Your search keyword '"Rosanna C. T. Wright"' showing total 5 results

1. Cross-resistance is modular in bacteria-phage interactions.

Author

Rosanna C T Wright, Ville-Petri Friman, Margaret C M Smith, and Michael A Brockhurst

Subjects

Biology (General), QH301-705.5

Abstract

Phages shape the structure of natural bacterial communities and can be effective therapeutic agents. Bacterial resistance to phage infection, however, limits the usefulness of phage therapies and could destabilise community structures, especially if individual resistance mutations provide cross-resistance against multiple phages. We currently understand very little about the evolution of cross-resistance in bacteria-phage interactions. Here we show that the network structure of cross-resistance among spontaneous resistance mutants of Pseudomonas aeruginosa evolved against each of 27 phages is highly modular. The cross-resistance network contained both symmetric (reciprocal) and asymmetric (nonreciprocal) cross-resistance, forming two cross-resistance modules defined by high within- but low between-module cross-resistance. Mutations conferring cross-resistance within modules targeted either lipopolysaccharide or type IV pilus biosynthesis, suggesting that the modularity of cross-resistance was structured by distinct phage receptors. In contrast, between-module cross-resistance was provided by mutations affecting the alternative sigma factor, RpoN, which controls many lifestyle-associated functions, including motility, biofilm formation, and quorum sensing. Broader cross-resistance range was not associated with higher fitness costs or weaker resistance against the focal phage used to select resistance. However, mutations in rpoN, providing between-module cross-resistance, were associated with higher fitness costs than mutations associated with within-module cross-resistance, i.e., in genes encoding either lipopolysaccharide or type IV pilus biosynthesis. The observed structure of cross-resistance predicted both the frequency of resistance mutations and the ability of phage combinations to suppress bacterial growth. These findings suggest that the evolution of cross-resistance is common, is likely to play an important role in the dynamic structure of bacteria-phage communities, and could inform the design principles for phage therapy treatments.

Published

2018

2. Plasmid fitness costs are caused by specific genetic conflicts enabling resolution by compensatory mutation

Author

Katie J. Muddiman, Rosanna C. T. Wright, A. Jamie Wood, Steve Paterson, James P. J. Hall, Ellie Harrison, and Michael A. Brockhurst

Subjects

Evolutionary Genetics, Transcription, Genetic, Molecular biology, Operon, Gene Expression, medicine.disease_cause, Biochemistry, Plasmid, Mobile Genetic Elements, Biology (General), Genetics, 0303 health sciences, Experimental evolution, Mutation, General Neuroscience, Genomics, Chromosomes, Bacterial, Up-Regulation, Nucleic acids, Bioassays and Physiological Analysis, Conjugation, Genetic, Horizontal gene transfer, General Agricultural and Biological Sciences, Research Article, Plasmids, Pseudomonas Fluorescens, Forms of DNA, QH301-705.5, DNA transcription, Bacterial genome size, DNA construction, Biology, Models, Biological, General Biochemistry, Genetics and Molecular Biology, Evolution, Molecular, 03 medical and health sciences, Genetic Elements, Pseudomonas, medicine, Gene Disruption, Gene, 030304 developmental biology, Evolutionary Biology, Bacteria, General Immunology and Microbiology, 030306 microbiology, Fluorescence Competition, Organisms, Biology and Life Sciences, Gene Expression Regulation, Bacterial, DNA, Research and analysis methods, Molecular biology techniques, Plasmid Construction, Genetic Fitness, Mobile genetic elements

