Your search keyword '"James P. J. Hall"' showing total 28 results

1. A megaplasmid family driving dissemination of multidrug resistance in Pseudomonas

Author

Adrian Cazares, Pitak Santanirand, Matthew P. Moore, Craig Winstanley, Roger C. Levesque, Jean-Guillaume Emond-Rheault, Laura Wright, James P. J. Hall, Macauley Grimes, Pisut Pongchaikul, and Joanne L. Fothergill

Subjects

0301 basic medicine, DNA, Bacterial, Science, 030106 microbiology, General Physics and Astronomy, Microbial Sensitivity Tests, medicine.disease_cause, ENCODE, Antimicrobial resistance, General Biochemistry, Genetics and Molecular Biology, Article, Evolution, Molecular, Bacterial evolution, 03 medical and health sciences, Plasmid, Drug Resistance, Multiple, Bacterial, Pseudomonas, Gene duplication, medicine, Humans, Pseudomonas Infections, lcsh:Science, Gene, Phylogeny, Bacterial genomics, Whole genome sequencing, Genetics, Multidisciplinary, biology, Whole Genome Sequencing, Pseudomonas aeruginosa, General Chemistry, Genomics, biology.organism_classification, Thailand, 3. Good health, Anti-Bacterial Agents, Multiple drug resistance, 030104 developmental biology, Genes, Bacterial, lcsh:Q, Pathogens, Plasmids

Abstract

Multidrug resistance (MDR) represents a global threat to health. Here, we used whole genome sequencing to characterise Pseudomonas aeruginosa MDR clinical isolates from a hospital in Thailand. Using long-read sequence data we obtained complete sequences of two closely related megaplasmids (>420 kb) carrying large arrays of antibiotic resistance genes located in discrete, complex and dynamic resistance regions, and revealing evidence of extensive duplication and recombination events. A comprehensive pangenomic and phylogenomic analysis indicates that: 1) these large plasmids comprise an emerging family present in different members of the Pseudomonas genus, and associated with multiple sources (geographical, clinical or environmental); 2) the megaplasmids encode diverse niche-adaptive accessory traits, including multidrug resistance; 3) the accessory genome of the megaplasmid family is highly flexible and diverse. The history of the megaplasmid family, inferred from our analysis of the available database, suggests that members carrying multiple resistance genes date back to at least the 1970s., The emergence of multidrug resistance (MDR) in bacteria represents a global threat to human health. Here, Cazares et al. identify a family of MDR megaplasmids carrying large arrays of antibiotic resistance genes in Pseudomonas strains from various sources, including P. aeruginosa clinical isolates.

Published

2020

2. What makes a megaplasmid?

Author

James P. J. Hall, João Botelho, Adrian Cazares, and David A. Baltrus

Subjects

pangenome, megaplasmid, mobile genetic element, food and beverages, Articles, Biology, genome evolution, General Biochemistry, Genetics and Molecular Biology, Orders of magnitude (bit rate), Plasmid, Evolutionary biology, plasmid, Horizontal gene transfer, horizontal gene transfer, General Agricultural and Biological Sciences, Review Articles, Plasmids

Abstract

Naturally occurring plasmids come in different sizes. The smallest are less than a kilobase of DNA, while the largest can be over three orders of magnitude larger. Historically, research has tended to focus on smaller plasmids that are usually easier to isolate, manipulate and sequence, but with improved genome assemblies made possible by long-read sequencing, there is increased appreciation that very large plasmids—known as megaplasmids—are widespread, diverse, complex, and often encode key traits in the biology of their host microorganisms. Why are megaplasmids so big? What other features come with large plasmid size that could affect bacterial ecology and evolution? Are megaplasmids 'just' big plasmids, or do they have distinct characteristics? In this perspective, we reflect on the distribution, diversity, biology, and gene content of megaplasmids, providing an overview to these large, yet often overlooked, mobile genetic elements. This article is part of the theme issue ‘The secret lives of microbial mobile genetic elements’.

Published

2022

3. The dilution effect limits plasmid horizontal transmission in multispecies bacterial communities

Author

Anastasia Kottara, James P. J. Hall, Laura Carrilero, Michael A. Brockhurst, and Ellie Harrison

Subjects

Infection risk, Gene Transfer, Horizontal, Biology, Microbiology, 03 medical and health sciences, Plasmid, experimental evolution, plasmid transfer, 030304 developmental biology, Genetics, 0303 health sciences, Experimental evolution, Bacteria, conjugative plasmids, 030306 microbiology, Host (biology), Microbial Interactions and Communities, mobile genetic elements, bacterial communities, Dilution, Conjugation, Genetic, Horizontal gene transfer, horizontal gene transfer, Mobile genetic elements, human activities, Horizontal transmission, Plasmids

Abstract

By transferring ecologically important traits between species, plasmids drive genomic divergence and evolutionary innovation in their bacterial hosts. Bacterial communities are often diverse and contain multiple coexisting plasmids, but the dynamics of plasmids in multispecies communities are poorly understood. Here, we show, using experimental multispecies communities containing two plasmids, that bacterial diversity limits the horizontal transmission of plasmids due to ‘the dilution effect’; an epidemiological phenomenon whereby living alongside less proficient host species reduces the expected infection risk for a focal host species. In addition, plasmid horizontal transmission was also affected by plasmid diversity, such that the rate of plasmid conjugation was reduced from coinfected host cells carrying both plasmids. In diverse microbial communities, plasmid spread may be limited by the dilution effect and plasmid-plasmid interactions reducing the rate of horizontal transmission.

Published

2021

4. Positive selection inhibits plasmid coexistence in bacterial genomes

Author

James P. J. Hall, David Guymer, Michael A. Brockhurst, Anastasia Kottara, Ellie Harrison, and Laura Carrilero

Subjects

Bacterial genome size, Biology, Microbiology, Genome, 03 medical and health sciences, Negative selection, Plasmid, Virology, Replicon, experimental evolution, Selection, Genetic, Gene, Selection (genetic algorithm), 030304 developmental biology, Genetics, 0303 health sciences, Experimental evolution, Bacteria, 030306 microbiology, Horizontal gene transfer, Plasmid biology, Adaptation, Physiological, QR1-502, Phenotype, horizontal gene transfer, Genetic Fitness, Adaptation, Genome, Bacterial, Function (biology), Plasmids, Research Article, plasmid biology

