Abstract
The phosphoenolpyruvate-dependent phosphotransferase system (PTS) modulates the preferential use of sugars in bacteria. The first proteins in the cascade are common to all organisms (EI and HPr). The active site of HPr involves a histidine (His15) located immediately before the beginning of the first α-helix. The regulator of sigma D (Rsd) protein also binds to HPr. The region of HPr comprising residues Gly9-Ala30 (HPr9–30), involving the first α-helix (Ala16-Thr27) and the preceding active site loop, binds to both the N-terminal region of EI and intact Rsd. HPr9–30 is mainly disordered. We attempted to improve the affinity of HPr9–30 to both proteins by mutating its sequence to increase its helicity. We designed peptides that led to a marginally larger population in solution of the helical structure of HPr9–30. Molecular simulations also suggested a modest increment in the helical population of mutants, when compared to the wild-type. The mutants, however, were bound with a less favorable affinity than the wild-type to both the N-terminal of EI (EIN) or Rsd, as tested by isothermal titration calorimetry and fluorescence. Furthermore, mutants showed lower antibacterial properties against Staphylococcus aureus than the wild-type peptide. Therefore, we concluded that in HPr, a compromise between binding to its partners and residual structure at the active site must exist to carry out its function.
Highlights
As a preliminary step towards the aim to assess the ability of peptides for binding to Rsdec and EINsc, we firstly biophysically characterized them by using far-UV CD and NMR
The dissociation constant of the interaction between regulator of sigma D (Rsd) and HPr in E. coli reported as 8.87 nM [22], as measured by surface plasmon resonance (SPR)
By using fluorescence and biolayer interferometry (BLI) for the intact HPrsc [24], suggested that the binding occurred in the low micromolar range (0.2 to 1.5 μM, depending on the technique), in agreement with previous measurements [22,23]
Summary
The PTS controls the preferential use of carbon sources in bacteria [3,4] It is involved in the transport and release of carbohydrates (PTS sugars) through the cell external membrane; the PTS intervenes in the movement of bacteria towards carbon sources (chemotaxis) in nitrogen metabolism and in regulation of other metabolic pathways in both Gram-negative and Gram-positive bacteria [2,5,6]. The regulation of such pathways occurs through phosphorylation of its target proteins, and by interaction between the phosphorylated proteins. The 64-kDa protomer of EI protein, in all the species described so far, exhibits a dimer–monomer equilibrium
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