Abstract

Plasmids play an important role in bacterial genome evolution by transferring genes between lineages. Fitness costs associated with plasmid carriage are expected to be a barrier to gene exchange, but the causes of plasmid fitness costs are poorly understood. Single compensatory mutations are often sufficient to completely ameliorate plasmid fitness costs, suggesting that such costs are caused by specific genetic conflicts rather than generic properties of plasmids, such as their size, metabolic burden, or gene expression level. By combining the results of experimental evolution with genetics and transcriptomics, we show here that fitness costs of 2 divergent large plasmids in Pseudomonas fluorescens are caused by inducing maladaptive expression of a chromosomal tailocin toxin operon. Mutations in single genes unrelated to the toxin operon, and located on either the chromosome or the plasmid, ameliorated the disruption associated with plasmid carriage. We identify one of these compensatory loci, the chromosomal gene PFLU4242, as the key mediator of the fitness costs of both plasmids, with the other compensatory loci either reducing expression of this gene or mitigating its deleterious effects by up-regulating a putative plasmid-borne ParAB operon. The chromosomal mobile genetic element Tn6291, which uses plasmids for transmission, remained up-regulated even in compensated strains, suggesting that mobile genetic elements communicate through pathways independent of general physiological disruption. Plasmid fitness costs caused by specific genetic conflicts are unlikely to act as a long-term barrier to horizontal gene transfer (HGT) due to their propensity for amelioration by single compensatory mutations, helping to explain why plasmids are so common in bacterial genomes., Plasmids impose fitness costs on their hosts, but the underlying mechanisms have been unclear. This study shows that specific gene interactions, rather than general properties of plasmids such as their size, are principally responsible for the burden plasmids impose. The propensity of such conflicts to be ameliorated by single compensatory mutations may help to explain why plasmids are so widespread.

Published

2021

3. Cross-resistance is modular in bacteria–phage interactions

Author

Rosanna C. T. Wright, Margaret C. M. Smith, Ville-Petri Friman, and Michael A. Brockhurst

Subjects

0301 basic medicine, medicine.medical_treatment, Mutant, Drug Resistance, medicine.disease_cause, Pathology and Laboratory Medicine, Biochemistry, Sigma factor, Microbial Physiology, Medicine and Health Sciences, Bacteriophages, Biology (General), Genetics, Mutation, Agricultural and Biological Sciences(all), General Neuroscience, Microbial Mutation, Microbial Growth and Development, Pseudomonas Aeruginosa, Quorum Sensing, Bacterial Pathogens, Medical Microbiology, Viruses, Receptors, Virus, Cellular Structures and Organelles, Pathogens, General Agricultural and Biological Sciences, Research Article, Pathogen Motility, Virus genetics, Phage therapy, QH301-705.5, Virulence Factors, Neuroscience(all), 030106 microbiology, Biology, Biosynthesis, Microbiology, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, Pseudomonas, Immunology and Microbiology(all), medicine, Microbial Pathogens, Evolutionary Biology, Bacterial Evolution, General Immunology and Microbiology, Bacteria, Pseudomonas aeruginosa, Biochemistry, Genetics and Molecular Biology(all), Bacterial Growth, Organisms, Biology and Life Sciences, Bacteriology, Cell Biology, Organismal Evolution, Quorum sensing, Species Interactions, Pili and Fimbriae, Microbial Evolution, rpoN, Developmental Biology

Abstract

Phages shape the structure of natural bacterial communities and can be effective therapeutic agents. Bacterial resistance to phage infection, however, limits the usefulness of phage therapies and could destabilise community structures, especially if individual resistance mutations provide cross-resistance against multiple phages. We currently understand very little about the evolution of cross-resistance in bacteria–phage interactions. Here we show that the network structure of cross-resistance among spontaneous resistance mutants of Pseudomonas aeruginosa evolved against each of 27 phages is highly modular. The cross-resistance network contained both symmetric (reciprocal) and asymmetric (nonreciprocal) cross-resistance, forming two cross-resistance modules defined by high within- but low between-module cross-resistance. Mutations conferring cross-resistance within modules targeted either lipopolysaccharide or type IV pilus biosynthesis, suggesting that the modularity of cross-resistance was structured by distinct phage receptors. In contrast, between-module cross-resistance was provided by mutations affecting the alternative sigma factor, RpoN, which controls many lifestyle-associated functions, including motility, biofilm formation, and quorum sensing. Broader cross-resistance range was not associated with higher fitness costs or weaker resistance against the focal phage used to select resistance. However, mutations in rpoN, providing between-module cross-resistance, were associated with higher fitness costs than mutations associated with within-module cross-resistance, i.e., in genes encoding either lipopolysaccharide or type IV pilus biosynthesis. The observed structure of cross-resistance predicted both the frequency of resistance mutations and the ability of phage combinations to suppress bacterial growth. These findings suggest that the evolution of cross-resistance is common, is likely to play an important role in the dynamic structure of bacteria–phage communities, and could inform the design principles for phage therapy treatments., Author summary Phage therapy is a promising alternative to antibiotics for treating bacterial infections. Yet as with antibiotics, bacteria readily evolve resistance to phage attack, including cross-resistance that protects against multiple phages at once and so limits the usefulness of phage cocktails. Here we show, using laboratory experimental evolution of resistance against 27 phages in P. aeruginosa, that cross-resistance is common and determines the ability of phage combinations to suppress bacterial growth. Using whole-genome sequencing, we show that cross-resistance is most common against multiple phages that use the same receptor but that global regulator mutations provide generalist resistance, probably by simultaneously affecting the expression of multiple different phage receptors. Future trials should test if these features of cross-resistance evolution translate to more complex in vivo environments and can therefore be exploited to design more effective phage therapies for the clinic.

