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199 results on '"Meyer, Justin R."'

1. Competition-driven eco-evolutionary feedback reshapes bacteriophage lambda’s fitness landscape and enables speciation

Author

Doud, Michael B, Gupta, Animesh, Li, Victor, Medina, Sarah J, De La Fuente, Caesar A, and Meyer, Justin R

Subjects
Climate Change Impacts and Adaptation, Biological Sciences, Environmental Sciences, Emerging Infectious Diseases, Bacteriophage lambda, Feedback, Mutation, Genetic Fitness, Models, Genetic, Biological Evolution
Abstract

A major challenge in evolutionary biology is explaining how populations navigate rugged fitness landscapes without getting trapped on local optima. One idea illustrated by adaptive dynamics theory is that as populations adapt, their newly enhanced capacities to exploit resources alter fitness payoffs and restructure the landscape in ways that promote speciation by opening new adaptive pathways. While there have been indirect tests of this theory, to our knowledge none have measured how fitness landscapes deform during adaptation, or test whether these shifts promote diversification. Here, we achieve this by studying bacteriophage [Formula: see text], a virus that readily speciates into co-existing receptor specialists under controlled laboratory conditions. We use a high-throughput gene editing-phenotyping technology to measure [Formula: see text]'s fitness landscape in the presence of different evolved-[Formula: see text] competitors and find that the fitness effects of individual mutations, and their epistatic interactions, depend on the competitor. Using these empirical data, we simulate [Formula: see text]'s evolution on an unchanging landscape and one that recapitulates how the landscape deforms during evolution. [Formula: see text] heterogeneity only evolves in the shifting landscape regime. This study provides a test of adaptive dynamics, and, more broadly, shows how fitness landscapes dynamically change during adaptation, potentiating phenomena like speciation by opening new adaptive pathways.

Published
2024

2. Viral protein instability enhances host-range evolvability

Author

Strobel, Hannah M, Horwitz, Elijah K, and Meyer, Justin R

Subjects
Biological Sciences, Bioinformatics and Computational Biology, Genetics, 2.1 Biological and endogenous factors, Aetiology, 2.2 Factors relating to the physical environment, Infection, Host Specificity, Mutation, Phenotype, Viral Proteins, Viruses, Developmental Biology
Abstract

Viruses are highly evolvable, but what traits endow this property? The high mutation rates of viruses certainly play a role, but factors that act above the genetic code, like protein thermostability, are also expected to contribute. We studied how the thermostability of a model virus, bacteriophage λ, affects its ability to evolve to use a new receptor, a key evolutionary transition that can cause host-range evolution. Using directed evolution and synthetic biology techniques we generated a library of host-recognition protein variants with altered stabilities and then tested their capacity to evolve to use a new receptor. Variants fell within three stability classes: stable, unstable, and catastrophically unstable. The most evolvable were the two unstable variants, whereas seven of eight stable variants were significantly less evolvable, and the two catastrophically unstable variants could not grow. The slowly evolving stable variants were delayed because they required an additional destabilizing mutation. These results are particularly noteworthy because they contradict a widely supported contention that thermostabilizing mutations enhance evolvability of proteins by increasing mutational robustness. Our work suggests that the relationship between thermostability and evolvability is more complex than previously thought, provides evidence for a new molecular model of host-range expansion evolution, and identifies instability as a potential predictor of viral host-range evolution.

Published
2022

3. Coevolutionary phage training leads to greater bacterial suppression and delays the evolution of phage resistance

Author

Borin, Joshua M, Avrani, Sarit, Barrick, Jeffrey E, Petrie, Katherine L, and Meyer, Justin R

Subjects
Genetics, Human Genome, Antimicrobial Resistance, Biotechnology, Infection, Bacteriophage lambda, Escherichia coli, Host-Pathogen Interactions, Mutation, evolution, coevolution, resistance, phage therapy, phage training
Abstract

