Site-directed mutagenesis was employed to examine the role played by specific surface residues in the activity of cytochrome c peroxidase. The double charge, aspartic acid to lysine, point mutations were constructed at positions 37, 79, and 217 on the surface of cytochrome c peroxidase, sites purported to be within or proximal to the recognition site for cytochrome c in an electron-transfer productive complex formed by the two proteins. The resulting mutant peroxidases were examined for catalytic activity by steady-state measurements and binding affinity by two methods, fluorescence binding titration and cytochrome c affinity chromatography. The cloned peroxidases exhibit similar UV-visible spectra to the wild-type yeast protein, indicating that there are no major structural differences between the cloned peroxidases and the wild-type enzyme. The aspartic acid to lysine mutations at positions 79 and 217 exhibited similar turnover numbers and binding affinities to that seen for the "wild type-like" cloned peroxidase. The same change at position 37 caused more than a 10-fold decrease in both turnover of and binding affinity for cytochrome c. This empirical finding localizes a primary recognition region critical to the dynamic complex. Models from the literature proposing structures for the complex between peroxidase and cytochrome c are discussed in light of these findings.
Transient absorption techniques were used to measure the intracomplex electron transfer rates between four recombinant yeast cytochrome c peroxidases and iso-1 cytochrome c (cytc). The binding affinities and catalytic activities with cytc were previously examined [Corin et al. (1991) Biochemistry 30, 11585]. The four include a wild-type peroxidase (ECcP) and three others, each of which has one surface aspartic acid converted to lysine at position 37, 79, or 217. These sites have been suggested to be within or proximal to the recognition site for cytc. These mutants conduct electron transfer with cytc but differ with respect to the ionic strength profiles of their limiting rate constants. At pH and mu = 114 mM, ECcP and D217K show similar limiting rate constants for electron transfer with cytc, k(lim), of ca. 2000 s-1. In the same peroxidase concentration range, the D37K mutant exhibits a k(obs) of ca. 100 s-1. Instability of the compound I form of D79K prevented a complete study of the intracomplex kinetics of this mutant by this technique. At pH 6 and low ionic strength (8 mM), D37K exhibits a dramatic increase in k(obs) to ca. 800 s-1 while the other two recombinants show a marked decrease to values < 150 s-1. D37K displays much lower affinity for cytc than do the other peroxidases at higher ionic strengths [Hake et al. (1992) J. Am. Chem. Soc. 114, 5442], thus preventing adequate complexation necessary for efficient electron transfer. Variations in binding affinity do not explain the more subtle ionic strength kinetic profile observed for D217K.(ABSTRACT TRUNCATED AT 250 WORDS)
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