Your search keyword '"Bull J."' showing total 17 results

1. Optimality models of phage life history and parallels in disease evolution.

Author

Bull JJ

Subjects

Animals, Bacteriophages pathogenicity, Biological Evolution, Cell Death genetics, Phenotype, Virulence genetics, Bacteriophages physiology, Models, Biological

Abstract

Optimality models constitute one of the simplest approaches to understanding phenotypic evolution. Yet they have shortcomings that are not easily evaluated in most organisms. Most importantly, the genetic basis of phenotype evolution is almost never understood, and phenotypic selection experiments are rarely possible. Both limitations can be overcome with bacteriophages. However, phages have such elementary life histories that few phenotypes seem appropriate for optimality approaches. Here we develop optimality models of two phage life history traits, lysis time and host range. The lysis time models show that the optimum is less sensitive to differences in host density than suggested by earlier analytical work. Host range evolution is approached from the perspective of whether the virus should avoid particular hosts, and the results match optimal foraging theory: there is an optimal "diet" in which host types are either strictly included or excluded, depending on their infection qualities. Experimental tests of both models are feasible, and phages provide concrete illustrations of many ways that optimality models can guide understanding and explanation. Phage genetic systems already support the perspective that lysis time and host range can evolve readily and evolve without greatly affecting other traits, one of the main tenets of optimality theory. The models can be extended to more general properties of infection, such as the evolution of virulence and tissue tropism.

Published

2006

2. Evolutionary feedback mediated through population density, illustrated with viruses in chemostats.

Author

Bull JJ, Millstein J, Orcutt J, and Wichman HA

Subjects

Adaptation, Biological, Bacteria virology, Bacteriophages genetics, Ecosystem, Evolution, Molecular, Genome, Viral, Models, Biological, Population Density, Selection, Genetic, Virus Cultivation, Bacteriophages physiology, Biological Evolution

Abstract

A cornerstone of evolutionary ecology is that population density affects adaptation: r and K selection is the obvious example. The reverse is also appreciated: adaptation impacts population density. Yet, empirically demonstrating a direct connection between population density and adaptation is challenging. Here, we address both evolution and ecology of population density in models of viral (bacteriophage) chemostats. Chemostats supply nutrients for host cell growth, and the hosts are prey for viral reproduction. Two different chemostat designs have profoundly different consequences for viral evolution. If host and virus are confined to the same chamber, as in a predator-prey system, viral regulation of hosts feeds back to maintain low viral density (measured as infections per cell). Viral adaptation impacts host density but has a small effect on equilibrium viral density. More interesting are chemostats that supply the viral population with hosts from a virus-free refuge. Here, a type of evolutionary succession operates: adaptation at low viral density leads to higher density, but high density then favors competitive ability. Experiments support these models with both phenotypic and molecular data. Parallels to these designs exist in many natural systems, so these experimental systems may yield insights to the evolution and regulation of natural populations.

Published

2006

3. Genome properties and the limits of adaptation in bacteriophages.

Author

Bull JJ, Badgett MR, Springman R, and Molineux IJ

Subjects

Adsorption, Analysis of Variance, Bacteriophage T3 genetics, Bacteriophage T7 genetics, Bacteriophages genetics, Endpoint Determination, Escherichia coli, Models, Biological, Selection, Genetic, Adaptation, Biological, Bacteriophages growth & development, Bacteriophages physiology, DNA Replication genetics, Genome, Viral, Virus Replication genetics

Abstract

Eight bacteriophages were adapted for rapid growth under similar conditions to compare their evolved, endpoint fitnesses. Four pairs of related phages were used, including two RNA phages with small genomes (MS2 and Qbeta) two single-stranded DNA phages with small genomes (phiX174 and G4), two T-odd phages with medium-sized, double-stranded DNA genomes (T7 and T3), and two T-even phages with large, double-stranded DNA genomes (T6 and RB69). Fitness was measured as absolute growth rate per hour under the same conditions used for adaptation. T7 and T3 achieved the highest fitnesses, able to increase by 13 billionfold and three-quarters billionfold per hour, respectively. In contrast, the RNA phages achieved low fitness maxima, with growth rates approximately 400-fold and 4000-fold per hour. The highest fitness limits were not attributable to high mutation rates or small genome size, even though both traits are expected to enhance adaptation for fast growth. We suggest that major differences in fitness limits stem from different "global" constraints, determined by the organization and composition of the phage genome affecting whether and how it overcomes potentially rate-limiting host processes, such as transcription, translation, and replication. Adsorption rates were also measured on the evolved phages. No consistent pattern of adsorption rate and fitness was observed across the four different types of phages, but within each pair of related phages, higher adsorption was associated with higher fitness. Different adsorption rate limits within pairs may stem from "local" constraints-sequence differences leading to different local optima in the sequence space.

