期刊
MBIO
卷 12, 期 6, 页码 -出版社
AMER SOC MICROBIOLOGY
DOI: 10.1128/mBio.02259-21
关键词
livestock MRSA; CC398; Sa3int; phage; excision; integration; φ 13; recombinase; integrase; S; aureus; prophage; attP
类别
资金
- European Union [765147]
The study revealed that phages carrying virulence factors can adapt and integrate into new strains of Staphylococcus aureus, even those lacking preferred integration sites. This adaptation is facilitated by the promiscuity of the phage-encoded tyrosine recombinase, allowing the phages to increase virulence and zoonotic potential in different host organisms.
Bacterial pathogens commonly carry prophages that express virulence factors, and human strains of Staphylococcus aureus carry Sa3int phages, which promote immune evasion. Recently, however, these phages have been found in livestock-associated, methicillin-resistant S. aureus (LA-MRSA). This is surprising, as LA-MRSA strains contain a mutated primary bacterial integration site, which likely explains why the rare integration events that do occur mostly happen at alternative locations. Using deep sequencing, we show that after initial integration at secondary sites, Sa3int phages adapt through nucleotide changes in their attachment sequences to increase homology with alternative bacterial attachment sites. Importantly, this homology significantly enhances integrations in new rounds of infections. We propose that promiscuity of the phageencoded tyrosine recombinase is responsible for establishment of Sa3int phages in LAMRSA. Our results demonstrate that phages can adopt extensive population heterogeneity, leading to establishment in strains lacking bona fide integration sites. Ultimately, their presence may increase virulence and zoonotic potential of pathogens with major implications for human health. IMPORTANCE A growing number of humans are being infected by antibiotic resistant Staphylococcus aureus originating from livestock. The preference of S. aureus for humans or animals is in part determined by factors encoded by viruses (phages) that reside in the bacterial genome. Here, we reveal a process by which phages adapt to and become integrated in new strains of S. aureus lacking the preferred phage integration site. We propose that this is due to the relaxed specificity of a phage-encoded enzyme called recombinase. As this recombinase is used by many other phages, our results might have implications for a broader range of phages. Importantly, the adaptation described here enables S. aureus to jump between host organisms and increases its zoonotic threat.
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