Phenylacetic acid metabolic genes are associated with Mycobacteroides abscessus dominant circulating clone 1.

Mycobacteroides abscessus (MAB) causes lung infections in people with cystic fibrosis (pwCF), and infecting strains show significant genetic variability both between and within individuals. MAB isolates can be divided into dominant clonal clusters (DCCs) or non-clustering groups and can present as smooth or rough colonies on agar plates. Both DCCs and the rough colony morphology have been linked to increased pathogenicity, but the mechanisms are unclear. This study explored the genomes of MAB isolates collected from individuals within the CF@LANTA CF center along with publicly available genomes to identify genes associated with more pathogenic MAB DCCs. Sixty-eight isolates from 26 CF individuals colonized by MAB were morphotyped and sequenced, with almost half of these isolates being members of DCC group 1 (DCC1). While lung function was not significantly impacted by colonization with DCC1 or rough isolates, 102 genes were specifically associated with DCC1 isolates. These genes were enriched for functions in sulfur-based DNA modification, DNA integration, and phenylacetic acid (PAA) catabolism. PAA is produced by the human gut microbiota and found throughout the human body. We show that strains containing PAA metabolic genes allow MAB to use PAA as a sole carbon and energy source. Although the benefits of PAA metabolic genes and other enriched pathways remain unclear, these findings highlight genes associated with emerging MAB CF strains.

Importance: A primary challenge in treating bacterial infections is the wide spectrum of disease and genetic variability across bacterial strains. This is particularly evident in Mycobacteroides abscessus (MAB), an emerging pathogen affecting people with cystic fibrosis (pwCF). MAB exhibits significant genetic diversity both within and between individuals. However, seven dominant circulating clones (DCCs) have emerged as the major cause of human infections, demonstrating increased pathogenicity. Understanding the mechanisms underlying this increased pathogenicity and the associated genetic factors is crucial for developing novel treatment strategies. Our findings reveal that specific genes are associated with the DCC1 isolate of MAB, many of which are implicated in antimicrobial susceptibility or virulence.