posted on 2022-09-16, 10:01authored bySarah Diver, Koirobi Haldar, Pamela Jane McDowell, John Busby, Vijay Mistry, Claudia Micieli, Vanessa Brown, Ciara Cox, Freda Yang, Catherine Borg, Rahul Shrimanker, Mohammadali Yavari Ramsheh, Tim Hardman, Joseph Arron, Peter Bradding, Douglas Cowan, Adel Hasan Mansur, Stephen J Fowler, Jim Lordan, Andrew Menzies-Gow, Douglas Robinson, John Matthews, Ian D Pavord, Rekha Chaudhuri, Liam G Heaney, Michael R Barer, Christopher Brightling
Background: In T2-mediated severe asthma, biologic therapies, such as mepolizumab, are increasingly used to control disease. Current biomarkers can indicate adequate suppression of T2 inflammation, but it is unclear whether they provide information about airway microbial composition. We investigated the relationships between current T2 biomarkers and microbial profiles, characteristics associated with a ProteobacteriaHIGH microbial profile and the effects of mepolizumab on airway ecology. Methods: Microbiota sequencing was performed on sputum samples obtained at stable and exacerbation state from 140 subjects with severe asthma participating in two clinical trials. Inflammatory subgroups were compared on the basis of biomarkers, including FeNO and sputum and blood eosinophils. ProteobacteriaHIGH subjects were identified by Proteobacteria to Firmicutes ratio ≥0.485. Where paired sputum from stable visits was available, we compared microbial composition at baseline and following ≥12 weeks of mepolizumab. Results: Microbial composition was not related to inflammatory subgroup based on sputum or blood eosinophils. FeNO ≥50 ppb when stable and at exacerbation indicated a group with less dispersed microbial profiles characterised by high alpha-diversity and low Proteobacteria. ProteobacteriaHIGH subjects were neutrophilic and had a longer time from asthma diagnosis than ProteobacteriaLOW subjects. In those studied, mepolizumab did not alter airway bacterial load or lead to increased Proteobacteria. Conclusion: High FeNO could indicate a subgroup of severe asthma less likely to benefit from antimicrobial strategies at exacerbation or in the context of poor control. Where FeNO is <50 ppb, biomarkers of microbial composition are required to identify those likely to respond to microbiome-directed strategies. We found no evidence that mepolizumab alters airway microbial composition.
Funding
National Institute for Health Research Leicester Biomedical Research Unit
UK Medical Research Council
History
Author affiliation
Department of Respiratory Sciences, University of Leicester