8 results on '"Morgan, Andrew"'
Search Results
2. Higher resources decrease fluctuating selection during host-parasite coevolution
- Author
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Lopez Pascua, Laura, Hall, Alex, Morgan, Andrew D., Boots, Mike, and Buckling, Angus
- Subjects
Bacteria ,Experimental evolution ,Adaptive dynamics ,Virus - Abstract
We still know very little about how the environment influences coevolutionary dynamics. Here, we investigated both theoretically and empirically how nutrient availability affects the relative extent of escalation of resistance and infectivity (arms race dynamic; ARD) and fluctuating selection (fluctuating selection dynamic; FSD) in experimentally coevolving populations of bacteria and viruses. By comparing interactions between clones of bacteria and viruses both within- and between-time points, we show that increasing nutrient availability resulted in coevolution shifting from FSD, with fluctuations in average infectivity and resistance ranges over time, to ARD. Our model shows that range fluctuations with lower nutrient availability can be explained both by elevated costs of resistance (a direct effect of nutrient availability), and reduced benefits of resistance when population sizes of hosts and parasites are lower (an indirect effect). Nutrient availability can therefore predictably and generally affect qualitative coevolutionary dynamics by both direct and indirect (mediated through ecological feedbacks) effects on costs of resistance., Ecology Letters, 17 (11), ISSN:1461-023X, ISSN:1461-0248
- Published
- 2014
3. Selection on non-social traits limits the invasion of social cheats.
- Author
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Morgan, Andrew D., Quigley, Benjamin J. Z., Brown, Sam P., Buckling, Angus, and Baalen, Minus
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BACTERIAL ecology , *PSEUDOMONAS fluorescens , *BACTERIAL population , *COEVOLUTION , *BACTERIOPHAGES , *MICROBIAL invasiveness , *MICROBIAL virulence - Abstract
While the conditions that favour the maintenance of cooperation have been extensively investigated, the significance of non-social selection pressures on social behaviours has received little attention. In the absence of non-social selection pressures, patches of cooperators are vulnerable to invasion by cheats. However, we show both theoretically, and experimentally with the bacterium Pseudomonas fluorescens, that cheats may be unable to invade patches of cooperators under strong non-social selection (both a novel abiotic environment and to a lesser extent, the presence of a virulent parasite). This is because beneficial mutations are most likely to arise in the numerically dominant cooperator population. Given the ubiquity of novel selection pressures on microbes, these results may help to explain why cooperation is the norm in natural populations of microbes. [ABSTRACT FROM AUTHOR]
- Published
- 2012
- Full Text
- View/download PDF
4. Comparative Analysis of Myxococcus Predation on Soil Bacteria.
- Author
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Morgan, Andrew D., MacLean, R. Craig, Hillesland, Kristina L., and Velicer, Gregory J.
- Subjects
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MYXOCOCCUS , *SOILS , *BACTERIA , *PREDATORY animals , *PROKARYOTES - Abstract
Predator-prey relationships among prokaryotes have received little attention but are likely to be important determinants of the composition, structure, and dynamics of microbial communities. Many species of the soil-dwelling myxobacteria are predators of other microbes, but their predation range is poorly characterized. To better understand the predatory capabilities of myxobacteria in nature, we analyzed the predation performance of numerous Myxococcus isolates across 12 diverse species of bacteria. All predator isolates could utilize most potential prey species to effectively fuel colony expansion, although one species hindered predator swarming relative to a control treatment with no growth substrate. Predator strains varied significantly in their relative performance across prey types, but most variation in predatory performance was determined by prey type, with Gram-negative prey species supporting more Myxococcus growth than Gram-positive species. There was evidence for specialized predator performance in some predator-prey combinations. Such specialization may reduce resource competition among sympatric strains in natural habitats. The broad prey range of the Myxococcus genus coupled with its ubiquity in the soil suggests that myxobacteria are likely to have very important ecological and evolutionary effects on many species of soil prokaryotes. [ABSTRACT FROM AUTHOR]
- Published
- 2010
- Full Text
- View/download PDF
5. Experimental coevolution with bacteria and phage: The Pseudomonas fluorescens—Φ2 model system
- Author
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Brockhurst, Michael A., Morgan, Andrew D., Fenton, Andrew, and Buckling, Angus
- Subjects
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PARASITES , *BACTERIA , *BACTERIOPHAGES , *ANTAGONISTIC fungi , *BIOLOGICAL evolution , *BIOLOGICAL systems - Abstract
Abstract: Parasites are ubiquitous in biological systems and antagonistic coevolution between hosts and parasites is thought be a major ecological and evolutionary force. Recent experiments using laboratory populations of bacteria and their parasitic viruses, phage, have provided the first direct empirical evidence of antagonistic coevolution in action. In this article we describe this model system and synthesise recent findings that address the causes and consequences of antagonistic coevolution. [Copyright &y& Elsevier]
