Urinary metabotype of severe asthma evidences decreased carnitine metabolism independent of oral corticosteroid treatment in the U-BIOPRED study.
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BORIS DOI
Date of Publication
June 2022
Publication Type
Article
Division/Institute
Contributor
Reinke, Stacey N | |
Naz, Shama | |
Chaleckis, Romanas | |
Gallart-Ayala, Hector | |
Kolmert, Johan | |
Kermani, Nazanin Z | |
Tiotiu, Angelica | |
Broadhurst, David I | |
Lundqvist, Anders | |
Olsson, Henric | |
Ström, Marika | |
Wheelock, Åsa M | |
Gómez, Cristina | |
Ericsson, Magnus | |
Sousa, Ana R | |
Riley, John H | |
Bates, Stewart | |
Scholfield, James | |
Loza, Matthew | |
Baribaud, Frédéric | |
Bakke, Per S | |
Caruso, Massimo | |
Chanez, Pascal | |
Fowler, Stephen J | |
Howarth, Peter | |
Horváth, Ildikó | |
Krug, Norbert | |
Montuschi, Paolo | |
Behndig, Annelie | |
Musial, Jacek | |
Shaw, Dominick E | |
Dahlén, Barbro | |
Hu, Sile | |
Lasky-Su, Jessica | |
Sterk, Peter J | |
Chung, Kian Fan | |
Djukanovic, Ratko | |
Dahlén, Sven-Erik | |
Adcock, Ian M | |
Wheelock, Craig E |
Subject(s)
Series
European respiratory journal
ISSN or ISBN (if monograph)
0903-1936
Publisher
European Respiratory Society
Language
English
Publisher DOI
PubMed ID
34824054
Description
INTRODUCTION
Asthma is a heterogeneous disease with poorly defined phenotypes. Severe asthmatics often receive multiple treatments including oral corticosteroids (OCS). Treatment may modify the observed metabotype, rendering it challenging to investigate underlying disease mechanisms. Here, we aimed to identify dysregulated metabolic processes in relation to asthma severity and medication.
METHODS
Baseline urine was collected prospectively from healthy participants (n=100), mild-to-moderate asthmatics (n=87) and severe asthmatics (n=418) in the cross-sectional U-BIOPRED cohort; 12-18-month longitudinal samples were collected from severe asthmatics (n=305). Metabolomics data were acquired using high-resolution mass spectrometry and analysed using univariate and multivariate methods.
RESULTS
Ninety metabolites were identified, with 40 significantly altered (p<0.05, FDR<0.05) in severe asthma and 23 by OCS use. Multivariate modelling showed that observed metabotypes in healthy participants and mild-to-moderate asthmatics differed significantly from severe asthmatics (p=2.6×10-20), OCS-treated asthmatics differed significantly from non-treated (p=9.5×10-4), and longitudinal metabotypes demonstrated temporal stability. Carnitine levels evidenced the strongest OCS-independent decrease in severe asthma. Reduced carnitine levels were associated with mitochondrial dysfunction via decreases in pathway enrichment scores of fatty acid metabolism and reduced expression of the carnitine transporter SLC22A5 in sputum and bronchial brushings.
CONCLUSIONS
This is the first large-scale study to delineate disease- and OCS-associated metabolic differences in asthma. The widespread associations with different therapies upon the observed metabotypes demonstrate the necessity to evaluate potential modulating effects on a treatment- and metabolite-specific basis. Altered carnitine metabolism is a potentially actionable therapeutic target that is independent of OCS treatment, highlighting the role of mitochondrial dysfunction in severe asthma.
Asthma is a heterogeneous disease with poorly defined phenotypes. Severe asthmatics often receive multiple treatments including oral corticosteroids (OCS). Treatment may modify the observed metabotype, rendering it challenging to investigate underlying disease mechanisms. Here, we aimed to identify dysregulated metabolic processes in relation to asthma severity and medication.
METHODS
Baseline urine was collected prospectively from healthy participants (n=100), mild-to-moderate asthmatics (n=87) and severe asthmatics (n=418) in the cross-sectional U-BIOPRED cohort; 12-18-month longitudinal samples were collected from severe asthmatics (n=305). Metabolomics data were acquired using high-resolution mass spectrometry and analysed using univariate and multivariate methods.
RESULTS
Ninety metabolites were identified, with 40 significantly altered (p<0.05, FDR<0.05) in severe asthma and 23 by OCS use. Multivariate modelling showed that observed metabotypes in healthy participants and mild-to-moderate asthmatics differed significantly from severe asthmatics (p=2.6×10-20), OCS-treated asthmatics differed significantly from non-treated (p=9.5×10-4), and longitudinal metabotypes demonstrated temporal stability. Carnitine levels evidenced the strongest OCS-independent decrease in severe asthma. Reduced carnitine levels were associated with mitochondrial dysfunction via decreases in pathway enrichment scores of fatty acid metabolism and reduced expression of the carnitine transporter SLC22A5 in sputum and bronchial brushings.
CONCLUSIONS
This is the first large-scale study to delineate disease- and OCS-associated metabolic differences in asthma. The widespread associations with different therapies upon the observed metabotypes demonstrate the necessity to evaluate potential modulating effects on a treatment- and metabolite-specific basis. Altered carnitine metabolism is a potentially actionable therapeutic target that is independent of OCS treatment, highlighting the role of mitochondrial dysfunction in severe asthma.
File(s)
| File | File Type | Format | Size | License | Publisher/Copright statement | Content | |
|---|---|---|---|---|---|---|---|
| 13993003.01733-2021.full.pdf | text | Adobe PDF | 4.4 MB | published |