The evolution of antibiotic-resistant bacteria threatens to become the leading cause of worldwide mortality. This crisis has renewed interest in the practice of phage therapy. Yet, bacteria's capacity to evolve resistance may debilitate this therapy as well. To combat the evolution of phage resistance and improve treatment outcomes, many suggest leveraging phages' ability to counter resistance by evolving phages on target hosts before using them in therapy (phage training). We found that in vitro, λtrn, a phage trained for 28 d, suppressed bacteria ∼1,000-fold for three to eight times longer than its untrained ancestor. Prolonged suppression was due to a delay in the evolution of resistance caused by several factors. Mutations that confer resistance to λtrn are ∼100× less common, and while the target bacterium can evolve complete resistance to the untrained phage in a single step, multiple mutations are required to evolve complete resistance to λtrn. Mutations that confer resistance to λtrn are more costly than mutations for untrained phage resistance. Furthermore, when resistance does evolve, λtrn is better able to suppress these forms of resistance. One way that λtrn improved was through recombination with a gene in a defunct prophage in the host genome, which doubled phage fitness. This transfer of information from the host genome is an unexpected but highly efficient mode of training phage. Lastly, we found that many other independently trained λ phages were able to suppress bacterial populations, supporting the important role training could play during phage therapeutic development.

Published
2021

4. Trade‐off drives Pareto optimality of within‐ and among‐year emergence timing in response to increasing aridity

Author

Waterton, Joseph, Mazer, Susan J, Meyer, Justin R, and Cleland, Elsa E

Subjects
Biological Sciences, Ecology, Evolutionary Biology, Genetics, Climate Action, adaptation, aridity, bet&#8208, hedging, climate change, emergence timing, pareto optimality, phenology, trade&#8208, off, bet‐hedging, trade‐off, Medicinal and Biomolecular Chemistry, Evolutionary biology
Abstract

Adaptation to current and future climates can be constrained by trade-offs between fitness-related traits. Early seedling emergence often enhances plant fitness in seasonal environments, but if earlier emergence in response to seasonal cues is genetically correlated with lower potential to spread emergence among years (i.e., bet-hedging), then this functional trade-off could constrain adaptive evolution. Consequently, selection favoring both earlier within-year emergence and greater spread of emergence among years-as is expected in more arid environments-may constrain adaptive responses to trait value combinations at which a performance gain in either function (i.e., evolving earlier within- or greater among-year emergence) generates a performance loss in the other. All such trait value combinations that cannot be improved for both functions simultaneously are described as Pareto optimal and together constitute the Pareto front. To investigate how this potential emergence timing trade-off might constrain adaptation to increasing aridity, we sourced seeds of two grasses, Stipa pulchra and Bromus diandrus, from multiple maternal lines within populations across an aridity gradient in California and examined their performance in a greenhouse experiment. We monitored emergence and assayed ungerminated seeds for viability to determine seed persistence, a metric of potential among-year emergence spread. In both species, maternal lines with larger fractions of persistent seeds emerged later, indicating a trade-off between within-year emergence speed and potential among-year emergence spread. In both species, populations on the Pareto front for both earlier emergence and larger seed persistence fraction occupied significantly more arid sites than populations off the Pareto front, consistent with the hypothesis that more arid sites impose the strongest selection for earlier within-year emergence and greater among-year emergence spread. Our results provide an example of how evaluating genetically based correlations within populations and applying Pareto optimality among populations can be used to detect evolutionary constraints and adaptation across environmental gradients.

Published
2021

5. Viral speciation through subcellular genetic isolation and virogenesis incompatibility.

Author

Chaikeeratisak, Vorrapon, Birkholz, Erica A, Prichard, Amy M, Egan, MacKennon E, Mylvara, Avani, Nonejuie, Poochit, Nguyen, Katrina T, Sugie, Joseph, Meyer, Justin R, and Pogliano, Joe

Subjects
Cell Nucleus, Subcellular Fractions, Pseudomonas aeruginosa, Bacteriophages, Green Fluorescent Proteins, Species Specificity, Genetic Speciation
Abstract

Understanding how biological species arise is critical for understanding the evolution of life on Earth. Bioinformatic analyses have recently revealed that viruses, like multicellular life, form reproductively isolated biological species. Viruses are known to share high rates of genetic exchange, so how do they evolve genetic isolation? Here, we evaluate two related bacteriophages and describe three factors that limit genetic exchange between them: 1) A nucleus-like compartment that physically separates replicating phage genomes, thereby limiting inter-phage recombination during co-infection; 2) A tubulin-based spindle that orchestrates phage replication and forms nonfunctional hybrid polymers; and 3) A nuclear incompatibility factor that reduces phage fitness. Together, these traits maintain species differences through Subcellular Genetic Isolation where viral genomes are physically separated during co-infection, and Virogenesis Incompatibility in which the interaction of cross-species components interferes with viral production.

