Genomic evolution of antibiotic resistance is contingent on genetic background following a long-term experiment with
            <i>Escherichia coli</i>

Card, Kyle J.; Thomas, Misty D.; Graves, Joseph L.; Barrick, Jeffrey E.; Lenski, Richard E.

doi:10.1073/pnas.2016886118

Cited by 55 publications

(56 citation statements)

References 55 publications

(80 reference statements)

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“…Interestingly, a similar role of the genetic background influencing the genomic basis of antibiotic resistance by channelling evolution along different mutational paths has been reported following a long-term in vitro evolution experiment with E. coli [49].…”

Section: Discussionmentioning

confidence: 75%

“…Such a functional redundancy suggests that the E. coli phylogroups were exposed to the same antibiotic pressure but acquired different ARGs to cope with it in an adaptive convergence process. Interestingly, a similar role of the genetic background influencing the genomic basis of antibiotic resistance by channelling evolution along different mutational paths has been reported following a long-term in vitro evolution experiment with E. coli [ 49 ].…”

Section: Discussionmentioning

confidence: 75%

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Phylum barrier and Escherichia coli intra-species phylogeny drive the acquisition of antibiotic-resistance genes

et al. 2021

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Escherichia coli is a ubiquitous bacterium that has been widely exposed to antibiotics over the last 70 years. It has adapted by acquiring different antibiotic-resistance genes (ARGs), the census of which we aim to characterize here. To do so, we analysed 70 301 E. coli genomes obtained from the EnteroBase database and detected 1 027 651 ARGs using the AMRFinder, Mustard and ResfinderFG ARG databases. We observed a strong phylogroup and clonal lineage specific distribution of some ARGs, supporting the argument for epistasis between ARGs and the strain genetic background. However, each phylogroup had ARGs conferring a similar antibiotic class resistance pattern, indicating phenotypic adaptive convergence. The G+C content or the type of ARG was not associated with the frequency of the ARG in the database. In addition, we identified ARGs from anaerobic, non- Proteobacteria bacteria in four genomes of E. coli , supporting the hypothesis that the transfer between anaerobic bacteria and E. coli can spontaneously occur but remains exceptional. In conclusion, we showed that phylum barrier and intra-species phylogenetic history are major drivers of the acquisition of a resistome in E. coli .

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Section: Discussionmentioning

confidence: 75%

Section: Discussionmentioning

confidence: 75%

Phylum barrier and Escherichia coli intra-species phylogeny drive the acquisition of antibiotic-resistance genes

et al. 2021

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“…Laboratory-based experimental evolution experiments have been extensively used to replicate bacterial adaptation during antibiotic therapy (MacLean et al, 2010; Palmer and Kishony, 2013; Cabot et al, 2014; Baym et al, 2016; Card et al, 2019; Windels et al, 2020; Card et al, 2021). This approach reduces complexity in order to establish reproducible and well-controlled conditions, from which evolutionary changes and mutational trajectories can be analyzed.…”

Section: Discussionmentioning

confidence: 99%

“…Our current knowledge regarding the evolution of bacterial antibiotic resistance mainly comes from clinical, microbiological and biochemical studies that are performed under highly controlled conditions (Elena and Lenski, 2003; Weinreich et al, 2006; MacLean et al, 2010; Palmer and Kishony, 2013; Baym et al, 2016; Boolchandani et al, 2019; Card et al, 2021). Collectively, we have learned that the emergence and evolution of antibiotic resistance, one of the greatest challenges to our civilization, is a far more complex phenomenon; few studies exist that offer insights into “real-world” scenarios that adequately or completely explain evolutionary trajectories that shape existing phenotypes (Bershtein et al, 2006; Meini et al, 2015; Stiffler et al, 2015; Prickett et al, 2017; Frimodt-Møller et al, 2018; Andersson et al, 2020; Mehlhoff et al, 2020).…”

Section: Introductionmentioning

confidence: 99%

Development of antibiotic resistance reveals diverse evolutionary pathways to face the complex and dynamic environment of a long-term treated patient

