Abstract
Bacteriophages exert strong evolutionary pressure on their microbial hosts. In their lytic lifecycle, complete bacterial subpopulations are utilized as hosts for bacteriophage replication. However, during their lysogenic lifecycle, bacteriophages can integrate into the host chromosome and alter the host’s genomic make-up, possibly resulting in evolutionary important adjustments. Not surprisingly, bacteria have evolved sophisticated immune systems to protect against phage infection. Streptococcus pyogenes isolates are frequently lysogenic and their prophages have been shown to be major contributors to the virulence of this pathogen. Most S. pyogenes phage research has focused on genomic prophages in relation to virulence, but little is known about the defensive arsenal of S. pyogenes against lytic phage infection. Here, we characterized Phage A1, an S. pyogenes bacteriophage, and investigated several mechanisms that S. pyogenes utilizes to protect itself against phage predation. We show that Phage A1 belongs to the Siphoviridae family and contains a circular double-stranded DNA genome that follows a modular organization described for other streptococcal phages. After infection, the Phage A1 genome can be detected in isolated S. pyogenes survivor strains, which enables the survival of the bacterial host and Phage A1 resistance. Furthermore, we demonstrate that the type II-A CRISPR-Cas system of S. pyogenes acquires new spacers upon phage infection, which are increasingly detectable in the absence of a capsule. Lastly, we show that S. pyogenes produces membrane vesicles that bind to phages, thereby limiting the pool of phages available for infection. Altogether, this work provides novel insight into survival strategies employed by S. pyogenes to combat phage predation.
Highlights
The so-called “flesh-eating bacterium” Streptococcus pyogenes is a Gram-positive βhemolytic pathogen that strictly infects humans in natural settings [1,2]
We show that Phage A1 is a putative temperate phage and that its DNA can be detected in S. pyogenes genomes, resulting in strains that are resistant to subsequent infections
To evaluate whether increased amounts of membrane vesicles (MVs) produced by S. pyogenes are able to limit phage predation, we incubated purified MVs of S. pyogenes SF370 with Phage A1 before infecting S. pyogenes SF370
Summary
The so-called “flesh-eating bacterium” Streptococcus pyogenes is a Gram-positive βhemolytic pathogen that strictly infects humans in natural settings [1,2]. S. pyogenes can colonize the throat and skin asymptomatically [3], the hallmark of S. pyogenes is its ability to cause a vast variety of diseases [4]. Clinical manifestations of S. pyogenesinfections range from superficial skin infections and pharyngitis to toxin-mediated diseases (e.g., streptococcal toxic shock syndrome (STSS)), and invasive disease in subcutaneous tissues [5]. With an estimated 616 million pharyngitis cases, almost 2 million severe S. pyogenes disease cases and more than 500,000 deaths per year, S. pyogenes remains among the top 10 individual pathogens causing morbidity and mortality [6]. No penicillin-resistant S. pyogenes strains have been observed in clinical settings, up to 40%
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