Your search keyword '"O'Brien, Siobhan"' showing total 2 results

1. Parallel ecological and evolutionary responses to selection in a natural bacterial community.

Author

Hesse, Elze, Luján, Adela M., O'Brien, Siobhan, Newbury, Arthur, McAvoy, Terence, Pascual, Jesica Soria, Bayer, Florian, Hodgson, David J., and Buckling, Angus

Subjects

NATURAL selection, NONFERROUS metals, BIOTIC communities, BACTERIAL communities, HEAVY metals

Abstract

Evolution can occur over ecological timescales, suggesting a potentially important role for rapid evolution in shaping community trait distributions. However, evidence of concordant eco-evolutionary dynamics often comes from in vitro studies of highly simplified communities, and measures of ecological and evolutionary dynamics are rarely directly comparable. Here, we quantified how ecological species sorting and rapid evolution simultaneously shape community trait distributions by tracking within- and between-species changes in a key trait in a complex bacterial community. We focused on the production of siderophores; bacteria use these costly secreted metabolites to scavenge poorly soluble iron and to detoxify environments polluted with toxic nonferrous metals. We found that responses to copper-imposed selection within and between species were ultimately the same--intermediate siderophore levels were favored--and occurred over similar timescales. Despite being a social trait, this level of siderophore production was selected regardless of whether species evolved in isolation or in a community context. Our study suggests that evolutionary selection can play a pivotal role in shaping community trait distributions within natural, highly complex, bacterial communities. Furthermore, trait evolution may not always be qualitatively affected by interactions with other community members. [ABSTRACT FROM AUTHOR]

Published

2024

2. Temperate phages both mediate and drive adaptive evolution in pathogen biofilms.

Author

Davies, Emily V., James, Chloe E., Williams, David, O'Brien, Siobhan, Fothergill, Joanne L., Haldenby, Sam, Paterson, Steve, Winstanley, Craig, and Brockhurst, Michael A.

Subjects

BACTERIOPHAGES, BIOFILMS, BACTERIAL diseases, TRANSPOSONS, BACTERIA insertion mutation, QUORUM sensing, CYSTIC fibrosis

Abstract

Temperate phages drive genomic diversification in bacterial pathogens. Phage-derived sequences are more common in pathogenic than nonpathogenic taxa and are associated with changes in pathogen virulence. High abundance and mobilization of temperate phages within hosts suggests that temperate phages could promote withinhost evolution of bacterial pathogens. However, their role in pathogen evolution has not been experimentally tested. We experimentally evolved replicate populations of Pseudomonas aeruginosa with or without a community of three temperate phages active in cystic fibrosis (CF) lung infections, including the transposable phage, ɸ4, which is closely related to phage D3112. Populations grew as freefloating biofilms in artificial sputum medium, mimicking sputum of CF lungs where P. aeruginosa is an important pathogen and undergoes evolutionary adaptation and diversification during chronic infection. Although bacterial populations adapted to the biofilm environment in both treatments, population genomic analysis revealed that phages altered both the trajectory and mode of evolution. Populations evolving with phages exhibited a greater degree of parallel evolution and faster selective sweeps than populations without phages. Phage ɸ4 integrated randomly into the bacterial chromosome, but integrations into motility-associated genes and regulators of quorum sensing systems essential for virulence were selected in parallel, strongly suggesting that these insertional inactivation mutations were adaptive. Temperate phages, and in particular transposable phages, are therefore likely to facilitate adaptive evolution of bacterial pathogens within hosts. [ABSTRACT FROM AUTHOR]

Published

2016