Colque

Tomatis

Orio

et al. 2021

Preprint

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Bacteria are endowed with a unique ability to adapt to challenging environments. The evolution of bacterial populations during chronic infections involves a large diversity of adaptive mechanisms that cannot always be reproduced upon controlled laboratory conditions. This creates a gap between the phenotypical description and the underlying biochemical processes that drive that phenotype. Herein, we address the complexity of the bacterial adaptive response to antibiotic selective pressures by studying the in-patient evolution of a broad diversity of β-lactam resistant Pseudomonas aeruginosa hypermutator clones. By using mutational and ultra-deep amplicon sequencing analysis, we analyzed multiple generations of a P. aeruginosa hypermutator strain persisting for more than 26 years of chronic infection in the airways of a cystic fibrosis patient. We identify the accumulation of multiple alterations targeting the chromosomally encoded class C β-lactamase (blaPDC), providing structural and functional protein changes that resulted in a continuous enhancement of its catalytic efficiency and high level of cephalosporin resistance. This evolution was linked to the persistent treatment with ceftazidime, which we demonstrate selected for variants with robust catalytic activity against this expanded-spectrum cephalosporin. Surprisingly, 'a gain of function' of collateral resistance towards ceftolozane, a more recently introduced cephalosporin that was not prescribed to this patient, was also observed and the biochemical basis of this cross-resistance phenomenon was elucidated. This work pinpoints the considerable evolutionary potential of hypermutator strains and uncovers the link between the antibiotic prescription history and the in-patient evolution of resistance.

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“…Furthermore, urinary tract infections may lead to some serious diseases that span from the gastrointestinal tract to extraintestinal sites such as the blood stream and central nervous system, which can be life-threatening [ 7 , 8 ]. Antibiotic treatment is currently the most effective method, but it is easy to promote the emergence of multi-drug resistant E. coli , which constitutes one of the dominant challenges to human health [ 9 , 10 , 11 ]. Additionally, the obvious and continuous decrease in the number of approved antibiotics in the past 10 years has exacerbated the increasingly threatening circumstances [ 12 , 13 ].…”

Section: Introductionmentioning

confidence: 99%

Plasmon-Enhanced Antibacterial Activity of Chiral Gold Nanoparticles and In Vivo Therapeutic Effect

Wang

Zhang

et al. 2021

Nanomaterials

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d-cysteine (d-cys) has been demonstrated to possess an extraordinary antibacterial activity because of its unique steric configuration. However, inefficient antibacterial properties seriously hinder its wide applications. Here, cysteine-functionalized gold nanoparticles (d-/l-Au NPs) were prepared by loading d-/l-cysteine on the surface of gold nanoparticles for the effective inhibition of Escherichia coli (E. coli) in vitro and in vivo, and the effects on the intestinal microflora in mice were explored during the treatment of E. coli infection in the gut. We found that the antibacterial activity of d-/l-Au NPs was more than 2–3 times higher than pure d-cysteine, l-cysteine and Au NPs. Compared with l-Au NPs, d-Au NPs showed the stronger antibacterial activity, which was related to its unique steric configuration. Chiral Au NPs showed stronger destructive effects on cell membrane compared to other groups, which further leads to the leakage of the cytoplasm and bacterial cell death. The in vivo antibacterial experiment illustrated that d-Au NPs displayed impressive antibacterial activity in the treatment of E. coli-infected mice comparable to kanamycin, whereas they could not affect the balance of intestinal microflora. This work is of great significance in the development of an effective chiral antibacterial agent.

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Genomic evolution of antibiotic resistance is contingent on genetic background following a long-term experiment with Escherichia coli

Cited by 55 publications

References 55 publications

Phylum barrier and Escherichia coli intra-species phylogeny drive the acquisition of antibiotic-resistance genes

Phylum barrier and Escherichia coli intra-species phylogeny drive the acquisition of antibiotic-resistance genes

Development of antibiotic resistance reveals diverse evolutionary pathways to face the complex and dynamic environment of a long-term treated patient

Plasmon-Enhanced Antibacterial Activity of Chiral Gold Nanoparticles and In Vivo Therapeutic Effect

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