Evolution of high-level resistance during low-level antibiotic exposure

It has become increasingly clear that low levels of antibiotics present in many environments can select for resistant bacteria, yet the evolutionary pathways for resistance development during exposure to low amounts of antibiotics remain poorly defined. Here we show that Salmonella enterica exposed to sub-MIC levels of streptomycin evolved high-level resistance via novel mechanisms that are different from those observed during lethal selections. During lethal selection only rpsL mutations are found, whereas at sub-MIC selection resistance is generated by several small-effect resistance mutations that combined confer high-level resistance via three different mechanisms: (i) alteration of the ribosomal RNA target ( gidB mutations), (ii) reduction in aminoglycoside uptake ( cyoB, nuoG, and trkH mutations), and (iii) induction of the aminoglycoside-modifying enzyme AadA ( znuA mutations). These results demonstrate how the strength of the selective pressure influences evolutionary trajectories and that even weak selective pressures can cause evolution of high-level resistance.

Mutational antibiotic resistance can emerge under either high or low antibiotic levels. Here, the authors show several small-effect resistance mutations are combined to confer high-level resistance in Salmonella enterica exposed to sub-MIC levels of streptomycin.