Faculty Bibliography

SaPIs are a family of homologous phage-related pathogenicity islands in staphylococci that carry superantigen and other virulence genes, and are responsible for a wide variety of superantigen-related diseases. SaPIs are induced to excise and replicate by particular staphylococcal phages and are encapsidated in infectious, small-headed, phage-like particles, which are transmitted at very high frequency among staphylococcal strains and species. SaPI2 is a prototypical member of this family that was identified in a typical menstrual toxic shock syndrome (TSS) strain of Staphylococcus aureus, the so-called Harrisburg strain, and found to be mobilizable by typing phage 80. Most menstrual TSS strains belong to a highly uniform agr group III clone of electrophoretic type (ET) 41, and this study was undertaken to determine whether such strains typically carry SaPI2, and whether it has spread beyond the ET41 clone. We report here the complete sequence of SaPI2, describe its relation to other known SaPIs, and show that it, or a very similar element, is carried by most ET41 strains but that it has disseminated to other strains that have also been implicated in TSS. We show additionally, that SaPIs are widespread among the staphylococci and that most TSS strains carry two or more, including SaPI2

The SaPIs are 14- to 17-kb mobile pathogenicity islands in staphylococci that carry genes for superantigen toxins and other virulence factors and are responsible for the toxic shock syndrome and other superantigen-related diseases. They reside at specific chromosomal sites and are induced by certain bacteriophages to initiate an excision-replication-packaging program, resulting in their incorporation into small infective phage-like particles. These are responsible for very high transfer frequencies that often equal and sometimes exceed the plaque-forming titer of the inducing phage. The ability of the SaPIs to replicate autonomously defines them as individual replicons and, like other prokaryotic replicons, they possess replicon-specific initiation functions. In this paper, we report identification of the SaPI replication origin (ori) and replication initiation protein (Rep), which has helicase as well as initiation activity. The SaPI oris are binding sites for the respective Rep proteins and consist of multiple oligonucleotide repeats in two sets, flanking an AT-rich region that may be the site of initial melting. Plasmids containing the rep-ori complex plus an additional gene, pri, can replicate autonomously in Staphylococcus aureus but are very unstable, probably because of defective segregation

TraP is a triply phosphorylated staphylococcal protein that has been hypothesized to be the mediator of a second Staphylococcus aureus quorum-sensing system, 'SQS1,' that controls expression of the agr system and therefore is essential for the organism's virulence. This hypothesis was based on the loss of agr expression and virulence by a traP mutant of strain 8325-4 and was supported by full complementation of both phenotypic defects by the cloned traP gene in strain NB8 (Y. Gov, I. Borovok, M. Korem, V. K. Singh, R. K. Jayaswal, B. J. Wilkinson, S. M. Rich, and N. Balaban, J. Biol. Chem. 279:14665-14672, 2004), in which the wild-type traP gene was expressed in trans in the 8325-4 traP mutant. We initiated a study of the mechanism by which TraP activates agr and found that the traP mutant strain used for this and other recently published studies has a second mutation, an adventitious stop codon in the middle of agrA, the agr response regulator. The traP mutation, once separated from the agrA defect by outcrossing, had no effect on agr expression or virulence, indicating that the agrA defect accounts fully for the lack of agr expression and for the loss of virulence attributed to the traP mutation. In addition, DNA sequencing showed that the agrA gene in strain NB8 (Gov et al., J. Biol. Chem., 2004), in contrast to that in the agr-defective 8325-4 traP mutant strain, had the wild-type sequence; further, the traP mutation in that strain, when outcrossed, also had no effect on agr expression

SaPIbov2 is a member of the SaPI family of staphylococcal pathogenicity islands and is very closely related to SaPIbov1. Typically, certain temperate phages can induce excision and replication of one or more of these islands and can package them into special small phage-like particles commensurate with their genome sizes (referred to as the excision-replication-packaging [ERP] cycle). We have studied the phage-SaPI interaction in some depth using SaPIbov2, with special reference to the role of its integrase. We demonstrate here that SaPIbov2 can be induced to replicate by different staphylococcal phages. After replication, SaPIbov2 is efficiently encapsidated and transferred to recipient organisms, including different non-Staphylococcus aureus staphylococci, where it integrates at a SaPI-specific attachment site, att(C), by means of a self-coded integrase (Int). Phages that cannot induce the SaPIbov2 ERP cycle can transfer the island by recA-dependent classical generalized transduction and can also transfer it by a novel mechanism that requires the expression of SaPIbov2 int in the recipient but not in the donor. It is suggested that this mechanism involves the encapsidation of standard transducing fragments containing the intact island followed by int-mediated excision, circularization, and integration in the recipient

Transfer of Staphylococcus aureus pathogenicity islands (SaPIs) is directly controlled by the cellular repressor LexA. We have found that transcription of the SaPIbov1 operon I is repressed by LexA and is therefore SOS-induced. Two copies of the LexA binding site consensus (Cheo box) are present in the 5' region of this operon, at the same location in all of 15 different SaPIs analysed. Both of these boxes bind LexA protein. Furthermore, replacement of the chromosomal lexA with a non-cleavable mutant LexA (G94E) greatly diminished expression of SaPIbov1 operon I and differentially reduced the production of SaPI transducing particles in comparison with the production of plaque-forming particles. In concordance with this finding, deletion of operon I blocked the formation of SaPI transducing particles but had no effect on replication of the island. Operon I contains a gene encoding a homologue of the phage terminase small subunit plus two other genes that direct the assembly of the small sized SaPIbov1 capsids. Interestingly, mutations affecting the latter two genes were not defective in SaPI transfer, but rather encapsidated the island in full-sized phage heads, which would have to contain a multimeric SaPI genome

The Staphylococcus aureus svrA gene was identified in a signature-tagged mutagenesis screen for Tn917 insertions attenuated for mouse virulence, and subsequently found to be defective in agr expression. Its attenuation of virulence was attributed to its failure to express the agr regulon. In addition to the Tn917 insertion in svrA, the original svrA mutant strain (P6C63) has an adventitious frame-shift in agrC, which results in truncation of the AgrC peptide. Separation of the svrA mutation from the agrC frame-shift revealed that svrA has no detectable affect on agr activation, as assessed by exoprotein profiles and the production of haemolytic toxins. These results indicate that svrA does not play a role in Staphylococcus aureus infections via an agr-mediated pathway