The methyl-accepting chemotaxis protein, DcrH, from the anaerobic sulfate-reducing bacterium, Desulfovibrio vulgaris (Hildenborough), has a hemerythrin-like domain, DcrH-Hr, at its C terminus. DcrH-Hr was previously shown to contain a diiron site that binds O2, suggesting an O2-sensing function. X-ray crystal structures of diferric (met-), azido-diferric (azidomet-), and diferrous (deoxy-) DcrH-Hr reveal a "substrate tunnel" distinct from that in invertebrate hemerythrins. This tunnel is proposed to facilitate the rapid autoxidation of oxy-DcrH-Hr and suggests that sensing is triggered by O2 binding and subsequent oxidation of the diferrous active site. The N-terminal loop of DcrH-Hr is highly ordered in both met- and azidomet-DcrH-Hr but is disordered in deoxy-DcrH-Hr. These redox-dependent conformational differences presumably transduce the sensory signal of DcrH-Hr to the neighboring methylation domain in the full-length receptor. Given the putative cytoplasmic localization of its Hr-like O2-sensing domain, DcrH is proposed to serve a role in negative aerotaxis (anaerotaxis).
High-resolution crystal structures of Desulfovibrio vulgaris nigerythrin (DvNgr), a member of the rubrerythrin (Rbr) family, demonstrate an approximately 2-A movement of one iron (Fe1) of the diiron site from a carboxylate to a histidine ligand upon conversion of the mixed-valent ([Fe2(II),Fe1(III)]) to diferrous states, even at cryogenic temperatures. This Glu<-->His ligand "toggling" of one iron, which also occurs in DvRbr, thus, appears to be a characteristic feature of Rbr-type diiron sites. Unique features of DvNgr revealed by these structures include redox-induced flipping of a peptide carbonyl that reversibly forms a hydrogen bond to the histidine ligand to Fe1 of the diiron site, an intra-subunit proximal orientation of the rubredoxin-(Rub)-like and diiron domains, and an electron transfer pathway consisting of six covalent and two hydrogen bonds connecting the Rub-like iron with Fe2 of the diiron site. This pathway can account for DvNgr's relatively rapid peroxidase turnover. The characteristic combination of iron sites together with the redox-dependent iron toggling between protein ligands can account for the selectivity of Rbrs for hydrogen peroxide over dioxygen.
The gsdA gene of the extreme thermophilic bacterium Aquifex aeolicus, encoding glucose-6-phosphate dehydrogenase (G6PDH), was cloned into a high-expression vector and overexpressed as a fusion protein in Escherichia coli. Here we report the characterization of this recombinant thermostable G6PDH. G6PDH was purified to homogeneity by heat precipitation followed by immobilized metal affinity chromatography on a nickel-chelate column. The data obtained indicate that the enzyme is a homodimer with a subunit molecular weight of 55 kDa. G6PDH followed Michaelis-Menten kinetics with a K(M) of 63 micro M for glucose-6-phosphate at 70 degrees C with NADP as the cofactor. The enzyme exhibited dual coenzyme specificity, although it showed a preference in terms of k(cat)/ K(M) of 20.4-fold for NADP over NAD at 40 degrees C and 5.7-fold at 70 degrees C. The enzyme showed optimum catalytic activity at 90 degrees C. Modeling of the dimer interface suggested the presence of cysteine residues that may form disulfide bonds between the two subunits, thereby preserving the oligomeric integrity of the enzyme. Interestingly, addition of dithiothreitol or mercaptoethanol did not affect the activity of the enzyme. With a half-life of 24 h at 90 degrees C and 12 h at 100 degrees C, this is the most thermostable G6PDH described.
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