Human sulfite oxidase (hSO), an essential molybdoheme enzyme, catalyzes the oxidation of toxic sulfite to sulfate. The proposed catalytic cycle includes two, one-electron intramolecular electron transfers (IET) between the molybdenum (Mo) and the heme domains. Rapid IET rates are ascribed to conformational changes that bring the two domains into close proximity to one another. Previous studies of hSO have focused on the roles of conserved residues near the Mo active site and on the tether that links the two domains. Here four aromatic surface residues on the heme domain (phenylalanine 57 (F57), phenylalanine 79 (F79), tyrosine 83 (Y83), and histidine 90 (H90)) have been mutated, and their involvement in IET rates, the heme midpoint potential, and the catalytic activity of hSO have been investigated using laser flash photolysis, spectroelectrochemistry, and steady-state kinetics, respectively. The results indicate that the size and hydrophobicity of F57 play an important role in modulating the heme potential and that F57 also affects the IET rates. The data also suggest that important interactions of H90 with a heme propionate group destabilize the Fe(III) state of the heme. The positive charge on H90 at pH ≤ 7.0 may decrease the electrostatic interaction between the Mo and heme domains, thereby decreasing the IET rates of wt hSO at low pH. Lastly, mutations of F79 and Y83, which are located on the surface of the heme domain, but not in direct contact with the heme or the propionate groups, have little effect on either IET or the heme potential.

Sulfite oxidase (SO) is a molybdoheme enzyme that is important in sulfur catabolism, and mutations in the active site region are known to cause SO deficiency disorder in humans. This investigation probes the effects that mutating aromatic residues (Y273, W338, and H337) in the molybdenum-containing domain of human SO have on both the intramolecular electron transfer (IET) rate between the molybdenum and iron centers using laser flash photolysis and on catalytic turnover via steady-state kinetic analysis. The W338 and H337 mutants show large decreases in their IET rate constants (kET) relative to the wild-type values, suggesting the importance of these residues for rapid IET. In contrast, these mutants are catalytically competent and exhibit higher kcat values than their corresponding kET, implying that these two processes involve different conformational states of the protein. Redox potential investigations using spectroelectrochemistry revealed that these aromatic residues close to the molybdenum center affect the potential of the presumably distant heme center in the resting state (as shown by the crystal structure of chicken SO), suggesting that the heme may be interacting with these residues during IET and/or catalytic turnover. These combined results suggest that in solution human SO may adopt different conformations for IET and for catalysis in the presence of the substrate. For IET the H337/W338 surface residues may serve as an alternative-docking site for the heme domain. The similarities between the mutant and wild-type EPR spectra indicate that the active site geometry around the Mo(V) center is not changed by the mutations studied here.

Human sulfite oxidase (hSO), an essential molybdoheme enzyme, catalyzes the oxidation of toxic sulfite to sulfate. The proposed catalytic cycle includes two, one-electron intramolecular electron transfers (IET) between the molybdenum (Mo) and the heme domains. Rapid IET rates are ascribed to conformational changes that bring the two domains into close proximity to one another. Previous studies of hSO have focused on the roles of conserved residues near the Mo active site and on the tether that links the two domains. Here four aromatic surface residues on the heme domain (phenylalanine 57 (F57), phenylalanine 79 (F79), tyrosine 83 (Y83), and histidine 90 (H90)) have been mutated, and their involvement in IET rates, the heme midpoint potential, and the catalytic activity of hSO have been investigated using laser flash photolysis, spectroelectrochemistry, and steady-state kinetics, respectively. The results indicate that the size and hydrophobicity of F57 play an important role in modulating the heme potential and that F57 also affects the IET rates. The data also suggest that important interactions of H90 with a heme propionate group destabilize the Fe(III) state of the heme. The positive charge on H90 at pH ≤ 7.0 may decrease the electrostatic interaction between the Mo and heme domains, thereby decreasing the IET rates of wt hSO at low pH. Lastly, mutations of F79 and Y83, which are located on the surface of the heme domain, but not in direct contact with the heme or the propionate groups, have little effect on either IET or the heme potential.