Published

2004

4. Dynamics of success and failure in phage and antibiotic therapy in experimental infections.

Author

Bull JJ, Levin BR, DeRouin T, Walker N, and Bloch CA

Subjects

Animals, Animals, Outbred Strains, Drug Resistance, Bacterial, Escherichia coli Infections mortality, Female, Mice, Streptomycin therapeutic use, Survival Rate, Time Factors, Virus Replication, Anti-Bacterial Agents therapeutic use, Bacteriophages growth & development, Escherichia coli drug effects, Escherichia coli Infections therapy

Abstract

Background: In 1982 Smith and Huggins showed that bacteriophages could be at least as effective as antibiotics in preventing mortality from experimental infections with a capsulated E. coli (K1) in mice. Phages that required the K1 capsule for infection were more effective than phages that did not require this capsule, but the efficacies of phages and antibiotics in preventing mortality both declined with time between infection and treatment, becoming virtually ineffective within 16 hours., Results: We develop quantitative microbiological procedures that (1) explore the in vivo processes responsible for the efficacy of phage and antibiotic treatment protocols in experimental infections (the Resistance Competition Assay, or RCA), and (2) survey the therapeutic potential of phages in vitro (the Phage Replication Assay or PRA). We illustrate the application and utility of these methods in a repetition of Smith and Huggins' experiments, using the E. coli K1 mouse thigh infection model, and applying treatments of phages or streptomycin., Conclusions: 1) The Smith and Huggins phage and antibiotic therapy results are quantitatively and qualitatively robust. (2) Our RCA values reflect the microbiological efficacies of the different phages and of streptomycin in preventing mortality, and reflect the decline in their efficacy with a delay in treatment. These results show specifically that bacteria become refractory to treatment over the term of infection. (3) The K1-specific and non-specific phages had similar replication rates on bacteria grown in broth (based on the PRA), but the K1-specific phage had markedly greater replication rates in mouse serum.

Published

2002

5. Virulence evolution in a virus obeys a trade-off.

Author

Messenger SL, Molineux IJ, and Bull JJ

Subjects

Bacteriophages genetics, Biological Evolution, Disease Transmission, Infectious, Escherichia coli virology, Infectious Disease Transmission, Vertical, Virus Diseases transmission, Virus Diseases virology, Virus Replication, Bacteriophages pathogenicity, Virulence genetics

Abstract

The evolution of virulence was studied in a virus subjected to alternating episodes of vertical and horizontal transmission. Bacteriophage f1 was used as the parasite because it establishes a debilitating but non-fatal infection that can be transmitted vertically (from a host to its progeny) as well as horizontally (infection of new hosts). Horizontal transmission was required of all phage at specific intervals, but was prevented otherwise. Each episode of horizontal transmission was followed by an interval of obligate vertical transmission, followed by an interval of obligate horizontal transmission etc. The duration of vertical transmission was eight times longer per episode in one treatment than in the other, thus varying the relative intensity of selection against virulence while maintaining selection for some level of virus production. Viral lines with the higher enforced rate of infectious transmission evolved higher virulence and higher rates of virus production. These results support the trade-off model for the evolution of virulence.

Published

1999

6. Experimental Evolution Recapitulates Natural Evolution

Author

Wichman, H. A., Scott, L. A., Yarber, C. D., and Bull, J. J.

Published

2000

7. Phage Therapy Revisited: The Population Biology of a Bacterial Infection and Its Treatment with Bacteriophage and Antibiotics

Author

Levin, Bruce R. and Bull, J. J.

Published

1996

8. Different Trajectories of Parallel Evolution During Viral Adaptation

Author

Wichman, H. A., Badgett, M. R., Scott, L. A., Boulianne, C. M., and Bull, J. J.

