Antibiotic interactions shape short-term evolution of resistance in E. faecalis

Dean, Ziah; Maltas, Jeff; Wood, Kevin B.

doi:10.1371/journal.ppat.1008278

Cited by 28 publications

(39 citation statements)

References 62 publications

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“… ( A ) Growth landscape (per capita growth rate relative to untreated cells) as a function of drug concentration for two drugs (drug 1, tigecycline; drug 2, ciprofloxacin; concentrations measured in μg/mL) based on measurements in Dean et al, 2020 . We consider evolution of resistance in a population exposed to a fixed external drug concentration (

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Section: Resultsmentioning

confidence: 99%

“…These interactions may be leveraged to improve treatments – for example, by offering enhanced antimicrobial effects at reduced concentrations. But these interactions can also accelerate, reduce, or even reverse the evolution of resistance ( Chait et al, 2007 ; Michel et al, 2008 ; Hegreness et al, 2008 ; Pena-Miller et al, 2013 ; Dean et al, 2020 ), leading to tradeoffs between short-term inhibitory effects and long-term evolutionary potential ( Torella et al, 2010 ). In addition, resistance to one drug may be associated with modulated resistance to other drugs.…”

Section: Introductionmentioning

confidence: 99%

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Price equation captures the role of drug interactions and collateral effects in the evolution of multidrug resistance

Gjini

Wood

2021

eLife

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Bacterial adaptation to antibiotic combinations depends on the joint inhibitory effects of the two drugs (drug interaction, DI) and how resistance to one drug impacts resistance to the other (collateral effects, CE). Here we model these evolutionary dynamics on two-dimensional phenotype spaces that leverage scaling relations between the drug-response surfaces of drug sensitive (ancestral) and drug resistant (mutant) populations. We show that evolved resistance to the component drugs-and in turn, the adaptation of growth rate-is governed by a Price equation whose covariance terms encode geometric features of both the two-drug response surface (DI) in ancestral cells and the correlations between resistance levels to those drugs (CE). Within this framework, mean evolutionary trajectories reduce to a type of weighted gradient dynamics, with the drug interaction dictating the shape of the underlying landscape and the collateral effects constraining the motion on those landscapes. We also demonstrate how constraints on available mutational pathways can be incorporated into the framework, adding a third key driver of evolution. Our results clarify the complex relationship between drug interactions and collateral effects in multi-drug environments and illustrate how specific dosage combinations can shift the weighting of these two effects, leading to different and temporally-explicit selective outcomes.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Price equation captures the role of drug interactions and collateral effects in the evolution of multidrug resistance

Gjini

Wood

2021

eLife

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“…However, for over a century, the idea of one drug being an antidote for another was mostly ignored. More recently, in the last decade and a half, there has been a renewed interest in this phenomenon of suppression ( Yeh et al., 2006 ; Chait et al., 2007 ; Cokol et al., 2014 ; de Vos and Bollenbach, 2014 ; Bollenbach, 2015 ; Singh and Yeh, 2017 ; Lukačišin and Bollenbach, 2019 ; Tyers and Wright, 2019 ; Dean et al., 2020 ). Suppression was first defined in terms of antibiotic interactions when a systematic study of 2-drug interactions in 21 antibiotics was conducted, and approximately 10% of all interactions fell into the category of suppression ( Yeh et al., 2006 ).…”

Section: Introductionmentioning

confidence: 99%

Hidden suppressive interactions are common in higher-order drug combinations

et al. 2021

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Summary The rapid increase of multi-drug resistant bacteria has led to a greater emphasis on multi-drug combination treatments. However, some combinations can be suppressive—that is, bacteria grow faster in some drug combinations than when treated with a single drug. Typically, when studying interactions, the overall effect of the combination is only compared with the single-drug effects. However, doing so could miss “hidden” cases of suppression, which occur when the highest order is suppressive compared with a lower-order combination but not to a single drug. We examined an extensive dataset of 5-drug combinations and all lower-order—single, 2-, 3-, and 4-drug—combinations. We found that a majority of all combinations—54%—contain hidden suppression. Examining hidden interactions is critical to understanding the architecture of higher-order interactions and can substantially affect our understanding and predictions of the evolution of antibiotic resistance under multi-drug treatments.

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“…To do so, standard practice calls for aggressive drug treatment to rapidly remove the drug-sensitive pathogen population and prevent resistance-conferring mutations [7][8][9][10][11][12][13][14][15][16][17]. Aggressive treatment can involve either single-drug or combination therapies, which have been shown to modulate the emergence of resistance [18][19][20][21][22][23][24][25]. Here, we are interested in situations in which such aggressive regimens do not completely prevent the emergence of resistance-for example, scenarios in which resistance is already present at the onset of treatment.…”

Section: Introductionmentioning

confidence: 99%

Antibiotics can be used to contain drug-resistant bacteria by maintaining sufficiently large sensitive populations

et al. 2020

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Standard infectious disease practice calls for aggressive drug treatment that rapidly eliminates the pathogen population before resistance can emerge. When resistance is absent, this elimination strategy can lead to complete cure. However, when resistance is already present, removing drug-sensitive cells as quickly as possible removes competitive barriers that may slow the growth of resistant cells. In contrast to the elimination strategy, a containment strategy aims to maintain the maximum tolerable number of pathogens, exploiting competitive suppression to achieve chronic control. Here, we combine in vitro experiments in computer-controlled bioreactors with mathematical modeling to investigate whether containment strategies can delay failure of antibiotic treatment regimens. To do so, we measured the "escape time" required for drug-resistant Escherichia coli populations to eclipse a threshold density maintained by adaptive antibiotic dosing. Populations containing only resistant cells rapidly escape the threshold density, but we found that matched resistant populations that also contain the maximum possible number of sensitive cells could be contained for significantly longer. The increase in escape time occurs only when the threshold density-the acceptable bacterial burden-is sufficiently high, an effect that mathematical models attribute to increased competition. The findings provide decisive experimental confirmation that maintaining the maximum number of sensitive cells can be used to contain resistance when the size of the population is sufficiently large.

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Antibiotic interactions shape short-term evolution of resistance in E. faecalis

Cited by 28 publications

References 62 publications

Price equation captures the role of drug interactions and collateral effects in the evolution of multidrug resistance

Price equation captures the role of drug interactions and collateral effects in the evolution of multidrug resistance

Hidden suppressive interactions are common in higher-order drug combinations

Antibiotics can be used to contain drug-resistant bacteria by maintaining sufficiently large sensitive populations

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