Abstract
Antibiotic combinations are increasingly used to combat bacterial infections. Multidrug therapies are a particularly important treatment option for E. faecalis, an opportunistic pathogen that contributes to high-inoculum infections such as infective endocarditis. While numerous synergistic drug combinations for E. faecalis have been identified, much less is known about how different combinations impact the rate of resistance evolution. In this work, we use high-throughput laboratory evolution experiments to quantify adaptation in growth rate and drug resistance of E. faecalis exposed to drug combinations exhibiting different classes of interactions, ranging from synergistic to suppressive. We identify a wide range of evolutionary behavior, including both increased and decreased rates of growth adaptation, depending on the specific interplay between drug interaction and drug resistance profiles. For example, selection in a dual β-lactam combination leads to accelerated growth adaptation compared to selection with the individual drugs, even though the resulting resistance profiles are nearly identical. On the other hand, populations evolved in an aminoglycoside and β-lactam combination exhibit decreased growth adaptation and resistant profiles that depend on the specific drug concentrations. We show that the main qualitative features of these evolutionary trajectories can be explained by simple rescaling arguments that correspond to geometric transformations of the two-drug growth response surfaces measured in ancestral cells. The analysis also reveals multiple examples where resistance profiles selected by drug combinations are nearly growth-optimized along a contour connecting profiles selected by the component drugs. Our results highlight trade-offs between drug interactions and resistance profiles during the evolution of multi-drug resistance and emphasize evolutionary benefits and disadvantages of particular drug pairs targeting enterococci.
Highlights
The rapid rise of antibiotic resistance poses a growing threat to public health [1, 2]
Antibiotics are increasingly used in combinations to combat difficult bacterial infections, including those caused by the opportunistic pathogen E. faecalis
We studied the evolution of antibiotic resistance using laboratory evolution of E. faecalis populations exposed to different two-drug combinations
Summary
The rapid rise of antibiotic resistance poses a growing threat to public health [1, 2]. Significant efforts have been devoted to designing evolutionarily sound strategies that balance short-term drug efficacy with the long-term potential to develop resistance These approaches describe a number of different factors that could modulate resistance evolution, including interactions between bacterial cells [3,4,5,6,7,8], synergy with the immune system [9], spatial heterogeneity [10,11,12,13,14,15], epistasis between resistance mutations [16, 17], precise temporal scheduling [18,19,20,21], and statistical correlations between resistance profiles for different drugs [22,23,24,25,26,27,28,29,30,31]. These studies show that drug interactions and collateral effects may combine in complex ways to influence evolution of resistance in multi-drug environments
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