Published
2021

6. Leaky resistance and the conditions for the existence of lytic bacteriophage.

Author

Chaudhry, Waqas N, Pleška, Maroš, Shah, Nilang N, Weiss, Howard, McCall, Ingrid C, Meyer, Justin R, Gupta, Animesh, Guet, Călin C, and Levin, Bruce R

Subjects
Bacteria, Escherichia coli, Bacteriophages, Bacteriophage lambda, Genetics, Population, Lysogeny, Models, Theoretical, Host Microbial Interactions, Genetics, Population, Models, Theoretical, Biological Sciences, Agricultural and Veterinary Sciences, Medical and Health Sciences, Developmental Biology
Abstract

In experimental cultures, when bacteria are mixed with lytic (virulent) bacteriophage, bacterial cells resistant to the phage commonly emerge and become the dominant population of bacteria. Following the ascent of resistant mutants, the densities of bacteria in these simple communities become limited by resources rather than the phage. Despite the evolution of resistant hosts, upon which the phage cannot replicate, the lytic phage population is most commonly maintained in an apparently stable state with the resistant bacteria. Several mechanisms have been put forward to account for this result. Here we report the results of population dynamic/evolution experiments with a virulent mutant of phage Lambda, λVIR, and Escherichia coli in serial transfer cultures. We show that, following the ascent of λVIR-resistant bacteria, λVIR is maintained in the majority of cases in maltose-limited minimal media and in all cases in nutrient-rich broth. Using mathematical models and experiments, we show that the dominant mechanism responsible for maintenance of λVIR in these resource-limited populations dominated by resistant E. coli is a high rate of either phenotypic or genetic transition from resistance to susceptibility-a hitherto undemonstrated mechanism we term "leaky resistance." We discuss the implications of leaky resistance to our understanding of the conditions for the maintenance of phage in populations of bacteria-their "existence conditions."

Published
2018

12. More evolvable bacteriophages better suppress their host.

Author

Horwitz, Elijah K., Strobel, Hannah M., Haiso, Jason, and Meyer, Justin R.

Subjects
BACTERIOPHAGES, BACTERIAL population, AMINO acids
Abstract

The number of multidrug‐resistant strains of bacteria is increasing rapidly, while the number of new antibiotic discoveries has stagnated. This trend has caused a surge in interest in bacteriophages as anti‐bacterial therapeutics, in part because there is near limitless diversity of phages to harness. While this diversity provides an opportunity, it also creates the dilemma of having to decide which criteria to use to select phages. Here we test whether a phage's ability to coevolve with its host (evolvability) should be considered and how this property compares to two previously proposed criteria: fast reproduction and thermostability. To do this, we compared the suppressiveness of three phages that vary by a single amino acid yet differ in these traits such that each strain maximized two of three characteristics. Our studies revealed that both evolvability and reproductive rate are independently important. The phage most able to suppress bacterial populations was the strain with high evolvability and reproductive rate, yet this phage was unstable. Phages varied due to differences in the types of resistance evolved against them and their ability to counteract resistance. When conditions were shifted to exaggerate the importance of thermostability, one of the stable phages was most suppressive in the short‐term, but not over the long‐term. Our results demonstrate the utility of biological therapeutics' capacities to evolve and adjust in action to resolve complications like resistance evolution. Furthermore, evolvability is a property that can be engineered into phage therapeutics to enhance their effectiveness. [ABSTRACT FROM AUTHOR]

Published
2024
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16. Viral Receptor-Binding Protein Evolves New Function through Mutations That Cause Trimer Instability and Functional Heterogeneity.

