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Iron‐containing superoxide dismutases (FeSOD) are generally dimers of identical 21‐kDa monomers, each of which contains a single active site. Each active site binds one Fe ion with roughly trigonal bipyramidal geometry, employing two His and an Asp − residue as equatorial ligands, and one more His and a coordinated solvent as axial ligands. In the course of the catalytic cycle, the Fe alternates between the +3 and +2 states, and the coordinated solvent is believed to alternate between OH − and H 2 O, in concert. Activity is inhibited by coordination of F − , N 3 − , or OH − to the oxidized state. Decreased activity at high pH reflects the latter in addition to ionization of the conserved Tyr34 in the reduced state of the enzyme at pH 8.5. Despite strong structural homologies with the manganese containing superoxide dismutases (MnSODs), many FeSODs are inactive when reconstituted with Mn, and in the case of Escherichia coli SODs this appears to reflect, at least in part, very large differences in the reduction potentials produced by the two different SOD proteins, either Fe or Mn. Subtle changes in strengths of key active site H‐bonds could differently tune the p K s of the coordinated solvent molecule, whose participation in proton‐coupled electron transfer would in turn cause these differences to contribute to different reduction potentials, in the two proteins. Thus, SOD suggests that H‐bond mediated tuning of the protonation state and p K s of redox‐coupled coordinated solvents may serve as a means of tuning the E m in other cases as well.
Iron‐containing superoxide dismutases (FeSOD) are generally dimers of identical 21‐kDa monomers, each of which contains a single active site. Each active site binds one Fe ion with roughly trigonal bipyramidal geometry, employing two His and an Asp − residue as equatorial ligands, and one more His and a coordinated solvent as axial ligands. In the course of the catalytic cycle, the Fe alternates between the +3 and +2 states, and the coordinated solvent is believed to alternate between OH − and H 2 O, in concert. Activity is inhibited by coordination of F − , N 3 − , or OH − to the oxidized state. Decreased activity at high pH reflects the latter in addition to ionization of the conserved Tyr34 in the reduced state of the enzyme at pH 8.5. Despite strong structural homologies with the manganese containing superoxide dismutases (MnSODs), many FeSODs are inactive when reconstituted with Mn, and in the case of Escherichia coli SODs this appears to reflect, at least in part, very large differences in the reduction potentials produced by the two different SOD proteins, either Fe or Mn. Subtle changes in strengths of key active site H‐bonds could differently tune the p K s of the coordinated solvent molecule, whose participation in proton‐coupled electron transfer would in turn cause these differences to contribute to different reduction potentials, in the two proteins. Thus, SOD suggests that H‐bond mediated tuning of the protonation state and p K s of redox‐coupled coordinated solvents may serve as a means of tuning the E m in other cases as well.
Iron‐containing superoxide dismutases (FeSOD) are generally dimers of identical 21‐kDa monomers, each of which contains a single active site. Each active site binds one Fe ion with roughly trigonal bipyramidal geometry, employing two His and an Asp − residue as equatorial ligands, and one more His and a coordinated solvent as axial ligands. In the course of the catalytic cycle, the Fe alternates between the +3 and +2 states, and the coordinated solvent is believed to alternate between OH − and H 2 O, in concert. Activity is inhibited by coordination of F − , N 3 − , or OH − to the oxidized state. Decreased activity at high pH reflects the latter in addition to ionization of the conserved Tyr34 in the reduced state of the enzyme at pH 8.5. Despite strong structural homologies with the manganese containing superoxide dismutases (MnSODs), many FeSODs are inactive when reconstituted with Mn, and in the case of Escherichia coli SODs this appears to reflect, at least in part, very large differences in the reduction potentials produced by the two different SOD proteins, either Fe or Mn. Subtle changes in strengths of key active site H‐bonds could differently tune the p K s of the coordinated solvent molecule, whose participation in proton‐coupled electron transfer would in turn cause these differences to contribute to different reduction potentials, in the two proteins. Thus, SOD suggests that H‐bond mediated tuning of the protonation state and p K s of redox‐coupled coordinated solvents may serve as a means of tuning the E m in other cases as well.
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