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Whole genome sequencing of phage resistant Bacillus anthracis mutants reveals an essential role for cell surface anchoring protein CsaB in phage AP50c adsorption

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  • 02/20/2025
Type of Material
Authors
    Kimberly A. Bishop-Lilly, NMRC-FrederickRoger D. Plaut, Food and Drug AdministrationPeter E. Chen, NMRC-FrederickArya Akmal, NMRC-FrederickKristin M. Willner, NMRC-FrederickAmy Butani, NMRC-FrederickShakia Dorsey, NMRC-FrederickVishwesh Mokashi, NMRC-FrederickAlfred J. Mateczun, NMRC-FrederickCarol Chapman, NMRC-FrederickMatroner George, NMRC-FrederickTruong Luu, NMRC-FrederickTimothy D Read, Emory UniversityRichard Calendar, University of CaliforniaScott Stibitz, Food and Drug AdministrationShanmuga Sozhamannan, NMRC-Frederick
Language
  • English
Date
  • 2012-10-26
Publisher
  • BioMed Central
Publication Version
Copyright Statement
  • © 2012 Bishop-Lilly et al.; licensee BioMed Central Ltd.
License
Final Published Version (URL)
Title of Journal or Parent Work
ISSN
  • 1743-422X
Volume
  • 9
Issue
  • 246
Start Page
  • 1
End Page
  • 14
Supplemental Material (URL)
Abstract
  • Background: Spontaneous Bacillus anthracis mutants resistant to infection by phage AP50c (AP50R) exhibit a mucoid colony phenotype and secrete an extracellular matrix. Methods: Here we utilized a Roche/454-based whole genome sequencing approach to identify mutations that are candidates for conferring AP50c phage resistance, followed by genetic deletion and complementation studies to validate the whole genome sequence data and demonstrate that the implicated gene is necessary for AP50c phage infection. Results: Using whole genome sequence data, we mapped the relevant mutations in six AP50R strains to csaB. Eleven additional spontaneous mutants, isolated in two different genetic backgrounds, were screened by PCR followed by Sanger sequencing of the csaB gene. In each spontaneous mutant, we found either a non-synonymous substitution, a nonsense mutation, or a frame-shift mutation caused by single nucleotide polymorphisms or a 5 base pair insertion in csaB. All together, 5 and 12 of the 17 spontaneous mutations are predicted to yield altered full length and truncated CsaB proteins respectively. As expected from these results, a targeted deletion or frame-shift mutations introduced into csaB in a different genetic background, in a strain not exposed to AP50c, resulted in a phage resistant phenotype. Also, substitution of a highly conserved histidine residue with an alanine residue (H270A) in CsaB resulted in phage resistance, suggesting that a functional CsaB is necessary for phage sensitivity. Conversely, introduction of the wild type allele of csaB in cis into the csaB deletion mutant by homologous recombination or supplying the wild type CsaB protein in trans from a plasmid restored phage sensitivity. The csaB mutants accumulated cell wall material and appeared to have a defective S-layer, whereas these phenotypes were reverted in the complemented strains. Conclusions: Taken together, these data suggest an essential role for csaB in AP50c phage infection, most likely in phage adsorption. (The whole genome sequences generated from this study have been submitted to GenBank under SRA project ID: SRA023659.1 and sample IDs: AP50 R1: SRS113675.1, AP50 R2: SRS113676.1, AP50 R3: SRS113728.1, AP50 R4: SRS113733.1, AP50 R6: SRS113734.1, JB220 Parent: SRS150209.1, JB220 Mutant: SRS150211.1).
Author Notes
Keywords
Research Categories
  • Biology, Virology
  • Biology, Cell
  • Biology, Genetics

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