Abstract

Plasmids play an important role in bacterial evolution by transferring niche-adaptive functional genes between lineages, thus driving genomic diversifica-tion. Bacterial genomes commonly contain multiple, coexisting plasmid replicons, which could fuel adaptation by increasing the range of gene functions available to selection and allowing their recombination. However, plasmid coexistence is difficult to explain because the acquisition of plasmids typically incurs high fitness costs for the host cell. Here, we show that plasmid coexistence was stably maintained without positive selection for plasmid-borne gene functions and was associated with compensatory evolution to reduce fitness costs. In contrast, with positive selection, plas-mid coexistence was unstable despite compensatory evolution. Positive selection dis-criminated between differential fitness benefits of functionally redundant plasmid replicons, retaining only the more beneficial plasmid. These data suggest that while the efficiency of negative selection against plasmid fitness costs declines over time due to compensatory evolution, positive selection to maximize plasmid-derived fitness benefits remains efficient. Our findings help to explain the forces structuring bacterial genomes: coexistence of multiple plasmids in a genome is likely to require either rare positive selection in nature or nonredundancy of accessory gene functions among the coexisting plasmids. IMPORTANCE Bacterial genomes often contain multiple coexisting plasmids that provide important functions like antibiotic resistance. Using lab experiments, we show that such plasmid coexistence within a genome is stable only in environments where the function they encode is useless but is unstable if the function is useful and beneficial for bacterial fitness. Where competing plasmids perform the same useful func-tion, only the most beneficial plasmid is kept by the cell, a process that is similar to competitive exclusion in ecological communities. This process helps explain how bacterial genomes are structured: bacterial genomes expand in size by acquiring multiple plasmids when selection is relaxed but subsequently contract during peri-ods of strong selection for the useful plasmid-encoded function.

Published

2021

5. Plasmid fitness costs are caused by specific genetic conflicts

Author

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

Subjects

Genetics, Experimental evolution, Plasmid, Operon, Horizontal gene transfer, Bacterial genome size, Mobile genetic elements, Biology, Gene, Reverse genetics

Abstract

Plasmids play an important role in bacterial genome evolution by transferring genes between lineages. Fitness costs associated with plasmid acquisition 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 expression level. Here we show — using a combination of experimental evolution, reverse genetics, and transcriptomics — that fitness costs of two divergent large plasmids inPseudomonas fluorescensare 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 acquisition. We identify one of these compensatory loci, the chromosomal genePFLU4242, 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 upregulating a putative plasmid-borne ParAB operon. The chromosomal mobile genetic element Tn6291, which uses plasmids for transmission, remained upregulated 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 due to their propensity for amelioration by single compensatory mutations, explaining why plasmids are so common in bacterial genomes.

Published

2021

6. The proficiency of the original host species determines community-level plasmid dynamics

Author

Michael A. Brockhurst, Anastasia Kottara, and James P. J. Hall

Subjects

0301 basic medicine, Gene Transfer, Horizontal, 030106 microbiology, Biology, Applied Microbiology and Biotechnology, Microbiology, Host Specificity, 03 medical and health sciences, Plasmid, Abundance (ecology), Gene, plasmid transfer, Genetics, Community level, Ecology, Bacteria, Resistance (ecology), conjugative plasmids, Host (biology), mobile genetic elements, bacterial communities, 030104 developmental biology, Conjugation, Genetic, Horizontal gene transfer, horizontal gene transfer, Mobile genetic elements, Plasmids

Abstract

Plasmids are common in natural bacterial communities, facilitating bacterial evolution via horizontal gene transfer. Bacterial species vary in their proficiency to host plasmids: whereas plasmids are stably maintained in some species regardless of selection for plasmid-encoded genes, in other species, even beneficial plasmids are rapidly lost. It is, however, unclear how this variation in host proficiency affects plasmid persistence in communities. Here, we test this using multispecies bacterial soil communities comprising species varying in their proficiency to host a large conjugative mercury resistance plasmid, pQBR103. The plasmid reached higher community-level abundance where beneficial and when introduced to the community in a more proficient host species. Proficient plasmid host species were also better able to disseminate the plasmid to a wider diversity of host species. These findings suggest that the dynamics of plasmids in natural bacterial communities depend not only upon the plasmid's attributes and the selective environment but also upon the proficiency of their host species.

Published

2020

7. The Impact of Mercury Selection and Conjugative Genetic Elements on Community Structure and Resistance Gene Transfer

Author

James P. J. Hall, Ellie Harrison, Katariina Pärnänen, Marko Virta, Michael A. Brockhurst, Department of Microbiology, and Antibiotic resistance in human impacted environments

Subjects

Microbiology (medical), BACTERIAL, mercury, FITNESS, Beta diversity, DIVERSITY, lcsh:QR1-502, Pseudomonas fluorescens, Biology, ECOLOGY, Microbiology, lcsh:Microbiology, soil, 03 medical and health sciences, Plasmid, TRANSPOSONS, Pseudomonas, Gene, 030304 developmental biology, Original Research, Genetics, 11832 Microbiology and virology, 0303 health sciences, SUGAR-BEET, Resistance (ecology), 030306 microbiology, conjugative plasmids, Community structure, mobile genetic elements, biology.organism_classification, bacterial communities, EVOLUTION, MOBILIZING CAPACITY, Horizontal gene transfer, HOST-RANGE PLASMIDS, 1182 Biochemistry, cell and molecular biology, horizontal gene transfer, PHYTOSPHERE, Mobile genetic elements

Abstract

Carriage of resistance genes can underpin bacterial survival, and by spreading these genes between species, mobile genetic elements (MGEs) can potentially protect diversity within microbial communities. The spread of MGEs could be affected by environmental factors such as selection for resistance, and biological factors such as plasmid host range, with consequences for individual species and for community structure. Here we cultured a focal bacterial strain, Pseudomonas fluorescens SBW25, embedded within a soil microbial community, with and without mercury selection, and with and without mercury resistance plasmids (pQBR57 or pQBR103), to investigate the effects of selection and resistance gene introduction on (1) the focal species; (2) the community as a whole; (3) the spread of the introduced mer resistance operon. We found that P. fluorescens SBW25 only escaped competitive exclusion by other members of community under mercury selection, even when it did not begin with a mercury resistance plasmid, due to its propensity to acquire resistance from the community by horizontal gene transfer. Mercury pollution had a significant effect on community structure, decreasing alpha diversity within communities while increasing beta diversity between communities, a pattern that was not affected by the introduction of mercury resistance plasmids by P. fluorescens SBW25. Nevertheless, the introduced merA gene spread to a phylogenetically diverse set of recipients over the 5 weeks of the experiment, as assessed by epicPCR. Our data demonstrates how the effects of MGEs can be experimentally assessed for individual lineages, the wider community, and for the spread of adaptive traits.

