Azurin from Pseudomonas aeruginosa and two mutants where the methionine ligand has been mutated have been studied in order to directly investigate the functional and structural significance of this ligand in the blue copper proteins. Reduction potentials, X-ray absorption fine structure (XAFS), electron paramagnetic resonance (EPR), and optical spectra are obtained in an attempt to provide a direct correlation between the spectrochemical properties and the immediate structure of this redox center.
The expression of rusticyanin in Escherichia coli and a number of mutants for Ser86 is reported. Mutations of Ser86 to Asn, Asp, Gln, and Leu were undertaken as this is an Asn residue in other structurally characterized cupredoxins, and it has been suggested that this may be partly responsible for the high redox potential (680 mV) and extreme acid stability of rusticyanin. N-Terminal sequence analysis, together with other biochemical and spectrochemical characterization, shows that the recombinant wild-type protein is indistinguishable from native rusticyanin. All four mutants retain the rhombic nature of the EPR spectra and a significant absorption maximum at approximately 450 nm, thus confirming that the overall geometry of the Cu ligands is essentially maintained. The oxidized form of all four mutants is less acid stable than the wild-type protein, although the detailed mechanism of lability varies. Ser86Leu readily loses copper as the pH is reduced from 4.0, but the protein does not denature. A significant proportion (approximately 30%) of Ser86Gln is denatured at lower pH values, whereas Ser86Asn and Ser86Asp are stable as the reduced (CuI) protein. The redox potential also varies by approximately 110 mV (590-702 mV) upon these single point mutations, thus providing direct experimental support to the idea that this residue is at least in part responsible for the acid stability and the highest redox potential of rusticyanin in the cupredoxin family.
The existence of a three-coordinate cuprous ion in bovine CuZn SOD is demonstrated and is a key feature of catalytic degradation of superoxide substrate by SOD involving alternate Cu(I) and Cu(II) states of the enzyme. Only subtle changes in the zinc K-edge XAFS take place upon reduction. Thus the reaction mechanism which involves breakage of the bridging histidine is unambiguously supported by the XAFS data.
Methane-oxidizing bacteria are ubiquitous in the environment and are globally important in oxidizing the potent greenhouse gas methane. It is also well recognized that they have wide potential for bioremediation of organic and chlorinated organic pollutants, thanks to the wide substrate ranges of the methane monooxygenase enzymes that they produce. Here we have demonstrated that the well characterized model methanotroph Methylococcus capsulatus (Bath) is able to bioremediate chromium(VI) pollution over a wide range of concentrations (1.4-1000 mg L(-1) of Cr(6+)), thus extending the bioremediation potential of this major group of microorganisms to include an important heavy-metal pollutant. The chromium(VI) reduction reaction was dependent on the availability of reducing equivalents from the growth substrate methane and was partially inhibited by the metabolic poison sodium azide. X-ray spectroscopy showed that the cell-associated chromium was predominantly in the +3 oxidation state and associated with cell- or medium-derived moieties that were most likely phosphate groups. The genome sequence of Mc. capsulatus (Bath) suggests at least five candidate genes for the chromium(VI) reductase activity in this organism.
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