• Title of article

    Probing the Flexibility of the DsbA Oxidoreductase from Vibrio cholerae—a 15N - 1H Heteronuclear NMR Relaxation Analysis of Oxidized and Reduced Forms of DsbA

  • Author/Authors

    James Horne، نويسنده , , Edward J. d’Auvergne، نويسنده , , Murray Coles، نويسنده , , Tony Velkov، نويسنده , , Yanni Chin، نويسنده , , William N. Charman، نويسنده , , Richard Prankerd، نويسنده , , Kenwyn R. Gayler and Paul R. Gooley، نويسنده , , Martin J. Scanlon، نويسنده ,

  • Issue Information
    روزنامه با شماره پیاپی سال 2007
  • Pages
    14
  • From page
    703
  • To page
    716
  • Abstract
    We have determined the structure of the reduced form of the DsbA oxidoreductase from Vibrio cholerae. The reduced structure shows a high level of similarity to the crystal structure of the oxidized form and is typical of this class of enzyme containing a thioredoxin domain with an inserted α-helical domain. Proteolytic and thermal stability measurements show that the reduced form of DsbA is considerably more stable than the oxidized form. NMR relaxation data have been collected and analyzed using a model-free approach to probe the dynamics of the reduced and oxidized states of DsbA. Akaikeʹs information criteria have been applied both in the selection of the model-free models and the diffusion tensors that describe the global motions of each redox form. Analysis of the dynamics reveals that the oxidized protein shows increased disorder on the pico- to nanosecond and micro- to millisecond timescale. Many significant changes in dynamics are located either close to the active site or at the insertion points between the domains. In addition, analysis of the diffusion data shows there is a clear difference in the degree of interdomain movement between oxidized and reduced DsbA with the oxidized form being the more rigid. Principal components analysis has been employed to indicate possible concerted movements in the DsbA structure, which suggests that the modeled interdomain motions affect the catalytic cleft of the enzyme. Taken together, these data provide compelling evidence of a role for dynamics in the catalytic cycle of DsbA.
  • Keywords
    DsbA , Dynamics , bacterial oxidoreductase , model-free , interdomain motion
  • Journal title
    Journal of Molecular Biology
  • Serial Year
    2007
  • Journal title
    Journal of Molecular Biology
  • Record number

    1249617