Abstract
The nature of the free radical species observed in the peroxide complex of yeast cytochrome c peroxidase is described for protein variants containing amino acid substitutions at Met-172 and Trp-51. As was the case with Met-172 mutations (Goodin, D.B., Mauk, A.G., and Smith, M. (1986) Proc. Natl. Acad. Sci. U.S.A. 83, 1295-1299), Trp-51 can be substituted to give active enzyme. Phe-51-containing enzyme has a higher turnover rate than the original enzyme and exhibits an altered pH dependence. The properties of the isotropic and axial components (Hoffman, B.M., Roberts, J.E., Kang, C.H., and Margoliash, E. (1981) J. Biol. Chem. 256, 6556-6564; Hori, H., and Yonetani, T. (1985) J. Biol. Chem. 260, 349-355) of the EPR signal of the wild-type enzyme-peroxide complex, studied as a function of H2O2 stoichiometry, support proposals (Goodin et al. (1985) and Hori and Yonetani (1985), see above) that two distinct radical species are formed, and spin quantification shows that the isotropic radical is always formed in substoichiometric amounts. The peroxide complexes for proteins containing amino acid substitutions at either Met-172 or Trp-51 exhibit somewhat larger than normal levels of the isotropic radical signal. In addition, these mutants are unlike wild-type enzyme in that the axial EPR signal associated with the peroxide complex is seen only at 10 K and not at 90 K. Thus, neither amino acid can be considered to be the molecular species responsible for either radical signal, but both mutations appear to affect the physical properties of the axial signal representing the major radical species.
Highlights
The nature of the free radical species observed in the complex (ES)’ that has been oxidized by two charge equivaperoxide complex of yeast cytochrome c peroxidase is lents [5]
We present additional evidence for two distinct radical species in ES, assess the relative contribution made by the isotropic signal, and addressed: Dept. of Biochemistry, 2146 Health Sciences Mall, University of British Columbia, Vancouver, British Columbia V6T 1W5, The abbreviations used are: ES, cytochrome cperoxidase-peroxide complex; WT CCP, cytochrome c peroxidase containing no altera
Isotropic and Axial Signals RepresentDistinct SpeciesEPR spectra collected at 90 K are presented in Fig. 1showing the effects of varying amounts of H202on the signals of cytochrome c peroxidase
Summary
Construction and Expression of Mutant Cytochromec PeroxidaseThe site-directed mutagenesis methods of Zoller and Smith[15]were used as previously described [1] for the construction of cytochrome c peroxidase mutants in the vector pEMBLCCPl with the following exceptions. Protein Expression and Purification-Using methods described earlier (l),mutants of the CCP gene (the cytochrome c peroxidase gene) contained on the 1.7-kilobase Hind111 fragment of pEMBLCCP1 were subcloned into theyeast vector YEpl3CCP which was used to transform yeast strains DG5-4 (a, ku, his, CCP;:HZS3) or DG5-10 (a, leu, his, ura, CCP;:HIS3,PEP4::URA3). These yeast strains were constructed by crossing ZA515 (a, barl, ku, PEP4::URA3) with a strain W303-1AX (a, u r d , his, CCP::HZS3) which was in turn derived from W303-1A A2H used previously [1]. Spin quantification was accomplished by numerical double integration of digitized spectra using a KzNO(SO& solution standardized optically [24]
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