Published

2020

8. Characterisation of a new megaplasmid family associated with the spread of multidrug resistance in Pseudomonas aeruginosa

Author

Roger C. Levesque, Adrian Cazares, James P. J. Hall, Pitak Santanirand, Pisut Pongchaikul, Craig Winstanley, Jean-Guillaume Emond-Rheault, Laura Wright, J.L. Fothergill, and Macauley Grimes

Subjects

Genetics, Multiple drug resistance, Plasmid, Antibiotic resistance, Pseudomonas aeruginosa, Phylogenomics, medicine, General Materials Science, Plasmidome, Biology, medicine.disease_cause, Genome, DNA sequencing

Abstract

Unlike in other important pathogens, the role of plasmids in the emergence of antimicrobial resistance (AMR) in Pseudomonas aeruginosa (Pa) has remained largely unaddressed. Previous work on AMR in Pa has mostly used genome sequencing methods that are limited because of the difficulty of using short-read data to detect and reconstruct complex plasmids. Here, using superior long-read sequencing, comprehensive bioinformatics analyses, and experimental characterization, we uncover an emerging family of important Pseudomonas megaplasmids and report its contribution to dissemination of multidrug resistance (MDR) on a global scale. Firstly, we identified large plasmids with a key role in the spread of MDR in a hospital in Thailand, and characterised their resistance regions revealing evidence of duplication, recombination and shared repeats, indicative of dynamic adaptation. Applying phylogenomics and pangenomics approaches we linked related megaplasmids and defined a core and pangenome for the family, exposing wide variations in AMR genes carriage. We then surveyed thousands of publicly available genomes, leading to discovery of dozens of megaplasmid relatives overlooked in multiple datasets, including already published studies. By integrating all this information and looking beyond the pathogenic species we gained valuable insights into the evolution of the megaplasmid family and revealed its widespread and multispecies distribution. We also showed that members of this family are stable in the absence of antibiotic pressure, bear no fitness cost to their host, and can be readily transferred between different Pseudomonas species. Our findings expand the bacterial plasmidome and provide insights on how MDR plasmids emerge from environmental reservoirs.

Published

2020

9. 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

10. The evolution of plasmid stability: Are infectious transmission and compensatory evolution competing evolutionary trajectories?

Author

Michael A. Brockhurst, Calvin Dytham, Ellie Harrison, and James P. J. Hall

Subjects

0301 basic medicine, Gene Transfer, Horizontal, 030106 microbiology, Genetic Fitness, Mutagenesis (molecular biology technique), Biology, law.invention, 03 medical and health sciences, Negative selection, Plasmid, law, Selection, Genetic, Molecular Biology, Genetics, Models, Statistical, Bacteria, Gene Expression Regulation, Bacterial, Chromosomes, Bacterial, Biological Evolution, Mutagenesis, Insertional, Transmission (mechanics), Genetic Loci, Conjugation, Genetic, Horizontal gene transfer, Adaptation, Horizontal transmission, Plasmids

Abstract

Conjugative plasmids are widespread and play an important role in bacterial evolution by accelerating adaptation through horizontal gene transfer. However, explaining the long-term stability of plasmids remains challenging because segregational loss and the costs of plasmid carriage should drive the loss of plasmids though purifying selection. Theoretical and experimental studies suggest two key evolutionary routes to plasmid stability: First, the evolution of high conjugation rates would allow plasmids to survive through horizontal transmission as infectious agents, and second, compensatory evolution to ameliorate the cost of plasmid carriage can weaken purifying selection against plasmids. How these two evolutionary strategies for plasmid stability interact is unclear. Here, we summarise the literature on the evolution of plasmid stability and then use individual based modelling to investigate the evolutionary interplay between the evolution of plasmid conjugation rate and cost amelioration. We find that, individually, both strategies promote plasmid stability, and that they act together to increase the likelihood of plasmid survival. However, due to the inherent costs of increasing conjugation rate, particularly where conjugation is unlikely to be successful, our model predicts that amelioration is the more likely long-term solution to evolving stable bacteria-plasmid associations. Our model therefore suggests that bacteria-plasmid relationships should evolve towards lower plasmid costs that may forestall the evolution of highly conjugative, ‘infectious’ plasmids.

Published

2017

11. The Ecology and Evolution of Pangenomes

Author

Michael A. Brockhurst, Craig MacLean, Ellie Harrison, Alan McNally, James P. J. Hall, and Thomas A. Richards

Subjects

0301 basic medicine, Biology, Biological Evolution, Genome, General Biochemistry, Genetics and Molecular Biology, Evolution, Molecular, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, Evolutionary biology, Metagenomics, Phylogenetics, Host chromosome, Horizontal gene transfer, Metagenome, Evolutionary ecology, Mobile genetic elements, General Agricultural and Biological Sciences, Gene, Genome, Bacterial, Phylogeny, 030217 neurology & neurosurgery

Abstract

Since the first genome-scale comparisons, it has been evident that the genomes of many species are unbound by strict vertical descent: Large differences in gene content can occur among genomes belonging to the same prokaryotic species, with only a fraction of genes being universal to all genomes. These insights gave rise to the pangenome concept. The pangenome is defined as the set of all the genes present in a given species and can be subdivided into the accessory genome, present in only some of the genomes, and the core genome, present in all the genomes. Pangenomes arise due to gene gain by genomes from other species through horizontal gene transfer and differential gene loss among genomes, and have been described in both prokaryotes and eukaryotes. Our current view of pangenome variation is phenomenological and incomplete. In this review, we outline the mechanistic, ecological and evolutionary drivers of and barriers to horizontal gene transfer that are likely to structure pangenomes. We highlight the key role of conflict between the host chromosome(s) and the mobile genetic elements that mediate gene exchange. We identify shortcomings in our current models of pangenome evolution and suggest directions for future research to allow a more complete understanding of how and why pangenomes evolve.

