Abstract
CA-MRSA infection, driven by the emergence of the USA300 genetic background, has become epidemic in the United States. USA300 isolates are hypervirulent, compared with other CA- and HA-MRSA strains, in experimental models of necrotizing pneumonia and skin infection. Interestingly, USA300 isolates also have increased expression of core genomic global regulatory and virulence factor genes, including agr and saeRS. To test the hypothesis that agr and saeRS promote the observed hypervirulent phenotype of USA300, isogenic deletion mutants of each were constructed in USA300. The effects of gene deletion on expression and protein abundance of selected downstream virulence genes were assessed by semiquantitative real-time reverse-transcriptase PCR (qRT-PCR) and western blot, respectively. The effects of gene deletion were also assessed in mouse models of necrotizing pneumonia and skin infection. Deletion of saeRS, and, to a lesser extent, agr, resulted in attenuated expression of the genes encoding α-hemolysin (hla) and the Panton-Valentine leukocidin (lukSF-PV). Despite the differences in hla transcription, the toxin was undetectable in culture supernatants of either of the deletion mutants. Deletion of agr, but not saeRS, markedly increased the expression of the gene encoding protein A (spa), which correlated with increased protein abundance. Each deletion mutant demonstrated significant attenuation of virulence, compared with wild-type USA300, in mouse models of necrotizing pneumonia and skin infection. We conclude that agr and saeRS each independently contribute to the remarkable virulence of USA300, likely by means of their effects on expression of secreted toxins.
Highlights
Infections caused by methicillin-resistant Staphylococcus aureus (MRSA) are common and frequently severe [1,2]
The observation that USA300 strains have increased in vitro expression of the global regulatory systems saeRS and agr [7] led us to investigate the possibility that increased transcription of these operons underlies this virulence
SaeRS was necessary for mortality in the necrotizing pneumonia model and for dermonecrosis in the skin infection model
Summary
Infections caused by methicillin-resistant Staphylococcus aureus (MRSA) are common and frequently severe [1,2]. An increasing percentage of these infections have occurred among previously healthy individuals without traditional risk factors, including children [3]. Among these community-associated MRSA (CA-MRSA) infections, uncomplicated skin and soft tissue infections predominate; serious disease, including complicated skin and soft tissue infections and necrotizing pneumonia requiring hospitalization, occur frequently [1]. The first reports of severe CA-MRSA infections in the United States implicated the genetic background USA400, as defined by pulsed-field gel electrophoresis, as the predominant cause [4,5]. The relationship between fitness and virulence is a subject of ongoing discussion, understanding the molecular mechanisms of the extraordinary virulence of USA300 may provide insight into the pathophysiology of this remarkable genetic background
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