Reversible mutations in gliding motility and virulence genes: A flexible and efficient phage defence mechanism in Flavobacterium psychrophilum

Research output: Contribution to journalJournal articlepeer-review

Documents

  • Fulltext

    Final published version, 1.72 MB, PDF document

  • Jóhanna Jørgensen
  • Krister Sundell
  • Daniel Castillo
  • Liv S. Dramshøj
  • Natasja B. Jørgensen
  • Susie B. Madsen
  • Lotta Landor
  • Tom Wiklund
  • Valentina L. Donati
  • Lone Madsen
  • Inger Dalsgaard
  • Middelboe, Mathias

Flavobacteria are among the most important pathogens in freshwater salmonid aquaculture worldwide. Due to concerns regarding development of antibiotic resistance, phage therapy has been proposed as a solution to decrease pathogen load. However, application of phages is challenged by the development of phage resistance, and knowledge of the mechanisms and implications of phage resistance is therefore required. To study this, 27 phage-resistant isolates of F. psychrophilum were genome sequenced and characterized to identify genetic modifications and evaluate changes in phenotypic traits, including virulence against rainbow trout. Phage-resistant isolates showed reduction or loss of gliding motility, proteolytic activity, and adhesion to surfaces, and most isolates were completely non-virulent against rainbow trout fry. Genomic analysis revealed that most phage-resistant isolates had mutations in genes associated with gliding motility and virulence. Reversal of these mutations in a sub-set of isolates led to regained motility, proteolytic activity, virulence and phage susceptibility. Although costly, the fast generation of phage resistance driven by single, reversible mutations likely represents a flexible and efficient phage defence mechanism in F. psychrophilum. The results further suggest that phage administration in aquaculture systems to prevent F. psychrophilum outbreaks selects for non-virulent phage-resistant phenotypes.

Original languageEnglish
JournalEnvironmental Microbiology
Volume24
Issue number10
Pages (from-to)4915-4930
ISSN1462-2912
DOIs
Publication statusPublished - 2022

    Research areas

  • COLD-WATER DISEASE, CELL-SURFACE, RAINBOW-TROUT, ANTIMICROBIAL SUSCEPTIBILITY, IN-VITRO, JOHNSONIAE, DIVERSITY, SECRETION, SEQUENCE, VIVO

ID: 316744429