Clinically relevant mutations in core metabolic genes confer antibiotic resistance

Lopatkin, Allison J.; Bening, Sarah C; McGuire, Abigail Manson; Stokes, Jonathan; Kohanski, Michael A.; Badran, Ahmed H.; Earl, Ashlee M.; Cheney, Nicole J.; Yang, Jason H.; Collins, James J.

doi:10.1126/science.aba0862

Cited by 251 publications

(225 citation statements)

References 57 publications

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“…Enrichment of translation and ribosomal structure genes (COG J), and energy production genes (COG C) in trimethoprim/sulfonamide group might be due to altered metabolism and changes in energy production leading to bacterial persistence and escape of antibiotic effect [61,62]. Similar findings were recently reported by Lopatkin et al [63] where it was shown that mutations in metabolic genes, in particular, central carbon and energy metabolism genes, lead to the increased antibiotic resistance. Ultimately, GWAS is a promising approach for a systematic innately complex bacterial resistance analysis, which could be applied to better understand the genetics of antibiotic resistance development.…”

Section: Discussionsupporting

confidence: 76%

Achromobacter spp. genetic adaptation in cystic fibrosis

et al. 2021

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Achromobacter spp. are emerging pathogens in patients with cystic fibrosis (CF) and Achromobacter spp. caused infections are associated with more severe disease outcomes and high intrinsic antibiotic resistance. While conventional CF pathogens are studied extensively, little is known about the genetic determinants leading to antibiotic resistance and the genetic adaptation in Achromobacter spp. infections. Here, we analysed 101 Achromobacter spp. genomes from 51 patients with CF isolated during the course of up to 20 years of infection to identify within-host adaptation, mutational signatures and genetic variation associated with increased antibiotic resistance. We found that the same regulatory and inorganic ion transport genes were frequently mutated in persisting clone types within and between Achromobacter species, indicating convergent genetic adaptation. Genome-wide association study of six antibiotic resistance phenotypes revealed the enrichment of associated genes involved in inorganic ion transport, transcription gene enrichment in β-lactams, and energy production and translation gene enrichment in the trimethoprim/sulfonamide group. Overall, we provide insights into the pathogenomics of Achromobacter spp. infections in patients with CF airways. Since emerging pathogens are increasingly recognized as an important healthcare issue, our findings on evolution of antibiotic resistance and genetic adaptation can facilitate better understanding of disease progression and how mutational changes have implications for patients with CF.

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Section: Discussionsupporting

confidence: 76%

Achromobacter spp. genetic adaptation in cystic fibrosis

et al. 2021

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“…These changes are evidence of the complementary role of GlpK. Based on this global deregulation, we hypothesize a diversified strategy led by GlpK to overcome antagonism in nutritional competitive scenarios (Figure 6C), supporting the recent ecological concept where new antibiotic resistance strategies point to the importance of mutations in metabolic genes (Lopatkin et al, 2021). First, GlpK causes the induction of sporulation and transcriptional changes in carbon source acquisition genes.…”

Section: Discussionsupporting

confidence: 71%

Chemical interplay and complementary adaptative strategies toggle bacterial antagonism and co-existence

Molina‐Santiago¹,

Vela‐Corcía²,

Petras³

et al. 2021

Cell Reports

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“…In recent years, advances in laboratory evolution, high-throughput sequencing, and computational biology have greatly expanded the scope of addressable questions in microbiology and the study of antibiotic resistance ( 16 ). For instance, adaptive laboratory evolution can simulate natural selection pressures ( 17 ), allowing researchers to study the emergence of novel antibiotic treatment phenotypes ( 18 ), as well as their relationship to environmental conditions ( 19 ). In many cases, these granular experimental techniques invite complementary computational modeling activities, from mechanistically simulating drug-target binding to predicting complex ecological dynamics, yielding deeper insights into clinical resistance phenomena.…”

Section: Digitalization In Clinical and Research Settingsmentioning

confidence: 99%

Digital Insights Into Nucleotide Metabolism and Antibiotic Treatment Failure

Lopatkin

Yang

2021

Front. Digit. Health

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Nucleotide metabolism plays a central role in bacterial physiology, producing the nucleic acids necessary for DNA replication and RNA transcription. Recent studies demonstrate that nucleotide metabolism also proactively contributes to antibiotic-induced lethality in bacterial pathogens and that disruptions to nucleotide metabolism contributes to antibiotic treatment failure in the clinic. As antimicrobial resistance continues to grow unchecked, new approaches are needed to study the molecular mechanisms responsible for antibiotic efficacy. Here we review emerging technologies poised to transform understanding into why antibiotics may fail in the clinic. We discuss how these technologies led to the discovery that nucleotide metabolism regulates antibiotic drug responses and why these are relevant to human infections. We highlight opportunities for how studies into nucleotide metabolism may enhance understanding of antibiotic failure mechanisms.

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Clinically relevant mutations in core metabolic genes confer antibiotic resistance

Cited by 251 publications

References 57 publications

Achromobacter spp. genetic adaptation in cystic fibrosis

Achromobacter spp. genetic adaptation in cystic fibrosis

Chemical interplay and complementary adaptative strategies toggle bacterial antagonism and co-existence

Digital Insights Into Nucleotide Metabolism and Antibiotic Treatment Failure

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