New research suggests a link between the bacteria that live in the upper airway and the severity of asthma symptoms among children with mild to moderate asthma.
The research paves the way for future studies to discover whether altering the types of bacteria that live in the upper airway could help patients with asthma.
“There is an urgent need to develop better asthma therapies for these patients,” says senior author Avraham Beigelman, an associate professor of pediatrics at Washington University in St. Louis. “Though our study can’t prove causation, it raises intriguing questions that we plan to pursue. If we somehow supplement such patients with what appear to be good bacteria, will they do better? We are interested in studying whether we can deliberately alter the airway microbiome to reduce the risk of worsening asthma symptoms.”
In the US, more than 6 million children under age 18 have asthma, or about 1 in 12. It is the leading chronic pediatric disease and the number one reason for missed school days, according to the Asthma and Allergy Foundation of America.
The researchers found that children who experienced early warning signs that their asthma was going to flare up were more likely to have bacteria associated with disease—including Staphylococcus, Streptococcus, and Moraxella bacterial groups—living in their upper airways. In contrast, airway microbes dominated by Corynebacterium and Dolosigranulum bacteria were associated with periods of good health, when asthma was well-controlled.
Beigelman and his colleagues also found that children whose airway microbial communities switched from Corynebacterium and Dolosigranulum bacteria dominating them to Moraxella bacteria dominating them were at the highest risk of worsening asthma symptoms compared with children whose microbial communities made any other kind of shift.
“Our data demonstrated a rapid change of the airway microbiome in the children who transitioned from respiratory health to disease,” says first author Yanjiao Zhou, who conducted postdoctoral microbiome and bioinformatics research at Washington University before joining the faculty at the University of Connecticut. “It is also intriguing to find that the microbiome changing pattern could play an important role in asthma exacerbation. We are planning future studies to explore this possibility.”
The researchers conducted the upper airway microbiome study in conjunction with a clinical trial involving 214 children ages 5 to 11 with mild to moderate asthma. The researchers conducted the trial—called Step Up Yellow Zone Inhaled Corticosteroids to Prevent Exacerbations (STICS)—as part of AsthmaNet, a national network of medical centers conducting asthma research funded by the National Heart, Lung, and Blood Institute (NHLBI) of the National Institutes of Health (NIH). Washington University is an AsthmaNet site, and asthma specialist and coauthor of the current microbiome study, Leonard B. Bacharier, a professor of pediatrics at Washington University, led the pediatric portion of the STICS trial at Washington University.
The clinical trial’s purpose was to determine whether quintupling the dose of an inhaled corticosteroid at the first signs of worsening asthma was better than keeping a low dose of the same medication. The trial, the results of which appeared in The New England Journal of Medicine in 2018, found no benefit to the larger dose.
During that trial, the researchers also collected nasal mucus samples from the children to study their upper airway microbiomes. They collected samples at the beginning of the trial, when all of the participants had controlled asthma, as well as at the first early signs that asthma control was slipping.
Based on these findings, the researchers say they plan to conduct studies in mice with carefully controlled airway microbiomes to see if the researchers can uncover a causal role for bacteria in asthma severity. In addition, such experiments could allow them to test different interventions that might deliberately alter the upper airway bacteria in a way that could be protective.
The findings appear in Nature Communications. Support for the study came from the National Heart, Lung, and Blood Institute of the National Institutes of Health and the Jackson Laboratory.