Published

2019

12. Application of long read sequencing to determine expressed antigen diversity in Trypanosoma brucei infections

Author

Richard Reeve, Claire Harris, Tom Michoel, Christina A. Cobbold, Heli Vaikkinen, Christiane Hertz-Fowler, Liam J. Morrison, Anne-Marie Donachie, James P. J. Hall, Siddharth Jayaraman, Richard McCulloch, John Kenny, Luca Lenzi, and Edith Paxton

Subjects

0301 basic medicine, lcsh:Arctic medicine. Tropical medicine, Sequence analysis, lcsh:RC955-962, 030231 tropical medicine, Population, Trypanosoma brucei brucei, Gene Expression, Trypanosoma brucei, Host-Parasite Interactions, 03 medical and health sciences, Mice, 0302 clinical medicine, parasitic diseases, Antigenic variation, Animals, Allele, education, Gene, Genetics, education.field_of_study, biology, Repertoire, Gene Expression Profiling, lcsh:Public aspects of medicine, Public Health, Environmental and Occupational Health, High-Throughput Nucleotide Sequencing, lcsh:RA1-1270, Amplicon, biology.organism_classification, Phenotype, Antigenic Variation, Gene expression profiling, 030104 developmental biology, Infectious Diseases, Trypanosomiasis, African, Trypanosoma, Variant Surface Glycoproteins, Trypanosoma

Abstract

Antigenic variation is employed by many pathogens to evade the host immune response, andTrypanosoma bruceihas evolved a complex system to achieve this phenotype, involving sequential use of variant surface glycoprotein (VSG) genes encoded from a large repertoire of ∼2,000 alleles.T. bruceiexpress multiple, sometimes closely related, VSGs in a population at any one time, and the ability to resolve and analyse this diversity has been limited. We applied long read sequencing (PacBio) to VSG amplicons generated from blood extracted from batches of mice sacrificed at time points (days 3, 6, 10 and 12) post-infection with T. brucei TREU927. The data showed that long read sequencing is reliable for resolving allelic differences between VSGs, and demonstrated that there is significant expressed diversity (449 VSGs detected across 20 mice) and across the timeframe of study there was a clear semi-reproducible pattern of expressed diversity (median of 27 VSGs per sample at day 3 post infection (p.i.), 82 VSGs at day 6 p.i., 187 VSGs at day 10 p.i. and 132 VSGs by day 12 p.i.). There was also consistent detection of one VSG dominating expression across replicates at days 3 and 6, and emergence of a second dominant VSG across replicates by day 12. The innovative application of ecological diversity analysis to VSG reads enabled characterisation of hierarchical VSG expression in the dataset, and resulted in a novel method for analysing such patterns of variation. Additionally, the long read approach allowed detection of mosaic VSG expression from very few reads – this was observed as early as day 3, the earliest that such events have been detected. Therefore, our results indicate that long read analysis is a reliable tool for resolving diverse allele expression profiles, and provides novel insights into the complexity and nature of VSG expression in trypanosomes, revealing significantly higher diversity than previously shown and identifying mosaic gene formation unprecedentedly early during the infection process.

Published

2019

13. Coinfection promotes plasmid stability

Author

Michael A. Brockhurst, Laura Carrilero Aguado, and James P. J. Hall

Subjects

Genetics, biology, Pseudomonas fluorescens, Bacterial population, biology.organism_classification, medicine.disease, Plasmid, Horizontal gene transfer, Coinfection, medicine, General Materials Science, Mobile genetic elements, Recombination, Bacteria

Abstract

Bacteria exist in complex communities that include not only many other bacterial species but also diverse mobile genetic elements which accelerate bacterial evolution via horizontal gene transfer. How multiple mobile genetic elements interact in bacterial populations and how this affects plasmid dynamics remains poorly understood. We experimentally evolved populations of Pseudomonas fluorescens SBW25 either singly-infected or co-infected with two conjugative mercury resistance plasmids either with or without positive selection (i.e. addition of Hg(II)). We show that co-infection led to higher levels of mercury resistance in the bacterial population in the absence of positive selection. Consistent with this, in the absence of positive selection the plasmids could stably coexist within bacterial cells resulting in the maintenance co-infection. By contrast, with positive selection, plasmid coexistence was destabilised, leading to the dominance of a single plasmid in several replicate bacterial populations. Plasmid co-infection appears to alter the trajectory of compensatory evolution to ameliorate the cost of plasmid carriage and may have selected for alternative mechanisms compared to singly-infected populations. Stable plasmid co-infection without positive selection for plasmid-encoded traits suggests that environments where plasmids are useless may be hot-spots for genomic innovation via plasmid-plasmid recombination.

Published

2019

14. Migration promotes plasmid stability under spatially heterogeneous positive selection

Author

Ellie Harrison, Michael A. Brockhurst, and James P. J. Hall

Subjects

0301 basic medicine, Gene Transfer, Horizontal, Pseudomonas fluorescens, Biology, Environment, Stability (probability), General Biochemistry, Genetics and Molecular Biology, Mobile genetic element, Amelioration, 03 medical and health sciences, Negative selection, Plasmid, Environmental Science(all), Immunology and Microbiology(all), Species interactions, Selection, Genetic, Symbiosis, Gene, Selection (genetic algorithm), Compensatory evolution, General Environmental Science, Genetics, Experimental evolution, Extinction, General Immunology and Microbiology, Ecology, Agricultural and Biological Sciences(all), Biochemistry, Genetics and Molecular Biology(all), fungi, General Medicine, Mercury, biology.organism_classification, Source-sink, 030104 developmental biology, Spatial heterogeneity, General Agricultural and Biological Sciences, Plasmids

Abstract

Bacteria–plasmid associations can be mutualistic or antagonistic depending on the strength of positive selection for plasmid-encoded genes, with contrasting outcomes for plasmid stability. In mutualistic environments, plasmids are swept to high frequency by positive selection, increasing the likelihood of compensatory evolution to ameliorate the plasmid cost, which promotes long-term stability. In antagonistic environments, plasmids are purged by negative selection, reducing the probability of compensatory evolution and driving their extinction. Here we show, using experimental evolution ofPseudomonas fluorescensand the mercury-resistance plasmid, pQBR103, that migration promotes plasmid stability in spatially heterogeneous selection environments. Specifically, migration from mutualistic environments, by increasing both the frequency of the plasmid and the supply of compensatory mutations, stabilized plasmids in antagonistic environments where, without migration, they approached extinction. These data suggest that spatially heterogeneous positive selection, which is common in natural environments, coupled with migration helps to explain the stability of plasmids and the ecologically important genes that they encode.

