Mutations in dnaA and a cryptic interaction site increase drug resistance in Mycobacterium tuberculosis

Hicks, Nathan D.; Giffen, Samantha R.; Culviner, Peter H.; Chao, Michael C.; Dulberger, Charles L.; Liu, Qingyun; Stanley, Sydney; Brown, J. A.; Sixsmith, Jaimie; Wolf, Ian D.; Fortune, Sarah M.

doi:10.1371/journal.ppat.1009063

Cited by 26 publications

(42 citation statements)

References 59 publications

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“…The resistance mechanisms involved seem to be multiple and diverse. For instance, two of the genes with the most mutations in resistant strains are dnaA and mutT4 , which are involved in DNA replication and may affect the acquisition of resistance by increasing mutation rate or indirect mechanisms such as decreasing expression levels of katG 24 . Other interesting genes in the candidate set are those encoding epoxide hydrolases ( ephD and ephF ), which are involved in detoxification following oxidative damage to lipids.…”

Section: Resultsmentioning

confidence: 99%

An evolutionary functional genomics approach identifies novel candidate regions involved in isoniazid resistance in Mycobacterium tuberculosis

et al. 2021

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Efforts to eradicate tuberculosis are hampered by the rise and spread of antibiotic resistance. Several large-scale projects have aimed to specifically link clinical mutations to resistance phenotypes, but they were limited in both their explanatory and predictive powers. Here, we combine functional genomics and phylogenetic associations using clinical strain genomes to decipher the architecture of isoniazid resistance and search for new resistance determinants. This approach has allowed us to confirm the main target route of the antibiotic, determine the clinical relevance of redox metabolism as an isoniazid resistance mechanism and identify novel candidate genes harboring resistance mutations in strains with previously unexplained isoniazid resistance. This approach can be useful for characterizing how the tuberculosis bacilli acquire resistance to new antibiotics and how to forestall them.

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Section: Resultsmentioning

confidence: 99%

An evolutionary functional genomics approach identifies novel candidate regions involved in isoniazid resistance in Mycobacterium tuberculosis

et al. 2021

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“…Mutations in DnaA that compromise its ATPase activity would help achieve this. Second, DnaA mutations in clinical and laboratory strains of M. tuberculosis have been associated with isoniazid resistance due to altered gene expression profiles ( Hicks et al, 2020 ), and a similar mechanism may be operative in the case of E. coli and trimethoprim. The appearance of mutations at these loci only at high antibiotic pressure is likely to be a result of the higher pressure for resistance.…”

Section: Discussionmentioning

confidence: 99%

Adaptation and compensation in a bacterial gene regulatory network evolving under antibiotic selection

Patel

Matange

2021

eLife

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Gene regulatory networks allow organisms to generate coordinated responses to environmental challenges. In bacteria, regulatory networks are re-wired and re-purposed during evolution, though the relationship between selection pressures and evolutionary change is poorly understood. In this study, we discover that the early evolutionary response of Escherichia coli to the antibiotic trimethoprim involves derepression of PhoPQ signaling, an Mg2+-sensitive two-component system, by inactivation of the MgrB feedback-regulatory protein. We report that derepression of PhoPQ confers trimethoprim-tolerance to E. coli by hitherto unrecognized transcriptional upregulation of dihydrofolate reductase (DHFR), target of trimethoprim. As a result, mutations in mgrB precede and facilitate the evolution of drug resistance. Using laboratory evolution, genome sequencing, and mutation re-construction, we show that populations of E. coli challenged with trimethoprim are faced with the evolutionary ‘choice’ of transitioning from tolerant to resistant by mutations in DHFR, or compensating for the fitness costs of PhoPQ derepression by inactivating the RpoS sigma factor, itself a PhoPQ-target. Outcomes at this evolutionary branch-point are determined by the strength of antibiotic selection, such that high pressures favor resistance, while low pressures favor cost compensation. Our results relate evolutionary changes in bacterial gene regulatory networks to strength of selection and provide mechanistic evidence to substantiate this link.

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“…Mutations in DnaA that compromise its ATPase activity would help achieve this. Secondly, DnaA mutations in clinical and laboratory strains of Mycobacterium tuberculosis have been associated with isoniazid resistance due to altered gene expression profiles [66], and a similar mechanism may be operative in the case of E. coli and trimethoprim. The appearance of mutations at these loci only at high antibiotic pressure are likely to be a result of the higher pressure for resistance.…”

Section: Discussionmentioning

confidence: 99%

Adaptation and Compensation in a Bacterial Gene Regulatory Network Evolving Under Antibiotic Selection

Patel

Matange

2021

Preprint

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Gene regulatory networks allow organisms to generate coordinated responses to environmental challenges. In bacteria, regulatory networks are re-wired and re-purposed during evolution, though the relationship between selection pressures and evolutionary change is poorly understood. In this study, we discover that early evolutionary response of Escherichia coli to the antibiotic trimethoprim involves de-repression of PhoPQ signalling, a Mg2+-sensitive two-component system, by inactivation of the MgrB feedback-regulatory protein. We report that de-repression of PhoPQ confers trimethoprim-tolerance to E. coli by hitherto unrecognized transcriptional up-regulation of dihydrofolate reductase (DHFR), target of trimethoprim. As a result, mutations in mgrB precede and facilitate the evolution of drug resistance. Using laboratory evolution, genome sequencing and mutation re-construction, we show that populations of E. coli challenged with trimethoprim are faced with the evolutionary "choice" of transitioning from tolerant to resistant by mutations in DHFR, or compensating for the fitness costs of PhoPQ de-repression by inactivating the RpoS sigma factor, itself a PhoPQ-target. Outcomes at this evolutionary branch-point are determined by strength of antibiotic selection, such that high pressures favour resistance, while low pressures favour cost-compensation. Our results relate evolutionary changes in bacterial gene regulatory networks to strength of selection and provide mechanistic evidence to substantiate this link.

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Mutations in dnaA and a cryptic interaction site increase drug resistance in Mycobacterium tuberculosis

Cited by 26 publications

References 59 publications

An evolutionary functional genomics approach identifies novel candidate regions involved in isoniazid resistance in Mycobacterium tuberculosis

An evolutionary functional genomics approach identifies novel candidate regions involved in isoniazid resistance in Mycobacterium tuberculosis

Adaptation and compensation in a bacterial gene regulatory network evolving under antibiotic selection

Adaptation and Compensation in a Bacterial Gene Regulatory Network Evolving Under Antibiotic Selection

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