和健康个体支气管刷检气道微生物群的差异,并研究是否有任何特征性细菌与支气管基因表达相关。
对于这项16S rRNA基因测序和宿主转录组分析,招募了年龄在45 - 75岁、患有轻至中度COPD且正在接受或未接受吸入性糖皮质激素治疗的个体以及同一年龄组的健康个体,作为来自英国、德国、意大利、波兰和匈牙利九个中心的肺气肿与气道疾病(EvA)联盟的一部分。个体接受临床特征评估、肺功能测定、CT扫描和支气管镜检查。从支气管镜下支气管刷检样本中,我们使用16S rRNA基因测序获得微生物谱,并使用RNA - Seq技术获得基因表达。我们分析了COPD患者与健康个体之间、接受与未接受吸入性糖皮质激素治疗的COPD患者之间细菌属的相对丰度以及属丰度与临床特征之间或属丰度与宿主肺转录信号之间的关联。
在2009年2月至2012年3月期间,我们从574名个体中获取了刷检样本。我们使用了574个样本中的546个进行分析,其中包括207个来自健康个体的样本和339个来自COPD患者的样本(192个接受吸入性糖皮质激素治疗,147个未接受)。与健康个体相比,最能显著区分COPD患者的细菌属是普雷沃菌属(COPD患者的中位相对丰度为33.5%,四分位距为14.5 - 49.4,健康个体为47.7%,31.1 - 60.7;p<0.0001)、链球菌属(8.6%,3.8 - 15.8,健康个体为5.3%,3.0 - 10.1;p<0.0001)和莫拉克斯菌属(0.05%,0.02 - 0.14,健康个体为0.02%,0 - 0.07;p<0.0001)。就症状而言,普雷沃菌属丰度与COPD严重程度呈负相关,与肺功能和运动能力呈正相关。446个样本有可评估的RNA测序数据,其中257个来自COPD患者(136个接受吸入性糖皮质激素治疗,121个未接受),189个来自健康个体。在未接受吸入性糖皮质激素治疗的COPD患者和健康个体中,支气管刷检的肺转录信号与细菌属丰度之间未观察到显著关联。在接受吸入性糖皮质激素治疗的COPD患者中,普雷沃菌属丰度与参与促进紧密连接的上皮基因表达呈正相关,莫拉克斯菌属丰度与IL - 17和TNF炎症途径的表达相关。
随着COPD严重程度的增加,气道微生物群与普雷沃菌属丰度降低和莫拉克斯菌属丰度增加相关,同时促进上皮防御的基因下调,与吸入性糖皮质激素使用相关的促炎基因上调。我们的工作为理解微生物群改变与宿主炎症反应之间的关系提供了进一步的见解,这可能会为COPD带来新的治疗策略。
欧盟第七框架计划、国家卫生研究院。