Published

2018

15. Competitive species interactions constrain abiotic adaptation in a bacterial soil community

Author

Ellie Harrison, James P. J. Hall, and Michael A. Brockhurst

Subjects

0106 biological sciences, 0301 basic medicine, Letter, media_common.quotation_subject, Pseudomonas fluorescens, 010603 evolutionary biology, 01 natural sciences, Competition (biology), 03 medical and health sciences, Nutrient, Genetics, Letters, experimental evolution, Adaptation, Ecology, Evolution, Behavior and Systematics, media_common, Abiotic component, Experimental evolution, biology, Ecology, biology.organism_classification, Pseudomonas putida, soil microbiology, 030104 developmental biology, nutrient scavenging, Soil microbiology, competition

Abstract

Studies of abiotic adaptation often consider single species in isolation, yet natural communities contain many coexisting species which could limit or promote abiotic adaptation. Here we show, using soil bacterial communities, that evolving in the presence of a competitor constrained abiotic adaptation. Specifically, Pseudomonas fluorescens evolved alone was fitter than P. fluorescens evolved alongside Pseudomonas putida, when P. putida was absent. Genome analyses indicated this was due to mutation of the acetate scavenger actP, which occurred exclusively, and almost universally, in single-species-evolved clones. actP disruption was associated with increased growth in soil compared with wild-type actP, but this benefit was abolished when P. putida was present, suggesting a role for carbon scavenging transporters in species interactions, possibly through nutrient competition. Our results show that competitive species interactions can limit the evolutionary response to abiotic selection, because the fitness benefits of abiotic adaptive mutations were negated in more complex communities.

Published

2018

16. Sampling the mobile gene pool: innovation via horizontal gene transfer in bacteria

Author

Michael A. Brockhurst, Ellie Harrison, and James P. J. Hall

Subjects

0301 basic medicine, Genetics, Agricultural and Biological Sciences(all), Bacteria, Gene Transfer, Horizontal, Biochemistry, Genetics and Molecular Biology(all), 030106 microbiology, Pan-genome, Sampling (statistics), Accessory genome, Biological evolution, Horizontal gene transfer, Articles, Biology, Biological Evolution, General Biochemistry, Genetics and Molecular Biology, Lateral gene transfer, 03 medical and health sciences, Gene pool, General Agricultural and Biological Sciences

Abstract

In biological systems, evolutionary innovations can spread not only from parent to offspring (i.e. vertical transmission), but also ‘horizontally’ between individuals, who may or may not be related. Nowhere is this more apparent than in bacteria, where novel ecological traits can spread rapidly within and between species through horizontal gene transfer (HGT). This important evolutionary process is predominantly a by-product of the infectious spread of mobile genetic elements (MGEs). We will discuss the ecological conditions that favour the spread of traits by HGT, the evolutionary and social consequences of sharing traits, and how HGT is shaped by inherent conflicts between bacteria and MGEs.This article is part of the themed issue ‘Process and pattern in innovations from cells to societies’.

Published

2017

17. Variable plasmid fitness effects and mobile genetic element dynamics across Pseudomonas species

Author

James P. J. Hall, Michael A. Brockhurst, Ellie Harrison, and Anastasia Kottara

Subjects

0301 basic medicine, Gene Transfer, Horizontal, 030106 microbiology, Bacteria plasmid coevolution, Pseudomonas fluorescens, Pseudomonas savastanoi, Microbiology, Applied Microbiology and Biotechnology, Conjugative plasmids, 03 medical and health sciences, Plasmid, bacteria-plasmid coevolution, Host chromosome, Drug Resistance, Bacterial, experimental evolution, Genetics, biology, Ecology, conjugative plasmids, Pseudomonas putida, Pseudomonas, mobile genetic elements, Mercury, biology.organism_classification, Interspersed Repetitive Sequences, Experimental evolution, Mobile genetic elements, Conjugation, Genetic, Horizontal gene transfer, Pseudomonas aeruginosa, horizontal gene transfer, Research Article, Plasmids

Abstract

Mobile genetic elements (MGE) such as plasmids and transposons mobilise genes within and between species, playing a crucial role in bacterial evolution via horizontal gene transfer (HGT). Currently, we lack data on variation in MGE dynamics across bacterial host species. We tracked the dynamics of a large conjugative plasmid, pQBR103, and its Tn5042 mercury resistance transposon, in five diverse Pseudomonas species in environments with and without mercury selection. Plasmid fitness effects and stability varied extensively between host species and environments, as did the propensity for chromosomal capture of the Tn5042 mercury resistance transposon associated with loss of the plasmid. Whereas Pseudomonas fluorescens and Pseudomonas savastanoi stably maintained the plasmid in both environments, the plasmid was highly unstable in Pseudomonas aeruginosa and Pseudomonas putida, where plasmid-free genotypes with Tn5042 captured to the chromosome invaded to higher frequency under mercury selection. These data confirm that plasmid stability is dependent upon the specific genetic interaction of the plasmid and host chromosome rather than being a property of plasmids alone, and moreover imply that MGE dynamics in diverse natural communities are likely to be complex and driven by a subset of species capable of stably maintaining plasmids that would then act as hubs of HGT., Bacteria share genes via mobile genetic elements but the dynamics of these vary extensively between species.

Published

2017

18. Positive selection inhibits gene mobilisation and transfer in soil bacterial communities

Author

Michael A. Brockhurst, David J. Williams, Steve Paterson, Ellie Harrison, and James P. J. Hall

Subjects

0301 basic medicine, Genetics, biology, Ecology, 030106 microbiology, Chromosome, Interspecific competition, biology.organism_classification, Article, 03 medical and health sciences, Plasmid, Horizontal gene transfer, Adaptation, Mobile genetic elements, Gene, Bacteria, Ecology, Evolution, Behavior and Systematics

Abstract

Horizontal gene transfer (HGT) between bacterial lineages is a fundamental evolutionary process that accelerates adaptation. Sequence analyses show that conjugative plasmids are principal agents of HGT in natural communities. However, we lack understanding of how the ecology of bacterial communities and their environments affect the dynamics of plasmid-mediated gene mobilization and transfer. Here we show, in simple experimental soil bacterial communities containing a conjugative mercury resistance plasmid, the repeated, independent mobilization of transposon-borne genes from chromosome to plasmid, plasmid to chromosome and, in the absence of mercury selection, interspecific gene transfers from the chromosome of one species to the other via the plasmid. By reducing conjugation, positive selection for plasmid-encoded traits, like mercury resistance, can consequently inhibit HGT. Our results suggest that interspecific plasmid-mediated gene mobilization is most likely to occur in environments where plasmids are infectious, parasitic elements rather than those where plasmids are positively selected, beneficial elements. Transfer of mobile genetic elements between bacteria is widespread, facilitating adaptation. Here, the authors show that horizontal gene transfer is inhibited in soil bacterial communities undergoing positive selection for mercury resistance.