Published

1999

9. Selection of Benevolence in a Host-Parasite System

Author

Bull, J. J., Molineux, Ian J., and Rice, W. R.

Published

1991

10. Molecular Genetics of Adaptation in an Experimental Model of Cooperation

Author

Bull, J. J. and Molineux, Ian J.

Published

1992

11. Experimental Molecular Evolution of Bacteriophage T7

Author

Bull, J. J., Cunningham, C. W., Molineux, I. J., Badgett, M. R., and Hillis, D. M.

Published

1993

12. Experimental Approaches to Phylogenetic Analysis

Author

Hillis, David M., Bull, J. J., White, Mary E., Badgett, Marty R., and Molineux, Ian J.

Published

1993

13. Impact of Phages on Two-Species Bacterial Communities.

Author

Harcombe, W. R. and Bull, J. J.

Subjects

*BACTERIA, *BACTERIOPHAGES, *ESCHERICHIA coli, *SALMONELLA enteritidis, *DRUG resistance in microorganisms, *ESCHERICHIA

Abstract

A long history of experimental work has shown that addition of bacteriophages to a monoculture of bacteria leads to only a temporary depression of bacterial levels. Resistant bacteria usually become abundant, despite reduced growth rates relative to those of phage-sensitive bacteria. This restoration of high bacterial density occurs even if the phages evolve to overcome bacterial resistance. We believe that the generality of this result may be limited to monocultures, in which the resistant bacteria do not face competition from bacterial species unaffected by the phage. As a simple case, we investigated the impact of phages attacking one species in a two-species culture of bacteria. In the absence of phages, Escherichia coli B and Salmonella enterica serovar Typhimurium were stably maintained during daily serial passage in glucose minimal medium (M9). When either of two K coli-specific phages (T7 or T5) was added to the mixed culture, K coil became extinct or was maintained at densities that were orders of magnitude lower than those before phage introduction, even though the K coil densities with phage reached high levels when Salmonella was absent. In contrast, the addition of a phage that attacked only Salmonella (SP6) led to transient decreases in the bacterial number whether E. coli was absent or present. These results suggest that phages can sometimes, although not always, provide long-term suppression of target bacteria. [ABSTRACT FROM AUTHOR]

Published

2005

14. Experimental Evolution Yields Hundreds of Mutations in a Functional Viral Genome.

Author

Bull, J. J., Badgett, M. R., Rokyta, D., and Molineux, I. J.

Subjects

*BACTERIOPHAGES, *GENETIC mutation, *MUTAGENESIS, *GENOMES, *BIOLOGICAL evolution, *NUCLEOTIDES

Abstract

Two lines of the bacteriophage T7 were grown to fix mutations indiscriminately, using a combination of population bottlenecks and mutagenesis. Complete genome sequences revealed 404 and 299 base substitutions in the two lines, the largest number characterized in functional microbial genomes so far. Missense substitutions outnumbered silent substitutions. Silent substitutions occurred at similar rates between essential and nonessential genes, but missense substitutions occurred at a higher rate in nonessential genes than in essential genes, as expected if they were less deleterious in the nonessential genes. Viral fitness declined during this protocol, and subsequent passaging of each mutated line in large population sizes restored some of the lost fitness. Substitution levels during these recoveries were less than 6% of those during the bottleneck phase, and only two changes during recovery were reversions of the original mutations. Exchanges of genomic fragments between the two recovered lines revealed that fitness effects of some substitutions were not additive—that interactions were accumulating which could lead to incompatibility between the diverged genomes. Based on these results, unprecedented high rates of nucleotide and functional divergence in viral genomes should be attainable experimentally by using repeated population bottlenecks at a high mutation rate interspersed with recovery. [ABSTRACT FROM AUTHOR]

Published

2003

15. A General Mechanism for Viral Resistance to Suicide Gene Expression.

Author

Bull, J. J., Badgett, M. R., and Molineux, I. J.

