Abstract

Monitoring the emergence of antibiotic resistance is a recent issue in the treatment of Legionnaires' disease. Macrolides are recommended as first-line therapy, but resistance mechanisms have not been studied in <i>Legionella</i> species. Our aim was to determine the molecular basis of macrolide resistance in <i>L. pneumophila</i> Twelve independent lineages from a common susceptible <i>L. pneumophila</i> ancestral strain were propagated under conditions of erythromycin or azithromycin pressure to produce high-level macrolide resistance. Whole-genome sequencing was performed on 12 selected clones, and we investigated mutations common to all lineages. We reconstructed the dynamics of mutation for each lineage and demonstrated their involvement in decreased susceptibility to macrolides. The resistant mutants were produced in a limited number of passages to obtain a 4,096-fold increase in erythromycin MICs. Mutations affected highly conserved 5-amino-acid regions of L4 and L22 ribosomal proteins and of domain V of 23S rRNA (G2057, A2058, A2059, and C2611 nucleotides). The early mechanisms mainly affected L4 and L22 proteins and induced a 32-fold increase in the MICs of the selector drug. Additional mutations related to 23S rRNA mostly occurred later and were responsible for a major increase of macrolide MICs, depending on the mutated nucleotide, the substitution, and the number of mutated genes among the three <i>rrl</i> copies. The major mechanisms of the decreased susceptibility to macrolides in <i>L. pneumophila</i> and their dynamics were determined. The results showed that macrolide resistance could be easily selected in <i>L. pneumophila</i> and warrant further investigations in both clinical and environmental settings.