Staphylococcus aureus Prophage-Encoded Protein Causes Abortive Infection and Provides Population Immunity against Kayviruses.
Lucie KuntováIvana MašlaňováRadka ObořilováHana ŠimečkováAdéla FinstrlováPavol BardyMarta ŠiborováLiudmyla TroianovskaTibor BotkaPetr GintarOndrej ŠedoZdeněk FarkaJiří DoškařRoman PantucekPublished in: mBio (2023)
Both temperate and obligately lytic phages have crucial roles in the biology of staphylococci. While superinfection exclusion among closely related temperate phages is a well-characterized phenomenon, the interactions between temperate and lytic phages in staphylococci are not understood. Here, we present a resistance mechanism toward lytic phages of the genus Kayvirus , mediated by the membrane-anchored protein designated Pdp Sau encoded by Staphylococcus aureus prophages, mostly of the Sa2 integrase type. The prophage accessory gene pdp Sau is strongly linked to the lytic genes for holin and ami2-type amidase and typically replaces genes for the toxin Panton-Valentine leukocidin (PVL). The predicted Pdp Sau protein structure shows the presence of a membrane-binding α-helix in its N-terminal part and a cytoplasmic positively charged C terminus. We demonstrated that the mechanism of action of Pdp Sau does not prevent the infecting kayvirus from adsorbing onto the host cell and delivering its genome into the cell, but phage DNA replication is halted. Changes in the cell membrane polarity and permeability were observed from 10 min after the infection, which led to prophage-activated cell death. Furthermore, we describe a mechanism of overcoming this resistance in a host-range Kayvirus mutant, which was selected on an S. aureus strain harboring prophage 53 encoding Pdp Sau , and in which a chimeric gene product emerged via adaptive laboratory evolution. This first case of staphylococcal interfamily phage-phage competition is analogous to some other abortive infection defense systems and to systems based on membrane-destructive proteins. IMPORTANCE Prophages play an important role in virulence, pathogenesis, and host preference, as well as in horizontal gene transfer in staphylococci. In contrast, broad-host-range lytic staphylococcal kayviruses lyse most S. aureus strains, and scientists worldwide have come to believe that the use of such phages will be successful for treating and preventing bacterial diseases. The effectiveness of phage therapy is complicated by bacterial resistance, whose mechanisms related to therapeutic staphylococcal phages are not understood in detail. In this work, we describe a resistance mechanism targeting kayviruses that is encoded by a prophage. We conclude that the defense mechanism belongs to a broader group of abortive infections, which is characterized by suicidal behavior of infected cells that are unable to produce phage progeny, thus ensuring the survival of the host population. Since the majority of staphylococcal strains are lysogenic, our findings are relevant for the advancement of phage therapy.
Keyphrases
- staphylococcus aureus
- pseudomonas aeruginosa
- genome wide
- methicillin resistant staphylococcus aureus
- biofilm formation
- genome wide identification
- escherichia coli
- cell therapy
- cell death
- copy number
- single cell
- binding protein
- systematic review
- randomized controlled trial
- dna methylation
- antimicrobial resistance
- depressive symptoms
- protein protein
- cell cycle arrest
- amino acid
- genome wide analysis
- transcription factor
- computed tomography
- endothelial cells
- percutaneous coronary intervention
- mesenchymal stem cells
- stem cells
- small molecule
- heart failure
- signaling pathway
- coronary artery disease
- drug induced
- bone marrow