Unliganded and cyano derivatives of cytochrome ba3 from Thermus thermophilus have been examined by UV-vis, EPR, and resonance Raman spectroscopies. Species of cytochrome ba3 investigated include its resting, as-isolated, fully oxidized state, the fully reduced, unliganded enzyme, the one-electron-reduced cyano complex, the three-electron-reduced cyano complex, and the fully reduced cyano complex. Results are compared to those obtained from similar adducts of bovine cytochrome aa3, in particular, the fully reduced cyano complex. Our objective was to identify structural similarities and differences at the ligand-binding binuclear site of the two enzymes. We observed that the inner core skeletal vibrations of cytochrome a3 are the same for similar adducts of the bacterial ba3 and mammalian aa3, indicating similar spin and iron-porphyrin coordination properties resulting in comparable porphyrin core geometries. On the other hand, many of the vibrational frequencies associated with the formyl and vinyl peripheral substituents, and the outer pyrrole carbon atoms differ between the bovine and bacterial enzymes. Use of 57Fe labeled ba3 allows identification of two separate vFe-N(His) frequencies displayed by the fully reduced, unliganded cytochrome. These frequencies, occurring at 193 and 209 cm-1, are ascribed to distinct protein conformers, which are best evidenced by the Fe-N(His) vibrations. This result is again in contrast to the bovine enzyme which has been shown by others to display a single Fe-N(His) stretching frequency at 214 cm-1. The low-frequency Fea3(2+)-CN- vibrations of the three-electron and fully reduced cyano complexes of cytochrome ba3 are identified by using 15N and 13C isotopomers of CN-. These spectral signatures are identical to those reported earlier for the one-electron-reduced cyanide adduct (cytochrome a3 reduced), showing that the Fea3(2+)-CN- vibrational frequencies are independent of the redox states of the other three metal centers. Similarly, the CuB2+ EPR signatures appear similar in both the one-electron- and three-electron-reduced cyanide adducts. On the other hand, the electronic absorption spectra of ferrous alpha 3-CN- show systematic red-shifts of the alpha band as each of the other metal centers is reduced, and other, more subtle, differences in the electronic absorptions of the three-electron-reduced and four-electron-reduced cyanide adducts are revealed in the difference spectra. The relevance of these findings toward explaining the different cyanide binding and redox chemistry described herein and toward establishing the extent of structural analogy between the oxygen binding sites of the two proteins is discussed.
Myeloperoxidase compound II has been characterized by using optical absorption and resonance Raman spectroscopies. Compared to compounds II in other peroxidases, the electronic and vibrational properties of this intermediate are strongly perturbed due to the unusual active-site iron chromophore that occurs in myeloperoxidase. Despite this difference in prosthetic group, however, other properties of myeloperoxidase compound II are similar to those observed for this intermediate in the more common peroxidases (horseradish peroxidase in particular). Two forms of the myeloperoxidase intermediate species, each with distinct absorption spectra, are recognized as a function of pH. We present evidence consistent with interconversion of these two forms via a heme-linked ionization of a distal amino acid residue with a pKa congruent to 9. From resonance Raman studies of isotopically labeled species at pH 10.7, we identify an iron-oxygen stretching frequency at 782 cm-1, indicating the presence of an oxoferryl (O = FeIV) group in myeloperoxidase compound II. We further conclude that the oxo ligand is not hydrogen bonded above the pKa but possibly exhibits oxygen exchange with the medium at pH values below the pKa due to hydrogen bonding of the oxo ligand to the distal protein group.
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