Site-directed mutagenesis of tobacco anionic peroxidase: Effect of additional aromatic amino acids on stability and activity

Tobacco anionic peroxidase (TOP) is known to effectively catalyze luminol oxidation without enhancers, in contrast to horseradish peroxidase (HRP). To pursue structure-activity relationship studies for TOP, two amino acids have been chosen for mutation, namely Thr151, close to the heme plane, and Ph...

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Bibliographic Details
Published in:Biochimie 2015-08, Vol.115, p.71-77
Main Authors: Poloznikov, A.A., Zakharova, G.S., Chubar, T.A., Hushpulian, D.M., Tishkov, V.I., Gazaryan, I.G.
Format: Article
Language:English
Subjects:
Amino Acids, Aromatic
Benzothiazoles - metabolism
Biocatalysis
Catalytic activity
Chemiluminescence
Enzyme Stability
Hydrogen Peroxide - metabolism
Kinetics
Models, Molecular
Mutagenesis, Site-Directed
Oxidation-Reduction
Peroxidases - chemistry
Peroxidases - genetics
Peroxidases - metabolism
Protein Conformation
Protein Refolding
Recombinant tobacco peroxidase
Refolding
Site-directed mutagenesis
Substrate Specificity
Sulfonic Acids - metabolism
Temperature
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Summary:Tobacco anionic peroxidase (TOP) is known to effectively catalyze luminol oxidation without enhancers, in contrast to horseradish peroxidase (HRP). To pursue structure-activity relationship studies for TOP, two amino acids have been chosen for mutation, namely Thr151, close to the heme plane, and Phe140 at the entrance to the active site pocket. Three mutant forms TOP F140Y, T151W and F140Y/T151W have been expressed in Escherichia coli, and reactivated to yield active enzymes. Single-point mutations introducing additional aromatic amino acid residues at the surface of TOP exhibit a significant effect on the enzyme catalytic activity and stability as judged by the results of steady-state and transient kinetics studies. TOP T151W is up to 4-fold more active towards a number of aromatic substrates including luminol, whereas TOP F140Y is 2-fold more stable against thermal inactivation and 8-fold more stable in the reaction course. These steady-state observations have been rationalized with the help of transient kinetic studies on the enzyme reaction with hydrogen peroxide in a single turnover regime. The stopped-flow data reveal (a) an increased stability of F140Y Compound I towards hydrogen peroxide, and thus, a higher operational stability as compared to the wild-type enzyme, and (b) a lesser leakage of oxidative equivalents from TOP T151W Compound I resulting in the increased catalytic activity. The results obtained show that TOP unique properties can be further improved for practical applications by site-directed mutagenesis. •Three mutants of tobacco peroxidase have been expressed in Escherichia coli and reactivated.•TOP T151W is up to 4-fold more active towards aromatic substrates including luminol.•TOP F140Y is 2-fold more stable against thermal inactivation.•TOP F140Y is 8-fold more stable in the luminol oxidation reaction.•TOP F140Y Compound I has increased stability towards hydrogen peroxide.
ISSN:0300-9084
1638-6183
DOI:10.1016/j.biochi.2015.04.021