Abstract
Bacterial populations vary in their stress tolerance and population structure depending upon whether growth occurs in well-mixed or structured environments. We hypothesized that evolution in biofilms would generate greater genetic diversity than well-mixed environments and lead to different pathways of antibiotic resistance. We used experimental evolution and whole genome sequencing to test how the biofilm lifestyle influenced the rate, genetic mechanisms, and pleiotropic effects of resistance to ciprofloxacin in Acinetobacter baumannii populations. Both evolutionary dynamics and the identities of mutations differed between lifestyle. Planktonic populations experienced selective sweeps of mutations including the primary topoisomerase drug targets, whereas biofilm-adapted populations acquired mutations in regulators of efflux pumps. An overall trade-off between fitness and resistance level emerged, wherein biofilm-adapted clones were less resistant than planktonic but more fit in the absence of drug. However, biofilm populations developed collateral sensitivity to cephalosporins, demonstrating the clinical relevance of lifestyle on the evolution of resistance.
Highlights
Antimicrobial resistance (AMR) is one of the main challenges facing modern medicine
The dominant mode of growth for most microbes is on surfaces, and this biofilm lifestyle is central to AMR (Høiby et al, 2010; Olsen, 2015; Ahmed et al, 2018), especially in chronic infections (Wolcott et al, 2010; Wolcott, 2017)
Planktonic populations were serially passaged by daily 1:100 dilution while biofilm populations were propagated using a bead model simulating the biofilm life cycle (Poltak and Cooper, 2011; Traverse et al, 2013; Turner et al, 2018). This model selects for bacteria that attach to a 7 mm polystyrene bead, form a biofilm, and disperse to colonize a new bead each day. (A video tutorial for this protocol is available at http://evolvingstem.org/see-it-inaction)
Summary
Antimicrobial resistance (AMR) is one of the main challenges facing modern medicine. The dominant mode of growth for most microbes is on surfaces, and this biofilm lifestyle is central to AMR (Høiby et al, 2010; Olsen, 2015; Ahmed et al, 2018), especially in chronic infections (Wolcott et al, 2010; Wolcott, 2017). With few exceptions (Ridenhour et al, 2017; Ahmed et al, 2018; France et al, 2019), most of the research on the evolution of AMR has been conducted in well-mixed populations (reviewed in Hughes and Andersson, 2017) or on agar plates (Baym et al, 2016a), conditions that cannot simulate the effects of biofilms on the evolution of AMR.
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