Subjects

GENETIC regulation, GENE expression, RNA polymerases, GENES, BACTERIOPHAGES, PLASMIDS

Abstract

Bacteriophage T7 was challenged with either of two toxic genes expressed from plasmids. Each plasmid contained a different gene downstream of a T7 promoter; cells harboring each plasmid caused an infection by wild-type T7 to abort. T7 evolved resistance to both inhibitors by avoidance of the plasmid expression system rather than by blocking or bypassing the effects of the specific toxic gene product. Resistance was due to a combination of mutations in the T7 RNA polymerase and other genes expressed at the same time as the polymerase. Mutations mapped to sites that are unlikely to alter polymerase specificity for its cognate promoter but the basis for discrimination between phage and plasmid promoters in vivo was not resolved. A reporter assay indicated that, relative to wild-type phage, gene expression from the plasmid was diminished several-fold in cells infected by the evolved phages. A recombinant phage, derived from the original mutant but lacking a mutation in the gene for RNA polymerase, exhibited intermediate activity in the reporter assay and intermediate resistance to the toxic gene cassettes. Alterations in both RNA polymerase and a second gene are thus responsible for resistance. These findings have broad evolutionary parallels to other systems in which viral inhibition is activated by viral regulatory signals such as defective-interfering particles, and they may have mechanistic parallels to the general phenomena of position effects and gene silencing. [ABSTRACT FROM AUTHOR]

Published

2001

16. Adaptive Molecular Evolution for 13,000 Phage Generations: A Possible Arms Race.

Author

Wichman, Holly A., Millstein, Jack, and Bull, J. J.

Subjects

*BACTERIOPHAGES, *VIRUSES, *MOLECULAR evolution, *MOLECULAR biology, *ORIGIN of life, *GENETICS

Abstract

Bacteriophage ΦX174 was evolved on a continuous supply of sensitive hosts for 180 days (∼13,000 phage generations). The average rate of nucleotide substitution was nearly 0.2% (11 substitutions)/20 days, and, surprisingly, substitutions accumulated in a dock-like manner throughout the study, except for a low rate during the first 20 days. Rates of silent and missense substitutions varied over time and among genes. Approximately 40% of the 71 missense changes and 25% of the 58 silent changes have been observed in previous adaptations; the rate of parallel substitution was highest in the early phase of the evolution, but 7% of the later changes had evolved in previous studies of much shorter duration. Several lines of evidence suggest that most of the changes were adaptive, even many of the silent substitutions. The sustained, high rate of adaptive evolution for 180 days defies a model of adaptation to a constant environment. We instead suggest that continuing molecular evolution reflects a potentially indefinite arms race, stemming from high levels of co-infection and the resulting conflict among genomes competing within the same cell. [ABSTRACT FROM AUTHOR]

Published

2005

17. Evolution at a High Imposed Mutation Rate: Adaptation Obscures the Load in Phage T7.

Author

Springman, R., Keller, T., Molineux, I. J., and Bull, J. J.

Subjects

*GENETIC mutation, *MUTAGENESIS, *VIRAL disease treatment, *BACTERIOPHAGES, *DNA polymerases, *PATHOGENIC microorganisms

Abstract

Evolution at high mutation rates is expected to reduce population fitness deterministically by the accumulation of deleterious mutations. A high enough rate should even cause extinction (lethal mutagenesis), a principle motivating the clinical use of mutagenic drugs to treat viral infections. The impact of a high mutation rate on long-term viral fitness was tested here. A large population of the DNA bacteriophage T7 was grown with a mutagen, producing a genomic rate of 4 nonlethal mutations per generation, two to three orders of magnitude above the baseline rate. Fitness-viral growth rate in the mutagenic environment-was predicted to decline substantially; after 200 generations, fitness had increased, rejecting the model. A high mutation load was nonetheless evident from (i) many low- to moderate-frequency mutations in the population (averaging 245 per genome) and (ii) an 80% drop in average burst size. Twenty-eight mutations reached high frequency and were thus presumably adaptive, clustered mostly in DNA metabolism genes, chiefly DNA polymerase. Yet blocking DNA polymerase evolution failed to yield a fitness decrease after 100 generations. Although mutagenic drugs have caused viral extinction in vitro under some conditions, this study is the first to match theory and fitness evolution at a high mutation rate. Failure of the theory challenges the quantitative basis of lethal mutagenesis and highlights the potential for adaptive evolution at high mutation rates. [ABSTRACT FROM AUTHOR]

Published

2010