Purification, cloning and characterization of a novel peroxidase isozyme from sweetpotatoes (Ipomoea batatas).

An anionic peroxidase from sweetpotato tubers is purified and characterized. The isozyme ibPrx15 is purified to homogeneity by affinity chromatography using a concanavalin A column. The isoelectric point was determined to pI 4.9. MALDI-MS detected a singly charged molecule with a mass of 42029 Da. Absorption spectra of ibPrx15 compounds I, II and III were obtained after treatment with H(2)O(2) at room temperature. Comparative data of ibPrx15 on substrate specificity to tobacco anionic peroxidase (TOP) and horseradish peroxidase (HRP) reveal similar specific activity towards a series of conventional substrates except for iodide, which is a two-electron donor interacting directly with the compound I derivative in the catalytic cycle. ibPrx15 exhibits a high specific activity towards iodide about 10(3)-fold to that of tobacco peroxidase. The amino acid sequence of the main isozyme ibPrx15 was determined by Edman degradation and by sequencing the amplified cDNA fragments. ibPrx15 has 86% identity to another Ipomoea sequence ibPrx05 and 72% identity with a sequence from Populus trichocarpa (PtPrx72).

Comparative modeling of the latent form of a plant catechol oxidase using a molluskan hemocyanin structure.

The structure of the precursor form of catechol oxidase from sweet potatoes (Ipomoea batatas) has been modeled on the basis of the 3D structural data of mature catechol oxidase [Nat. Struct. Biol. 5 (1998) 1084] and of hemocyanin from giant octopus (Octopus dofleini) [J. Mol. Biol. 278 (1998) 855]. A C-terminal extension peptide is found in the cDNA sequence but not in the purified, mature form of catechol oxidase. Superimposition of the 3D structures of the native hemocyanin and catechol oxidase reveals a close relationship except for an additional C-terminal domain only found in the hemocyanin structure. As sequence alignment shows good homology this domain of the hemocyanin structure was used as a template to model the 3D structure of the C-terminal extension peptide of catechol oxidase. As hemocyanins show no or only weak catecholase activity due to this domain this indicates an inhibitory function of this extension peptide. Beside this possible shielding function for the precursor form, evidence for a function in copper-uptake also increases due to the location of three histidine residues in the model.

The crystal structure of catechol oxidase: new insight into the function of type-3 copper proteins.

The crystal structure of catechol oxidase reveals new insight into the functional properties of the type-3 copper proteins. This class of proteins includes the closely related and better-known tyrosinase as well as hemocyanin, an oxygen transport protein. All these proteins have a dinuclear copper center, have similar spectroscopic behaviors, and show close evolutionary and functional relationships. Comparison between the 3D structures of catechol oxidase and hemocyanins reveals the structural reasons for the divergence in function.