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Chimeric mutants of staphylococcal hemolysin, which act as both one-component and two-component hemolysin, created by grafting the stem domain.

Nouran GhanemNatsuki KanagamiTakashi MatsuiKein TakedaJun KanekoYasuyuki ShiraishiChristian A ChoeTomomi Uchikubo-KamoMikako ShirouzuTsubasa HashimotoTomohisa OgawaTomoaki MatsuuraPo-Ssu HuangTakeshi YokoyamaYoshikazu Tanaka
Published in: The FEBS journal (2022)
Staphylococcus aureus expresses several hemolytic pore-forming toxins (PFTs), which are all commonly composed of three domains: cap, rim and stem. PFTs are expressed as soluble monomers and assemble to form a transmembrane β-barrel pore in the erythrocyte cell membrane. The stem domain undergoes dramatic conformational changes to form a pore. Staphylococcal PFTs are classified into two groups: one-component α-hemolysin (α-HL) and two-component γ-hemolysin (γ-HL). The α-HL forms a homo-heptamer, whereas γ-HL is an octamer composed of F-component (LukF) and S-component (Hlg2). Because PFTs are used as materials for nanopore-based sensors, knowledge of the functional properties of PFTs is used to develop new, engineered PFTs. However, it remains challenging to design PFTs with a β-barrel pore because their formation as transmembrane protein assemblies requires large conformational changes. In the present study, aiming to investigate the design principles of the β-barrel formed as a consequence of the conformational change, chimeric mutants composed of the cap/rim domains of α-HL and the stem of LukF or Hlg2 were prepared. Biochemical characterization and electron microscopy showed that one of them assembles as a heptameric one-component PFT, whereas another participates as both a heptameric one- and heptameric/octameric two-component PFT. All chimeric mutants intrinsically assemble into SDS-resistant oligomers. Based on these observations, the role of the stem domain of these PFTs is discussed. These findings provide clues for the engineering of staphylococcal PFT β-barrels for use in further promising applications.
Keyphrases
  • staphylococcus aureus
  • single molecule
  • cell therapy
  • molecular dynamics
  • methicillin resistant staphylococcus aureus
  • molecular dynamics simulations
  • stem cells
  • cystic fibrosis
  • bone marrow