Author

Strobel, Hannah M, Labador, Sweetzel D, Basu, Dwaipayan, Sane, Mrudula, Corbett, Kevin D, and Meyer, Justin R

Subjects
VIRAL proteins, PROTEIN conformation, HETEROGENEITY, PROTEIN models, STRUCTURAL models, PROTEIN stability, HOST-virus relationships
Abstract

When proteins evolve new activity, a concomitant decrease in stability is often observed because the mutations that confer new activity can destabilize the native fold. In the conventional model of protein evolution, reduced stability is considered a purely deleterious cost of molecular innovation because unstable proteins are prone to aggregation and are sensitive to environmental stressors. However, recent work has revealed that nonnative, often unstable protein conformations play an important role in mediating evolutionary transitions, raising the question of whether instability can itself potentiate the evolution of new activity. We explored this question in a bacteriophage receptor-binding protein during host-range evolution. We studied the properties of the receptor-binding protein of bacteriophage λ before and after host-range evolution and demonstrated that the evolved protein is relatively unstable and may exist in multiple conformations with unique receptor preferences. Through a combination of structural modeling and in vitro oligomeric state analysis, we found that the instability arises from mutations that interfere with trimer formation. This study raises the intriguing possibility that protein instability might play a previously unrecognized role in mediating host-range expansions in viruses. [ABSTRACT FROM AUTHOR]

Published
2024
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19. A mobile intron facilitates interference competition between co-infecting viruses

Author

Birkholz, Erica A., primary, Morgan, Chase J., additional, Laughlin, Thomas G., additional, Lau, Rebecca K., additional, Prichard, Amy, additional, Rangarajan, Sahana, additional, Meza, Gabrielle N., additional, Lee, Jina, additional, Armbruster, Emily G., additional, Suslov, Sergey, additional, Pogliano, Kit, additional, Meyer, Justin R., additional, Villa, Elizabeth, additional, Corbett, Kevin D., additional, and Pogliano, Joe, additional

Published
2023
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24. Fecal virome transplantation is sufficient to alter fecal microbiota and drive lean and obese body phenotypes in mice

Author

Borin, Joshua M., primary, Liu, Roland, additional, Wang, Yanhan, additional, Wu, Tsung-Chin, additional, Chopyk, Jessica, additional, Huang, Lina, additional, Kuo, Peiting, additional, Ghose, Chandrabali, additional, Meyer, Justin R., additional, Tu, Xin M., additional, Schnabl, Bernd, additional, and Pride, David T., additional

Published
2023
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42. Comparison of bacterial suppression by phage cocktails, dual‐receptor generalists, and coevolutionarily trained phages.

Author

Borin, Joshua M., Lee, Justin J., Gerbino, Krista R., and Meyer, Justin R.

Subjects
BACTERIOPHAGES, DRUG resistance in bacteria, COCKTAILS, BACTERIAL diseases, ESCHERICHIA coli
Abstract

The evolution and spread of antibiotic‐resistant bacteria have renewed interest in phage therapy, the use of bacterial viruses (phages) to combat bacterial infections. The delivery of phages in cocktails where constituent phages target different modalities (e.g., receptors) may improve treatment outcomes by making it more difficult for bacteria to evolve resistance. However, the multipartite nature of cocktails may lead to unintended evolutionary and ecological outcomes. Here, we compare a 2‐phage cocktail with a largely unconsidered group of phages: generalists that can infect through multiple, independent receptors. We find that λ phage generalists and cocktails that target the same receptors (LamB and OmpF) suppress Escherichia coli similarly for ~2 days. Yet, a "trained" generalist phage, which previously adapted to its host via 28 days of coevolution, demonstrated superior suppression. To understand why the trained generalist was more effective, we measured the resistance of bacteria against each of our phages. We find that, when bacteria were assailed by two phages in the cocktail, they evolved mutations in manXYZ, a host inner‐membrane transporter that λ uses to move its DNA across the periplasmic space and into the cell for infection. This provided cross‐resistance against the cocktail and untrained generalist. However, these mutations were ineffective at blocking the trained generalist because, through coevolutionary training, it evolved to bypass manXYZ resistance. The trained generalist's past experiences in training make it exceedingly difficult for bacteria to evolve resistance, further demonstrating the utility of coevolutionary phage training for improving the therapeutic properties of phages. [ABSTRACT FROM AUTHOR]

Published
2023
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