Published

2017

19. Bacterial evolution: Resistance is a numbers game

Author

Ellie Harrison and James P. J. Hall

Subjects

0301 basic medicine, Microbiology (medical), Genetics, Resistance (ecology), 030106 microbiology, Immunology, Cell Biology, Drug resistance, Biological evolution, Biology, biology.organism_classification, Applied Microbiology and Biotechnology, Microbiology, Bacterial genetics, 03 medical and health sciences, 030104 developmental biology, Plasmid, Antibiotic resistance, Gene, Bacteria

Abstract

Plasmids are well known for spreading antibiotic-resistance genes between bacterial strains. Recent experiments show that they can also act as catalysts for evolutionary innovation, promoting rapid evolution of novel antibiotic resistance.

Published

2016

20. Source-sink plasmid transfer dynamics maintain gene mobility in soil bacterial communities

Author

Michael A. Brockhurst, Ellie Harrison, A. Jamie Wood, and James P. J. Hall

Subjects

0301 basic medicine, 030106 microbiology, Population, Pseudomonas fluorescens, Biology, Microbiology, Microbial ecology, 03 medical and health sciences, Negative selection, Plasmid, education, General, Gene, Soil Microbiology, Genetics, education.field_of_study, Multidisciplinary, Pseudomonas putida, Mercury, Interspecific competition, Horizontal gene transfer, Biological Sciences, biology.organism_classification, Anti-Bacterial Agents, Mobile genetic elements, Plasmids

Abstract

Horizontal gene transfer is a fundamental process in bacterial evolution that can accelerate adaptation via the sharing of genes between lineages. Conjugative plasmids are the principal genetic elements mediating the horizontal transfer of genes, both within and between bacterial species. In some species, plasmids are unstable and likely to be lost through purifying selection, but when alternative hosts are available, interspecific plasmid transfer could counteract this and maintain access to plasmid-borne genes. To investigate the evolutionary importance of alternative hosts to plasmid population dynamics in an ecologically relevant environment, we established simple soil microcosm communities comprising two species of common soil bacteria, Pseudomonas fluorescens and Pseudomonas putida, and a mercury resistance (HgR) plasmid, pQBR57, both with and without positive selection [i.e., addition of Hg(II)]. In single-species populations, plasmid stability varied between species: although pQBR57 survived both with and without positive selection in P. fluorescens, it was lost or replaced by nontransferable HgR captured to the chromosome in P. putida. A simple mathematical model suggests these differences were likely due to pQBR57's lower intraspecific conjugation rate in P. putida. By contrast, in two-species communities, both models and experiments show that interspecific conjugation from P. fluorescens allowed pQBR57 to persist in P. putida via source-sink transfer dynamics. Moreover, the replacement of pQBR57 by nontransferable chromosomal HgR in P. putida was slowed in coculture. Interspecific transfer allows plasmid survival in host species unable to sustain the plasmid in monoculture, promoting community-wide access to the plasmid-borne accessory gene pool and thus potentiating future evolvability.

Published

2016

21. Rapid compensatory evolution promotes the survival of conjugative plasmids

Author

David Guymer, Calvin Dytham, Steve Paterson, Michael A. Brockhurst, Ellie Harrison, James P. J. Hall, and Andrew J. Spiers

Subjects

0301 basic medicine, Genetics, education.field_of_study, Experimental evolution, Circular bacterial chromosome, 030106 microbiology, Population, Biology, Biochemistry, 03 medical and health sciences, 030104 developmental biology, Plasmid, Host chromosome, Horizontal gene transfer, Adaptation, education, Gene

Abstract

Conjugative plasmids play a vital role in bacterial adaptation through horizontal gene transfer. Explaining how plasmids persist in host populations however is difficult, given the high costs often associated with plasmid carriage. Compensatory evolution to ameliorate this cost can rescue plasmids from extinction. In a recently published study we showed that compensatory evolution repeatedly targeted the same bacterial regulatory system, GacA/GacS, in populations of plasmid-carrying bacteria evolving across a range of selective environments. Mutations in these genes arose rapidly and completely eliminated the cost of plasmid carriage. Here we extend our analysis using an individual based model to explore the dynamics of compensatory evolution in this system. We show that mutations which ameliorate the cost of plasmid carriage can prevent both the loss of plasmids from the population and the fixation of accessory traits on the bacterial chromosome. We discuss how dependent the outcome of compensatory evolution is on the strength and availability of such mutations and the rate at which beneficial accessory traits integrate on the host chromosome.

Published

2016

22. Multi-host environments select for host-generalist conjugative plasmids

Author

James P. J. Hall, Ellie Harrison, Anastasia Kottara, and Michael A. Brockhurst

Subjects

0301 basic medicine, Gene Transfer, Horizontal, 030106 microbiology, Genetic Fitness, Pseudomonas fluorescens, Generalist and specialist species, 03 medical and health sciences, Plasmid, Drug Resistance, Bacterial, Gene, Ecology, Evolution, Behavior and Systematics, Genetics, biology, Host (biology), Pseudomonas putida, Mercury, biology.organism_classification, Biological Evolution, 030104 developmental biology, Evolutionary biology, Horizontal gene transfer, bacteria, Plasmids, Research Article

Abstract

Background: Conjugative plasmids play an important role in bacterial evolution by transferring ecologically important genes within and between species. A key limit on interspecific horizontal gene transfer is plasmid host range. Here, we experimentally test the effect of single and multi-host environments on the host-range evolution of a large conjugative mercury resistance plasmid, pQBR57. Specifically, pQBR57 was conjugated between strains of a single host species, either P. fluorescens or P. putida, or alternating between P. fluorescens and P. putida. Crucially, the bacterial hosts were not permitted to evolve allowing us to observe plasmid evolutionary responses in isolation. Results: In all treatments plasmids evolved higher conjugation rates over time. Plasmids evolved in single-host environments adapted to their host bacterial species becoming less costly, but in the case of P. fluorescens-adapted plasmids, became costlier in P. putida, suggesting an evolutionary trade-off. When evolved in the multi-host environment plasmids adapted to P. fluorescens without a higher cost in P. putida. Conclusion: Whereas evolution in a single-host environment selected for host-specialist plasmids due to a fitness trade-off, this trade-off could be circumvented in the multi-host environment, leading to the evolution of host-generalist plasmids.