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- 2007
- Full Text
- View/download PDF
6. Differential impact of simultaneous migration on coevolving hosts and parasites.
- Author
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Morgan, Andrew D., Brockhurst, Michael A., Lopez-Pascua, Laura D. C., Pal, Csaba, and Buckling, Angus
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HOST-parasite relationships , *PARASITES , *PSEUDOMONAS fluorescens , *GENETICS , *BACTERIA - Abstract
Background: The dynamics of antagonistic host-parasite coevolution are believed to be crucially dependent on the rate of migration between populations. We addressed how the rate of simultaneous migration of host and parasite affected resistance and infectivity evolution of coevolving meta-populations of the bacterium Pseudomonas fluorescens and a viral parasite (bacteriophage). The increase in genetic variation resulting from small amounts of migration is expected to increase rates of adaptation of both host and parasite. However, previous studies suggest phages should benefit more from migration than bacteria; because in the absence of migration, phages are more genetically limited and have a lower evolutionary potential compared to the bacteria. Results: The results supported the hypothesis: migration increased the resistance of bacteria to their local (sympatric) hosts. Moreover, migration benefited phages more than hosts with respect to 'global' (measured with respect to the whole range of migration regimes) patterns of resistance and infectivity, because of the differential evolutionary responses of bacteria and phage to different migration regimes. Specifically, we found bacterial global resistance peaked at intermediate rates of migration, whereas phage global infectivity plateaued when migration rates were greater than zero. Conclusion: These results suggest that simultaneous migration of hosts and parasites can dramatically affect the interaction of host and parasite. More specifically, the organism with the lower evolutionary potential may gain the greater evolutionary advantage from migration. [ABSTRACT FROM AUTHOR]
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- 2007
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7. LETTER Population mixing accelerates coevolution.
- Author
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Brockhurst, Michael A., Morgan, Andrew D., Rainey, Paul B., and Buckling, Angus
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PARASITES , *COEVOLUTION , *BACTERIA , *PSEUDOMONAS fluorescens , *BACTERIOPHAGES - Abstract
Theory predicts that mixing in spatially structured populations of hosts and parasites can increase the rate of antagonistic coevolution. We experimentally tested this prediction by allowing populations of bacteria ( Pseudomonas fluorescens) and parasitic bacteriophage to coevolve in mixed and unmixed microcosms. Coevolution proceeded at approximately twice the rate in mixed populations compared with unmixed populations and caused the evolution of more resistant hosts and more infective parasites. [ABSTRACT FROM AUTHOR]
- Published
- 2003
- Full Text
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8. Wild Mouse Gut Microbiota Promotes Host Fitness and Improves Disease Resistance.
- Author
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Rosshart, Stephan P., Vassallo, Brian G., Angeletti, Davide, Hutchinson, Diane S., Morgan, Andrew P., Takeda, Kazuyo, Hickman, Heather D., McCulloch, John A., Badger, Jonathan H., Ajami, Nadim J., Trinchieri, Giorgio, Pardo-Manuel de Villena, Fernando, Yewdell, Jonathan W., and Rehermann, Barbara
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GUT microbiome , *MUTAGENS , *NATURAL immunity , *INFLAMMATION , *LABORATORY mice , *INFLUENZA viruses , *COLON cancer - Abstract
Summary Laboratory mice, while paramount for understanding basic biological phenomena, are limited in modeling complex diseases of humans and other free-living mammals. Because the microbiome is a major factor in mammalian physiology, we aimed to identify a naturally evolved reference microbiome to better recapitulate physiological phenomena relevant in the natural world outside the laboratory. Among 21 distinct mouse populations worldwide, we identified a closely related wild relative to standard laboratory mouse strains. Its bacterial gut microbiome differed significantly from its laboratory mouse counterpart and was transferred to and maintained in laboratory mice over several generations. Laboratory mice reconstituted with natural microbiota exhibited reduced inflammation and increased survival following influenza virus infection and improved resistance against mutagen/inflammation-induced colorectal tumorigenesis. By demonstrating the host fitness-promoting traits of natural microbiota, our findings should enable the discovery of protective mechanisms relevant in the natural world and improve the modeling of complex diseases of free-living mammals. Video Abstract [ABSTRACT FROM AUTHOR]
- Published
- 2017
- Full Text
- View/download PDF
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