Abstract
The genus Legionella includes opportunistic pathogens inhabiting engineered aquatic ecosystems, where managing their presence and abundance is crucial for public health. In these environments, Legionella interact positively or negatively with multiple members of the microbial communities. Here, we identified bacteria and compounds with Legionella-antagonistic properties. We isolated 212 bacterial colonies from various water sources in Switzerland and screened them for their ability to inhibit one reference strain of L. pneumophila. Ten selected antagonistic isolates were subsequently tested with spot-on-lawn-assays for inhibition towards seven environmental and two clinical isolates of Legionella, representing different species and strains. The antagonists produced highly variable inhibition patterns, highlighting distinct differences in susceptibility among Legionella species, and even strains. Only three isolates, all identified as Pseudomonas lurida, inhibited all Legionella species. Furthermore, we analysed the genomes of the antagonistic bacteria, and identified genes for several probable inhibitory compounds. We specifically found the gene cluster for the biosurfactant viscosin to be uniquely encoded by three Pseudomonas lurida isolates. This compound was subsequently detected in the supernatant of co-cultures inoculated with the antagonists and Legionella. This study provides new insights on the ability of aquatic microorganisms to compete with Legionella in controlled laboratory settings. It also highlights the diversity across and within Legionella species in their resistance to external antagonistic stress, and confirms the anti-Legionella activity of selected biosurfactants. These results can contribute to the understanding of how different species inhabit separate niches in the environment, and expand the discussion around alternative Legionella mitigation strategies.
Competing Interest Statement
The authors have declared no competing interest.