Published

2016

23. Identification of low- and high-impact hemagglutinin amino acid substitutions that drive antigenic drift of influenza A(H1N1) viruses

Author

Trevor Bedford, Richard Reeve, Daniel T. Haydon, John W. McCauley, Rodney S. Daniels, Victoria Gregory, D.J. Benton, Alan J. Hay, James P. J. Hall, and William T. Harvey

Subjects

0301 basic medicine, RNA viruses, Influenza Viruses, Viral Diseases, Physiology, Hemagglutinin Glycoproteins, Influenza Virus, medicine.disease_cause, Pathology and Laboratory Medicine, Biochemistry, Mice, Influenza A Virus, H1N1 Subtype, Immune Physiology, Influenza A virus, Medicine and Health Sciences, Amino Acids, Biology (General), Antigens, Viral, Phylogeny, Data Management, Genetics, Immune System Proteins, Organic Compounds, Hematology, Antigenic Variation, 3. Good health, Body Fluids, Phylogenetics, Chemistry, Blood, Infectious Diseases, Medical Microbiology, Influenza Vaccines, Viral evolution, Viral Pathogens, Physical Sciences, Viruses, Anatomy, Pathogens, Research Article, Computer and Information Sciences, QH301-705.5, 030106 microbiology, Immunology, Hemagglutinin (influenza), Biology, H5N1 genetic structure, Microbiology, Antigenic drift, Viral Evolution, 03 medical and health sciences, Orthomyxoviridae Infections, Virology, Influenza, Human, medicine, Antigenic variation, Animals, Humans, Evolutionary Systematics, Antigens, Molecular Biology, Microbial Pathogens, Taxonomy, Evolutionary Biology, Hemagglutination assay, Organic Chemistry, Chemical Compounds, Organisms, Antigenic shift, Biology and Life Sciences, Proteins, Blood Serum, RC581-607, Organismal Evolution, Influenza, 030104 developmental biology, Amino Acid Substitution, Microbial Evolution, biology.protein, Parasitology, Immunologic diseases. Allergy, Immune Serum, Orthomyxoviruses

Abstract

Determining phenotype from genetic data is a fundamental challenge. Identification of emerging antigenic variants among circulating influenza viruses is critical to the vaccine virus selection process, with vaccine effectiveness maximized when constituents are antigenically similar to circulating viruses. Hemagglutination inhibition (HI) assay data are commonly used to assess influenza antigenicity. Here, sequence and 3-D structural information of hemagglutinin (HA) glycoproteins were analyzed together with corresponding HI assay data for former seasonal influenza A(H1N1) virus isolates (1997–2009) and reference viruses. The models developed identify and quantify the impact of eighteen amino acid substitutions on the antigenicity of HA, two of which were responsible for major transitions in antigenic phenotype. We used reverse genetics to demonstrate the causal effect on antigenicity for a subset of these substitutions. Information on the impact of substitutions allowed us to predict antigenic phenotypes of emerging viruses directly from HA gene sequence data and accuracy was doubled by including all substitutions causing antigenic changes over a model incorporating only the substitutions with the largest impact. The ability to quantify the phenotypic impact of specific amino acid substitutions should help refine emerging techniques that predict the evolution of virus populations from one year to the next, leading to stronger theoretical foundations for selection of candidate vaccine viruses. These techniques have great potential to be extended to other antigenically variable pathogens., Author Summary Influenza A viruses are characterized by rapid antigenic drift: structural changes in B-cell epitopes that facilitate escape from pre-existing immunity. Consequently, seasonal influenza continues to impose a major burden on human health. Accurate quantification of the antigenic impact of specific amino acid substitutions is a pre-requisite for predicting the fitness and evolutionary outcome of variant viruses. Using assays to attribute antigenic variation to amino acid sequence changes we identify substitutions that contribute to antigenic drift and quantify their impact. We show that substitutions identified as low-impact are a critical component of virus antigenic evolution and by including these, as well as the high-impact substitutions often focused on, the accuracy of predicting antigenic phenotypes of emerging viruses from genotype is doubled.

Published

2016

24. Genome hyperevolution and the success of a parasite

Author

J. David Barry, Lindsey J. Plenderleith, and James P. J. Hall

Subjects

Trypanosoma, Population, Somatic hypermutation, Biology, antigenic variation, Genome, General Biochemistry, Genetics and Molecular Biology, Chromosomes, Host-Parasite Interactions, Evolution, Molecular, 03 medical and health sciences, History and Philosophy of Science, trypanosome, Trypanosomiasis, Genetic variation, Antigenic variation, Animals, Humans, education, Gene, 030304 developmental biology, Immune Evasion, Genetics, 0303 health sciences, education.field_of_study, genome hyperevolution, Base Sequence, 030306 microbiology, General Neuroscience, Genetic Variation, Original Articles, DNA, Protozoan, Subtelomere, Phenotype, parasite, subtelomere, Genome, Protozoan, Variant Surface Glycoproteins, Trypanosoma

Abstract

The strategy of antigenic variation is to present a constantly changing population phenotype that enhances parasite transmission, through evasion of immunity arising within, or existing between, host animals. Trypanosome antigenic variation occurs through spontaneous switching among members of a silent archive of many hundreds of variant surface glycoprotein (VSG) antigen genes. As with such contingency systems in other pathogens, switching appears to be triggered through inherently unstable DNA sequences. The archive occupies subtelomeres, a genome partition that promotes hypermutagenesis and, through telomere position effects, singular expression of VSG. Trypanosome antigenic variation is augmented greatly by the formation of mosaic genes from segments of pseudo-VSG, an example of implicit genetic information. Hypermutation occurs apparently evenly across the whole archive, without direct selection on individual VSG, demonstrating second-order selection of the underlying mechanisms. Coordination of antigenic variation, and thereby transmission, occurs through networking of trypanosome traits expressed at different scales from molecules to host populations.

Published

2012

25. DNA Recombination Strategies During Antigenic Variation in the African Trypanosome

Author

Richard McCulloch, Liam J. Morrison, and James P. J. Hall

Subjects

Microbiology (medical), Physiology, Trypanosoma brucei brucei, Antigens, Protozoan, Immune system, Antigen, parasitic diseases, Genetics, Antigenic variation, Animals, Humans, Coevolution, Immune Evasion, Mammals, Recombination, Genetic, General Immunology and Microbiology, Ecology, biology, Genetic Variation, Cell Biology, DNA, Protozoan, Acquired immune system, Virology, Antigenic Variation, Obligate parasite, Infectious Diseases, biology.protein, Adaptation, Antibody, Variant Surface Glycoproteins, Trypanosoma

Abstract

Survival of the African trypanosome in its mammalian hosts has led to the evolution of antigenic variation, a process for evasion of adaptive immunity that has independently evolved in many other viral, bacterial and eukaryotic pathogens. The essential features of trypanosome antigenic variation have been understood for many years and comprise a dense, protective Variant Surface Glycoprotein (VSG) coat, which can be changed by recombination-based and transcription-based processes that focus on telomeric VSG gene transcription sites. However, it is only recently that the scale of this process has been truly appreciated. Genome sequencing of Trypanosoma brucei has revealed a massive archive of >1000 VSG genes, the huge majority of which are functionally impaired but are used to generate far greater numbers of VSG coats through segmental gene conversion. This chapter will discuss the implications of such VSG diversity for immune evasion by antigenic variation, and will consider how this expressed diversity can arise, drawing on a growing body of work that has begun to examine the proteins and sequences through which VSG switching is catalyzed. Most studies of trypanosome antigenic variation have focused on T. brucei , the causative agent of human sleeping sickness. Other work has begun to look at antigenic variation in animal-infective trypanosomes, and we will compare the findings that are emerging, as well as consider how antigenic variation relates to the dynamics of host–trypanosome interaction.

