Molecular basis of halorespiration control by CprK, a CRP-FNR type transcriptional regulator

C. Levy, K. Pike, D. Heyes, M.G. Joyce, K. Gabor, H. Smidt, J. van der Oost, D. Leys

Research output: Contribution to journalArticleAcademicpeer-review

42 Citations (Scopus)

Abstract

Certain bacteria are able to conserve energy via the reductive dehalogenation of halo-organic compounds in a respiration-type metabolism. The transcriptional regulator CprK from Desulfitobacterium spp. induces expression of halorespiratory genes upon binding of o-chlorophenol ligands and is reversibly inactivated by oxygen through disulphide bond formation. We report crystal structures of D. hafniense CprK in the ligand-free (both oxidation states), ligand-bound (reduced) and DNA-bound states, making it the first member of the widespread CRP-FNR superfamily for which a complete structural description of both redox-dependent and allosteric molecular rearrangements is available. In conjunction with kinetic and thermodynamic ligand binding studies, we provide a model for the allosteric mechanisms underpinning transcriptional control. Amino acids that play a key role in this mechanism are not conserved in functionally distinct CRP-FNR members. This suggests that, despite significant structural homology, distinct allosteric mechanisms are used, enabling this protein family to control a very wide range of processes
Original languageEnglish
Pages (from-to)151-167
JournalMolecular Microbiology
Volume70
Issue number1
DOIs
Publication statusPublished - 2008

Keywords

  • genome sequence
  • dna-binding
  • desulfitobacterium-hafniense
  • dehalococcoides-ethenogenes
  • protein
  • activation
  • dehalorespiration
  • superfamily
  • cooa
  • camp

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