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Genome evolution and the emergence of pathogenicity in avian Escherichia coli

Author

Listed:
  • Leonardos Mageiros

    (University of Bath, Claverton Down)

  • Guillaume Méric

    (University of Bath, Claverton Down)

  • Sion C. Bayliss

    (University of Bath, Claverton Down
    MRC Cloud Infrastructure for Microbial Bioinformatics (CLIMB) Consortium)

  • Johan Pensar

    (University of Oslo
    University of Helsinki)

  • Ben Pascoe

    (University of Bath, Claverton Down
    University of Oslo)

  • Evangelos Mourkas

    (University of Bath, Claverton Down)

  • Jessica K. Calland

    (University of Bath, Claverton Down)

  • Koji Yahara

    (National Institute of Infectious Diseases)

  • Susan Murray

    (Uppsala University)

  • Thomas S. Wilkinson

    (Institute of Life Science)

  • Lisa K. Williams

    (Institute of Life Science)

  • Matthew D. Hitchings

    (Institute of Life Science)

  • Jonathan Porter

    (Environment Agency)

  • Kirsty Kemmett

    (University of Liverpool, Leahurst Campus)

  • Edward J. Feil

    (University of Bath, Claverton Down)

  • Keith A. Jolley

    (South Parks Road)

  • Nicola J. Williams

    (University of Liverpool, Leahurst Campus)

  • Jukka Corander

    (University of Oslo
    University of Helsinki
    Wellcome Sanger Institute)

  • Samuel K. Sheppard

    (University of Bath, Claverton Down
    MRC Cloud Infrastructure for Microbial Bioinformatics (CLIMB) Consortium
    South Parks Road)

Abstract

Chickens are the most common birds on Earth and colibacillosis is among the most common diseases affecting them. This major threat to animal welfare and safe sustainable food production is difficult to combat because the etiological agent, avian pathogenic Escherichia coli (APEC), emerges from ubiquitous commensal gut bacteria, with no single virulence gene present in all disease-causing isolates. Here, we address the underlying evolutionary mechanisms of extraintestinal spread and systemic infection in poultry. Combining population scale comparative genomics and pangenome-wide association studies, we compare E. coli from commensal carriage and systemic infections. We identify phylogroup-specific and species-wide genetic elements that are enriched in APEC, including pathogenicity-associated variation in 143 genes that have diverse functions, including genes involved in metabolism, lipopolysaccharide synthesis, heat shock response, antimicrobial resistance and toxicity. We find that horizontal gene transfer spreads pathogenicity elements, allowing divergent clones to cause infection. Finally, a Random Forest model prediction of disease status (carriage vs. disease) identifies pathogenic strains in the emergent ST-117 poultry-associated lineage with 73% accuracy, demonstrating the potential for early identification of emergent APEC in healthy flocks.

Suggested Citation

  • Leonardos Mageiros & Guillaume Méric & Sion C. Bayliss & Johan Pensar & Ben Pascoe & Evangelos Mourkas & Jessica K. Calland & Koji Yahara & Susan Murray & Thomas S. Wilkinson & Lisa K. Williams & Matt, 2021. "Genome evolution and the emergence of pathogenicity in avian Escherichia coli," Nature Communications, Nature, vol. 12(1), pages 1-13, December.
    • Handle: RePEc:nat:natcom:v:12:y:2021:i:1:d:10.1038_s41467-021-20988-w
    DOI: 10.1038/s41467-021-20988-w
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    Cited by:

    1. Jay Vornhagen & Emily K. Roberts & Lavinia Unverdorben & Sophia Mason & Alieysa Patel & Ryan Crawford & Caitlyn L. Holmes & Yuang Sun & Alexandra Teodorescu & Evan S. Snitkin & Lili Zhao & Patricia J., 2022. "Combined comparative genomics and clinical modeling reveals plasmid-encoded genes are independently associated with Klebsiella infection," Nature Communications, Nature, vol. 13(1), pages 1-15, December.

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