Characterization of a novel genus bacteriophage and its potential for efficient transfer of modified shuttle plasmids to strains of different clonal complexes.

UNLABELLED

is a significant human pathogen responsible for various nosocomial and community-acquired infections, leading to considerable morbidity and mortality worldwide. Temperate bacteriophages contribute to its virulence and facilitate the dissemination of pathogenicity traits. We isolated a novel siphovirus of the genus, ASZ22RN, derived from a prophage of an clonal complex 7 strain and capable of propagating in the prophage-free laboratory strain RN4220. ASZ22RN either productively infected or lysed from without all 47 tested clinical strains across 12 clonal complexes (CCs), demonstrating its ability to puncture their cell envelopes. When ASZ22RN was propagated in RN4220 cells harboring an plasmid replicating via theta mode, it transduced the plasmid to plasmid-free RN4220 with low frequency. The transduction frequency increased by nearly five orders of magnitude when the plasmid contained a fragment of ASZ22RN DNA (). Most plasmid-transducing particles carried plasmid concatamers, while some carried plasmid-phage DNA hybrids, as demonstrated by DNA sequencing. Strains from all tested CCs served as recipients for transduction, regardless of the presence of type I restriction-modification enzymes targeting plasmid/phage DNA, or prophages with lysis-lysogeny switch regions conferring superinfection immunity to ASZ22RN. Our results indicate that intracellular phage defense systems do not prevent phage-mediated plasmid transfer and demonstrate a simple method for introducing plasmids constructed in into clinical isolates. Moreover, the presence of the ASZ22RN lysis-lysogeny switch region in 21% of tested ASZ22RN-resistant strains highlights superinfection exclusion as a dominant mechanism of resistance to siphoviruses in staphylococci.

IMPORTANCE

This study highlights the capacity of a newly isolated staphylococcal , ASZ22RN, to transfer a low-copy-number shuttle - plasmid to various strains representing major clonal complexes from among clinical isolates. By increasing the plasmid transduction efficiency in an ASZ22RN-specific manner, we show that the primary factor determining a given strain's ability to be a recipient in transduction is the capacity of transducing phage to puncture the cell envelopes of this strain. This can be determined not only based on productive phage infection but also lysis from without. Major intracellular mechanisms protecting from productive phage infection do not impede the transduction-mediated acquisition of plasmids. Moreover, the lack of phage DNA in most of the plasmid-transducing virions indicates the lack of phage contamination in most transductants. Our results offer a promising approach for developing efficient pipelines to introduce plasmids constructed in to clinical isolates.