rSalvador: An R Package for the Fluctuation Experiment

Zheng, Qi

doi:10.1534/g3.117.300120

Cited by 98 publications

(113 citation statements)

References 44 publications

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“…To calculate per-base substitution rates, fluctuation data were analyzed by the maximum likelihood method, implemented using newton.LD.plating in rSalvador 1.7 (Zheng, 2017). Phenotypic mutation rates were calculated by normalizing to the average number of cells per culture.…”

Section: Star Methodsmentioning

confidence: 99%

Scalable, Continuous Evolution of Genes at Mutation Rates above Genomic Error Thresholds

Ravikumar

Arzumanyan

Obadi

et al. 2018

Cell

221

202

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Summary Directed evolution is a powerful approach for engineering biomolecules and understanding adaptation. However, experimental strategies for directed evolution are notoriously laborintensive and low-throughput, limiting access to demanding functions, multiple functions in parallel, and the study of molecular evolution in replicate. We report OrthoRep, an orthogonal DNA polymerase-plasmid pair in yeast that stably mutates ~100,000-fold faster than the host genome in vivo, exceeding the error threshold of genomic replication that causes singlegeneration extinction. User-defined genes in OrthoRep continuously and rapidly evolve through serial passaging, a highly straightforward and scalable process. Using OrthoRep, we evolved drug-resistant malarial DHFRs in 90 independent replicates. We uncovered a more complex fitness landscape than previously realized, including common adaptive trajectories constrained by epistasis, rare outcomes that avoid a frequent early adaptive mutation, and a suboptimal fitness peak that occasionally traps evolving populations. OrthoRep enables a new paradigm of routine, high-throughput evolution of biomolecular and cellular function.

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Section: Star Methodsmentioning

confidence: 99%

Scalable, Continuous Evolution of Genes at Mutation Rates above Genomic Error Thresholds

Ravikumar

Arzumanyan

Obadi

et al. 2018

Cell

221

202

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“…This is a maximum likelihood-based method for inferring mutation rates from fluctuation test colony counts, based on the classic Luria-Delbrück (LD) distribution with a correction to account for the effects of partial plating (i.e. plating a portion of each culture rather than the total volume) 77 . We chose this method because it has been shown to be the most accurate estimator of m when partial plating is involved 77,78 .…”

Section: Fluctuation Tests Calculation Of Mutation Rates and Model mentioning

confidence: 99%

“…plating a portion of each culture rather than the total volume) 77 . We chose this method because it has been shown to be the most accurate estimator of m when partial plating is involved 77,78 . To get µapp (apparent mutation rate per generation) from m, we divided m by the total number of cells per parallel culture 77 , as estimated from the mean number of CFUs counted for the six representative cultures.…”

Section: Fluctuation Tests Calculation Of Mutation Rates and Model mentioning

confidence: 99%

“…To compare the Hamon and Ycart model to the mixed LD-Poisson model, we simply compared the negative loglikelihoods (smaller values indicate a better fit); the likelihood ratio test was not applicable as these two models contain the same number of parameters. Note that although the Hamon and Ycart (or in some cases, LD-Poisson) models were often better fits than the basic LD model, we still used the basic LD model for statistical comparison of mutation rates between conditions, because an accurate method to account for partial plating has not yet been developed for the cases of post-plating mutations or differential fitness between mutants and parent strains 77 .…”

Section: Fluctuation Tests Calculation Of Mutation Rates and Model mentioning

confidence: 99%

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Bacterial defenses against a natural antibiotic promote collateral resilience to clinical antibiotics

Meirelles

Perry

Bergkessel

et al. 2020

Preprint

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As antibiotic-resistant infections become increasingly prevalent worldwide, understanding the factors that lead to antimicrobial treatment failure is essential to optimizing the use of existing drugs. Opportunistic human pathogens in particular typically exhibit high levels of intrinsic antibiotic resistance and tolerance 1 , leading to chronic infections that can be nearly impossible to eradicate 2 . We asked whether the recalcitrance of these organisms to antibiotic treatment could be driven in part by their evolutionary history as environmental microbes, which frequently produce or encounter natural antibiotics 3,4 . Using the opportunistic pathogen Pseudomonas aeruginosa as a model, we demonstrate that the self-produced natural antibiotic pyocyanin (PYO) activates bacterial defenses that confer collateral tolerance to certain synthetic antibiotics, including in a clinically-relevant growth medium. Non-PYO-producing opportunistic pathogens isolated from lung infections similarly display increased antibiotic tolerance when they are co-cultured with PYO-producing P. aeruginosa. Furthermore, we show that beyond promoting bacterial survival in the presence of antibiotics, PYO can increase the apparent rate of mutation to antibiotic resistance by up to two orders of magnitude. Our work thus suggests that bacterial production of natural antibiotics in infections could play an important role in modulating not only the immediate efficacy of clinical antibiotics, but also the rate at which antibiotic resistance arises in multispecies bacterial communities.

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“…Likelihood Ratio Test (LRT) using the rSalvador R package (Zheng 2015(Zheng , 2017. LRT estimates the 600 overlap between confidence intervals calculated for two fluctuation experiment data sets and allows 601 to compare fluctuation assay data with different number of cultures and resolve very small differences 602 in mutation rate (Zheng 2015(Zheng , 2017.…”

Section: Statistical Analysis 593mentioning

confidence: 99%

Evolutionary epidemiology ofStreptococcus iniae: linking mutation rate dynamics with adaptation to novel immunological landscapes

Silayeva

Engelstädter

Barnes

2018

Preprint

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Pathogens continuously adapt to changing host environments where variation in their virulence and antigenicity is critical to their long-term evolutionary success. The emergence of novel variants is accelerated in microbial mutator strains (mutators) deficient in DNA repair genes, most often from mismatch repair and oxidised-guanine repair systems (MMR and OG respectively). Bacterial MMR/OG mutants are abundant in clinical samples and show increased adaptive potential in experimental infection models, yet the role of mutators in the epidemiology and evolution of infectious disease is not well understood. Here we investigated the role of mutation rate dynamics in the evolution of a broad host range pathogen, Streptococcus iniae, using a set of 80 strains isolated globally over 40 years. We have resolved phylogenetic relationships using non-recombinant core genome variants, measured in vivo mutation rates by fluctuation analysis, identified variation in major MMR/OG genes and their regulatory regions, and phenotyped the major traits determining virulence in streptococci. We found that both mutation rate and MMR/OG genotype are remarkably conserved within phylogenetic clades but significantly differ between major phylogenetic lineages. Further, variation in MMR/OG loci correlates with occurrence of atypical virulence-associated phenotypes, infection in atypical hosts (mammals), and atypical tissue of a vaccinated primary hosts (barramundi bone). These findings suggest that mutators are likely to facilitate adaptations preceding major diversification events, and may promote emergence of variation permitting colonisation of a novel host tissue, novel host taxa (host jumps), and immune-escape in the vaccinated host.

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rSalvador: An R Package for the Fluctuation Experiment

Cited by 98 publications

References 44 publications

Scalable, Continuous Evolution of Genes at Mutation Rates above Genomic Error Thresholds

Scalable, Continuous Evolution of Genes at Mutation Rates above Genomic Error Thresholds

Bacterial defenses against a natural antibiotic promote collateral resilience to clinical antibiotics

Evolutionary epidemiology ofStreptococcus iniae: linking mutation rate dynamics with adaptation to novel immunological landscapes

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