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Article

Rapid colonisation of environmental plastic waste by pathogenic bacteria drives adaptive phenotypic changes

Details

Citation

Ormsby MJ, Woodford L, Fellows R, White HL & Quilliam RS (2024) Rapid colonisation of environmental plastic waste by pathogenic bacteria drives adaptive phenotypic changes. Journal of Hazardous Materials, 480, Art. No.: 136359. https://doi.org/10.1016/j.jhazmat.2024.136359

Abstract
Microbial biofilms on environmental plastic pollution can serve as a reservoir for both pathogenic and commensal bacteria. Associating with this ‘plastisphere’, provides a mechanism for the wider dissemination of pathogens within the environment and a greater potential for human exposure. For pathogens to bind to environmental plastic waste they need to be in close contact with it; therefore, understanding how rapidly pathogens can bind to plastics and the temporal colonisation dynamics of the continual cycling between the plastisphere and the environment are important factors for quantifying the persistence of human pathogens. Using simulated environmental conditions, we demonstrate that pathogenic E. coli O157 can rapidly colonise plastics (within 30 min) and persist for extended periods (at least 21 days), at concentrations sufficient to cause human infection. Importantly, repeated colonisation and dissociation cycles of E. coli O157 from the plastisphere leads to an enhanced capacity for persistence and the emergence of variants with increased virulence traits, including improved biofilm formation and antibiotic tolerance. This phenotypic adaptation to repeated colonisation of environmental plastic surfaces could be selecting for more persistent and virulent strains of pathogens, and hence increase the co-pollutant risks associated with plastic pollution.

Keywords
Plastisphere; Biofilm; Wastewater; E. coli 0157; AMR

Journal
Journal of Hazardous Materials: Volume 480

StatusPublished
Funders and
Publication date31/12/2024
Publication date online30/11/2024
Date accepted by journal28/10/2024
URL
PublisherElsevier BV
ISSN0304-3894

People (3)

Miss Rosie Fellows

Miss Rosie Fellows

Research Assistant, Biological and Environmental Sciences

Professor Richard Quilliam

Professor Richard Quilliam

Professor, Biological and Environmental Sciences

Dr Luke Woodford

Dr Luke Woodford

Postdoctoral Research Fellow, Biological and Environmental Sciences

Projects (2)

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