posted on 2011-10-25, 00:00authored byJuliette Trepreau, Eve de Rosny, Carole Duboc, Géraldine Sarret, Isabelle Petit-Hartlein, Antoine P. Maillard, Anne Imberty, Olivier Proux, Jacques Covès
CnrX, the dimeric metal sensor of the three-protein transmembrane
signal transduction complex CnrYXH of Cupriavidus metallidurans CH34, contains one metal-binding site per monomer. Both Ni and Co
elicit a biological response and bind the protein in a 3N2O1S coordination
sphere with a nearly identical octahedral geometry as shown by the
X-ray structure of CnrXs, the soluble domain of CnrX. However, in
solution CnrXs is titrated by 4 Co-equiv and exhibits an unexpected
intense band at 384 nm that was detected neither by single-crystal
spectroscopy nor under anaerobiosis. The data from a combination of
spectroscopic techniques (spectrophotometry, electron paramagnetic
resonance, X-ray absorption spectroscopy) showed that two sites correspond
to those identified by crystallography. The two extra binding sites
accommodate Co(II) in an octahedral geometry in the absence of oxygen
and are occupied in air by a mixture of low-spin Co(II) as well as
EPR-silent Co(III). These extra sites, located at the N-terminus of
the protein, are believed to participate to the formation of peroxo-bridged
dimers. Accordingly, we hypothesize that the intense band at 384 nm
relies on the formation of a binuclear μ-peroxo Co(III) complex.
These metal binding sites are not physiologically relevant since they
are not detected in full-length NccX, the closest homologue of CnrX.
X-ray absorption spectroscopy demonstrates that NccX stabilizes Co(II)
in two-binding sites similar to those characterized by crystallography
in its soluble counterpart. Nevertheless, the original spectroscopic
properties of the extra Co-binding sites are of interest because they
are susceptible to be detected in other Co-bound proteins.