Abstract
Pathogenicity islands of Staphylococcus aureus are under the strong control of helper phages, where regulation is communicated at the gene expression level via a family of specific repressor proteins. The repressor proteins are crucial to phage-host interactions and, based on their protein characteristics, may also be exploited as versatile molecular tools. The Stl repressor from this protein family has been recently investigated and although the binding site of Stl on DNA was recently discovered, there is a lack of knowledge on the specific protein segments involved in this interaction. Here, we develop a generally applicable system to reveal the mechanism of the interaction between Stl and its cognate DNA within the cellular environment. Our unbiased approach combines random mutagenesis with high-throughput analysis based on the lac operon to create a well-characterized gene expression system. Our results clearly indicate that, in addition to a previously implicated helix-turn-helix segment, other protein moieties also play decisive roles in the DNA binding capability of Stl. Structural model-based investigations provided a detailed understanding of Stl:DNA complex formation. The robustness and reliability of our novel test system were confirmed by several mutated Stl constructs, as well as by demonstrating the interaction between Stl and dUTPase from the Staphylococcal ϕ11 phage. Our system may be applied to high-throughput studies of protein:DNA and protein:protein interactions.
Highlights
Staphylococcus aureus (S. aureus) pathogenicity islands (SaPIs) operate in the fine-tuned control mechanism between phages and the host bacterial cell
Switchable systems in molecular biology are associated with well-defined advantages and far-reaching applications in medical and industrial biotechnologies
These systems are based on cognate molecules that turn on/off metabolic pathways, signal transduction processes, and gene expression regulation
Summary
Staphylococcus aureus (S. aureus) pathogenicity islands (SaPIs) operate in the fine-tuned control mechanism between phages and the host bacterial cell. SaPIs play an important role in spreading virulence factors [1]. These mobile genetic elements usually encode toxins, antibiotic resistance genes, and antigens responsible for the pathogenicity of the given strain. Pathogenicity islands are considered to be similar to phages since these mobile elements can move via horizontal transfer from one strain to the other, hijacking the phage capsid. The pathogenicity island is under the repression of a transcription regulatory factor encoded by the island.
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