Imperfect coordination chemistry facilitates metal ion release in the Psa permease.Counago, R.M., Ween, M.P., Begg, S.L., Bajaj, M., Zuegg, J., O'Mara, M.L., Cooper, M.A., McEwan, A.G., Paton, J.C., Kobe, B., McDevitt, C.A.
(2014) Nat Chem Biol 10: 35-41
- PubMed: 24212134
- DOI: 10.1038/nchembio.1382
- Structures With Same Primary Citation
- PubMed Abstract:
- The Crystal Structure of Pneumococcal Surface Antigen Psaa Reveals a Metal-Binding Site and a Novel Structure for a Putative Abc-Type Binding Protein.
Lawrence, M.C., Pilling, P.A., Epa, V.C., Berry, A.M., Ogunniyi, A.D., Paton, J.C.
(1998) Structure 6: 1553
- A Molecular Mechanism for Bacterial Susceptibility to Zinc.
McDevitt, C.A., Ogunniyi, A.D., Valkov, E., Lawrence, M.C., Kobe, B., McEwan, A.G., Paton, J.C.
(2011) PLoS Pathog 7: 02357
The relative stability of divalent first-row transition metal ion complexes, as defined by the Irving-Williams series, poses a fundamental chemical challenge for selectivity in bacterial metal ion acquisition. Here we show that although the substrate ...
The relative stability of divalent first-row transition metal ion complexes, as defined by the Irving-Williams series, poses a fundamental chemical challenge for selectivity in bacterial metal ion acquisition. Here we show that although the substrate-binding protein of Streptococcus pneumoniae, PsaA, is finely attuned to bind its physiological substrate manganese, it can also bind a broad range of other divalent transition metal cations. By combining high-resolution structural data, metal-binding assays and mutational analyses, we show that the inability of open-state PsaA to satisfy the preferred coordination chemistry of manganese enables the protein to undergo the conformational changes required for cargo release to the Psa permease. This is specific for manganese ions, whereas zinc ions remain bound to PsaA. Collectively, these findings suggest a new ligand binding and release mechanism for PsaA and related substrate-binding proteins that facilitate specificity for divalent cations during competition from zinc ions, which are more abundant in biological systems.
Research Centre for Infectious Diseases, School of Molecular and Biomedical Science, University of Adelaide, Adelaide, South Australia, Australia.