Published

2015

26. Withstanding the Challenges of Host Immunity: Antigenic Variation and the Trypanosome Surface Coat

Author

James P. J. Hall and Lindsey J. Plenderleith

Subjects

Genetics, Mutation, Effector, Pseudogene, Biology, Subtelomere, medicine.disease_cause, Virology, Phenotype, Immune system, parasitic diseases, Antigenic variation, medicine, Gene

Abstract

Prolonged survival in the face of host immunity has been a major force shaping the biology and evolution of the African trypanosomes, and nowhere are the effects of this force more apparent than in the antigenic variation of the trypanosome variant surface glycoprotein (VSG) coat. The coat protects the trypanosome within it from immune effectors, and spontaneous and stochastic events occurring at the molecular level cause individual trypanosomes to change the VSG variant they are expressing. The consequence of this switching at the population level is a diverse population that can pre-empt the specific immune responses that arise against VSG. The template for changes to VSG is an extensive archive of silent VSG genes and pseudogenes. VSG from the archive are activated not only as full-length genes but also through the combination of segments to form mosaic VSG genes, a process that augments the potential for antigenic variation by introducing combinatorial variation and allowing VSG pseudogenes to be used. The main part of the archive occupies subtelomeres and so is itself prone to mutation and rapid evolution, which are important features when superinfection or reinfection of partially immune hosts is necessary. The antigenic variation ‘diversity phenotype’ is thus a multifaceted one, enlisting and coordinating fundamental mechanisms of cell biology to bring about a process that unfolds across populations, thereby facilitating the success of the African trypanosomes.

Published

2013

27. Mosaic VSGs and the Scale of Trypanosoma brucei Antigenic Variation

Author

J. David Barry, Huanhuan Wang, and James P. J. Hall

Subjects

Time Factors, Genes, Protozoan, Protozoan Proteins, Antibodies, Protozoan, Adaptive Immunity, Protozoology, Mice, Molecular cell biology, Biology (General), Genetics, 0303 health sciences, Mice, Inbred BALB C, Membrane Glycoproteins, biology, Microbial Mutation, Phenotype, Antigenic Variation, 3. Good health, Host-Pathogen Interaction, Nucleic acids, Female, Pseudogenes, RNA, Protozoan, Research Article, Trypanosoma, QH301-705.5, DNA recombination, Surface Properties, Pseudogene, Immunology, Trypanosoma brucei brucei, Antigens, Protozoan, Trypanosoma brucei, Microbiology, Molecular Genetics, 03 medical and health sciences, Trypanosomiasis, Virology, Genetic variation, parasitic diseases, Antigenic variation, Animals, Gene conversion, Parasite Evolution, Molecular Biology, Gene, Biology, 030304 developmental biology, Organisms, Genetically Modified, 030306 microbiology, Immunity, Genetic Variation, DNA, RC581-607, biology.organism_classification, Parastic Protozoans, Parasitology, Immunologic diseases. Allergy

Abstract

A main determinant of prolonged Trypanosoma brucei infection and transmission and success of the parasite is the interplay between host acquired immunity and antigenic variation of the parasite variant surface glycoprotein (VSG) coat. About 0.1% of trypanosome divisions produce a switch to a different VSG through differential expression of an archive of hundreds of silent VSG genes and pseudogenes, but the patterns and extent of the trypanosome diversity phenotype, particularly in chronic infection, are unclear. We applied longitudinal VSG cDNA sequencing to estimate variant richness and test whether pseudogenes contribute to antigenic variation. We show that individual growth peaks can contain at least 15 distinct variants, are estimated computationally to comprise many more, and that antigenically distinct ‘mosaic’ VSGs arise from segmental gene conversion between donor VSG genes or pseudogenes. The potential for trypanosome antigenic variation is probably much greater than VSG archive size; mosaic VSGs are core to antigenic variation and chronic infection., Author Summary Trypanosoma brucei—a deadly parasite of humans and animals—owes its success to its ability to cope with host immunity, and the mechanism it uses to do so is a remarkable example of biological variation. Immune responses that develop against the parasite surface coat are only partially effective against the parasite population; some individual parasites will have already switched to a different variant of the coat antigen, and thus survive to prolong infection. Little is known about how the pattern of antigen variation unfolds, particularly after the early stage of infection. Here, we examined different antigen variants that appeared over the course of infection, to estimate their diversity and to see whether the parasites are able to generate new antigen variants by combination. We found antigen diversity was much greater than expected, and that ‘mosaic’ variants—produced by combining bits of more than one antigen gene—played a central role in the later stages of infection. These results provide important evidence for the robustness of this key survival strategy, provide clues about its evolution, and allow us to identify patterns in common with other antigenically variable pathogens.

Published

2013

28. Viral host-adaptation: insights from evolution experiments with phages

Author

James P. J. Hall, Michael A. Brockhurst, and Ellie Harrison

Subjects

viruses, Population, Biology, medicine.disease_cause, Host Specificity, 03 medical and health sciences, Virology, medicine, Bacteriophages, education, 030304 developmental biology, Genetics, 0303 health sciences, Mutation, education.field_of_study, Bacteria, 030306 microbiology, Host (biology), Adaptation, Physiological, Biological Evolution, Genetic divergence, Viral evolution, Host adaptation, Parallel evolution, Adaptation

Abstract

Phages, viral parasites of bacteria, share fundamental features of pathogenic animal and plant viruses and represent a highly tractable empirical model system to understand viral evolution and in particular viral host-adaptation. Phage adaptation to a particular host genotype often results in improved fitness by way of parallel evolution whereby independent lineages hit upon identical adaptive solutions. By contrast, phage adaptation to an evolving host population leads to the evolution of increasing host-range over time and correlated phenotypic and genetic divergence between populations. Phage host-range expansion frequently occurs by a process of stepwise evolution of multiple mutations, and host-shifts are often constrained by mutational availability, pleiotropic costs or ecological conditions.

Published

2013