Published

2018

4. Identification of pathways to high-level vancomycin resistance in Clostridioides difficile that incur high fitness costs in key pathogenicity traits.

Author

Jessica E Buddle, Lucy M Thompson, Anne S Williams, Rosanna C T Wright, William M Durham, Claire E Turner, Roy R Chaudhuri, Michael A Brockhurst, and Robert P Fagan

Subjects

Biology (General), QH301-705.5

Abstract

Clostridioides difficile is an important human pathogen, for which there are very limited treatment options, primarily the glycopeptide antibiotic vancomycin. In recent years, vancomycin resistance has emerged as a serious problem in several gram-positive pathogens, but high-level resistance has yet to be reported for C. difficile, although it is not known if this is due to constraints upon resistance evolution in this species. Here, we show that resistance to vancomycin can evolve rapidly under ramping selection but is accompanied by fitness costs and pleiotropic trade-offs, including sporulation defects that would be expected to severely impact transmission. We identified 2 distinct pathways to resistance, both of which are predicted to result in changes to the muropeptide terminal D-Ala-D-Ala that is the primary target of vancomycin. One of these pathways involves a previously uncharacterised D,D-carboxypeptidase, expression of which is controlled by a dedicated two-component signal transduction system. Our findings suggest that while C. difficile is capable of evolving high-level vancomycin resistance, this outcome may be limited clinically due to pleiotropic effects on key pathogenicity traits. Moreover, our data identify potential mutational routes to resistance that should be considered in genomic surveillance.

Published

2024

5. Plasmid fitness costs are caused by specific genetic conflicts enabling resolution by compensatory mutation.

Author

James P J Hall, Rosanna C T Wright, Ellie Harrison, Katie J Muddiman, A Jamie Wood, Steve Paterson, and Michael A Brockhurst

Subjects

Biology (General), QH301-705.5

Abstract

Plasmids play an important role in bacterial genome evolution by transferring genes between lineages. Fitness costs associated with plasmid carriage are expected to be a barrier to gene exchange, but the causes of plasmid fitness costs are poorly understood. Single compensatory mutations are often sufficient to completely ameliorate plasmid fitness costs, suggesting that such costs are caused by specific genetic conflicts rather than generic properties of plasmids, such as their size, metabolic burden, or gene expression level. By combining the results of experimental evolution with genetics and transcriptomics, we show here that fitness costs of 2 divergent large plasmids in Pseudomonas fluorescens are caused by inducing maladaptive expression of a chromosomal tailocin toxin operon. Mutations in single genes unrelated to the toxin operon, and located on either the chromosome or the plasmid, ameliorated the disruption associated with plasmid carriage. We identify one of these compensatory loci, the chromosomal gene PFLU4242, as the key mediator of the fitness costs of both plasmids, with the other compensatory loci either reducing expression of this gene or mitigating its deleterious effects by up-regulating a putative plasmid-borne ParAB operon. The chromosomal mobile genetic element Tn6291, which uses plasmids for transmission, remained up-regulated even in compensated strains, suggesting that mobile genetic elements communicate through pathways independent of general physiological disruption. Plasmid fitness costs caused by specific genetic conflicts are unlikely to act as a long-term barrier to horizontal gene transfer (HGT) due to their propensity for amelioration by single compensatory mutations, helping to explain why plasmids are so common in bacterial genomes.

Published

2021