Dpr-mediated HO resistance contributes to streptococcus survival in a cystic fibrosis airway model system.

Unlabelled: The cystic fibrosis (CF) lung environment is conducive to the colonization of bacteria as polymicrobial biofilms, which are associated with poor clinical outcomes for persons with CF (pwCF). spp. are highly prevalent in the CF airway, but its role in the CF lung microbiome is poorly understood. Some studies have shown spp. to be associated with better clinical outcomes for pwCF, while others show that high abundance of spp. is correlated with exacerbations. Our lab previously reported a polymicrobial culture system consisting of four CF-relevant pathogens that can be used to study microbial behavior in a more clinically relevant setting. Here, we use this model system to identify genetic pathways that are important for survival in the context of the polymicrobial community. We identified genes related to reactive oxygen species as differentially expressed in monoculture versus growth of this microbe in the mixed community. Genetic studies identified Dpr as important for survival in the community. We show that Dpr, a DNA-binding ferritin-like protein, and PerR, a peroxide-responsive transcriptional regulator of Dpr, are important for protecting from phenazine-mediated toxicity in co-culture with and when exposed to hydrogen peroxide, both of which mimic the CF lung environment. Characterizing such interactions in a clinically relevant model system contributes to our understanding of microbial behavior in the context of polymicrobial biofilm infections.

Importance: spp. are recognized as a highly prevalent pathogen in cystic fibrosis (CF) airway infections. However, the role of this microbe in clinical outcomes for persons with CF is poorly understood. Here, we leverage a polymicrobial community system previously developed by our group to model CF airway infections as a tool to investigate a - interaction involving reactive oxygen species (ROS). We show that protection against ROS is required for survival in a clinically relevant polymicrobial system. Using this model system to study interspecies interactions contributes to our broader understanding of the complex role of spp. in the CF lung.