Comparison of structure and activities of peroxidases from Coprinus cinereus, Coprinus macrorhizus and Arthromyces ramosus

Disulfide bonds and glycosylation in fungal peroxidases

Four conserved disulfide bonds and N-linked and O-linked glycans of extracellular fungal peroxidases have been identified from studies of a lignin and a manganese peroxidase from Trametes versicolor, and from Coprinus cinereus peroxidase (CIP) and recombinant C. cinereus peroxidase (rCIP) expressed in Aspergillus oryzae. The eight cysteine residues are linked 1-3, 2-7, 4-5 and 6-8, and are located differently from the four conserved disulfide bridges present in the homologous plant peroxidases. CIP and rCIP were identical in their glycosylation pattern, although the extent of glycan chain heterogeneity depended on the fermentation batch. CIP and rCIP have one N-linked glycan composed only of GlcNAc and Man at residue Asn142, and two O-linked glycans near the C-terminus. The major glycoform consists of single Man residues at Thr331 and at Ser338. T. versicolor lignin isoperoxidase TvLP10 contains a single N-linked glycan composed of (GlcNAc)2Man5 bound to Asn103, whereas (GlcNAc)2Man3 was found in T. versicolor manganese isoperoxidase TvMP2 at the same position. In addition, mass spectrometry of the C-terminal peptide of TvMP2 indicated the presence of five Man residues in O-linked glycans. No phosphate was found in these fungal peroxidases.

Enzymatic removal of selected aromatic contaminants from wastewater by a fungal peroxidase from Coprinus macrorhizus in batch reactors

The use of enzymes such as horseradish peroxidase (HRP) for degrading or removing toxic organics from synthetic wastewater has been demonstrated previously. Potential alternatives to HRP are other peroxidases, various ligninases, haloperoxidases and laccases. Results of this study indicate that a fungal peroxidase from Coprinus macrorhizus (CMP) has the capability to catalyze the same reactions as HRP. Similarly, in batch reactors the trend and removal efficiency of aromatic compounds by CMP from synthetic wastewater depend on the nature of the compound.

NMR studies of recombinant Coprinus peroxidase and three site-directed mutants. Implications for peroxidase substrate binding

Proton nuclear magnetic resonance spectroscopy has been used to characterise and compare wild-type fungal and recombinant Coprinus cinereus peroxidase (CIP) and three mutants in which Gly156 and/or Asn157 was replaced by Phe. Analysis of one- and two-dimensional NMR spectra of recombinant CIP was undertaken for comparison with the fungal enzyme and in order to establish a meaningful basis for solution studies of CIP mutants. Proton resonance assignments of haem and haem-linked residues obtained for the cyanide-ligated form of recombinant CIP revealed a high degree of spectral similarity with those of lignin and manganese-dependent peroxidases and extend previously reported NMR data for fungal CIP. The three mutants examined by NMR spectroscopy comprised site-specific substitutions made to a region of the structure believed to form part of the peroxidase haem group access channel for substrate and ligand molecules. Proton resonances of the aromatic side-chains of Phe156 and Phe157 were found to have similar spectral characteristics to those of two phenylalanine residues known to be involved in the binding of aromatic donor molecules to the plant peroxidase, horseradish peroxidase isoenzyme C. The results are discussed in the context of complementary reactivity studies on the mutants in order to develop a more detailed understanding of aromatic donor molecule binding to fungal and plant peroxidases.

Oxidation-reduction properties of compounds I and II of Arthromyces ramosus peroxidase

At neutral pH, compound I of Arthromyces ramosus peroxidase (ARP) was stable and was reduced to ferric ARP without apparent formation of compound II upon titration with ascorbate or hydroquinone. In the titration experiments, compound II was seen as an intermediate only at alkaline pH. However, measuring a difference spectrum in the Soret region by a stopped-flow method, we found that compound II was formed during the catalytic oxidation of ascorbate even at neutral pH. Using an EPR spectrometer with a microflow system, we measured the steady-state concentration of benzosemiquinone formed in the ARP-catalyzed oxidation of hydroquinone. The results clearly showed that ARP catalyzes the oxidation of hydroquinone by a one-electron-transfer mechanism, as does horseradish peroxidase. These observations led to the conclusion that compound I is reduced to compound II through a one-electron reduction by ascorbate or hydroquinone. Therefore, we concluded that ARP compound II is unusually unstable and is rapidly reduced to ferric enzyme without accumulation in the titration experiment. The unusual instability of ARP compound II is explained in terms of the high reduction potential of compound II. The reduction potentials (E0') of compounds I and II were measured at several pH values from redox equilibria with potassium hexachloroiridate on the basis of E0' = 0.90 V for the IrCL6(2)-IrCl6(3)- couple. These values were determined to be 0.915 and 0.982 V at pH 7, respectively, and decreased with increasing pH. This pH dependence was markedly changed by the buffer concentration.(ABSTRACT TRUNCATED AT 250 WORDS)

Three-dimensional structure of a recombinant peroxidase from Coprinus cinereus at 2.6 A resolution

The structure of a recombinant peroxidase from the ink cap, Coprinus cinereus, CiP, is reported to 2.6 A resolution and refined to a R-value of 18.1%. The structure was solved by molecular replacement using the coordinates from a newly published ligninase structure. LiP. CiP crystallizes in space group P2(1)2(1)2(1) with two independent molecules in the asymmetric unit related by the vector 0.29b + 0.5c. The two CiP molecules are structurally identical; each contains two Ca2+ ions in positions equivalent to those found in the LiP structure. Two N-acetylglucosamines and one mannose residue were fitted into the density adjacent to two of the three predicted glycosylation sites. The refinement also included 40 and 41 water molecules, respectively, in the two CiP molecules. The structure of CiP displays a folding very similar to that of LiP. The active sites are almost identical in the LiP and CiP structures. CiP has a much larger opening to the active site than LiP.

Crystal structure of the fungal peroxidase from Arthromyces ramosus at 1.9 A resolution. Structural comparisons with the lignin and cytochrome c peroxidases

The crystal structure of the peroxidase (donor: H2O2 oxidoreductase, EC 1.11.1.7) from the hyphomycete Arthromyces ramosus (ARP) has been determined by the multiple isomorphous replacement method and refined by the simulated annealing method to a crystallographic R-factor of 17.4% for the 19,191 reflections with F > 2 sigma F between 7.0 and 1.9 A resolution. The model includes residues 9 to 344, the heme group, two N-acetylglucosamine residues, two calcium ions and 246 water molecules. The root-mean-square deviation of bond lengths from the ideal values is 0.02 A. The mean coordinate error is estimated as 0.2 A. The electron density of the glycine-rich region of the amino-terminal eight residues was invisible. ARP has ten major and two short alpha-helices and a few short beta-strands. The overall tertiary structure of ARP is similar to that of yeast cytochrome c peroxidase (CCP) and is particularly similar to that of the lignin peroxidase (LiP) from Phanerochaete chrysosporium. Relative to CCP, ARP and LiP each have an extension of approximately 40 residues at the carboxy terminus. All eight cysteine residues in ARP form disulfide bonds (C12:C24, C23:C293, C43:C129 and C257:C322). Two calcium sites are inaccessible to solvent. The four disulfide bonds and two calcium sites, which are lacking in CCP, are conserved in ARP and LiP. The bond from Asn304C to Ala305N in ARP is the site sensitive to proteases. An Asx turn present in the Asn303 to Ala305 segment appears to orient the side-chain of Asn304 to outward from the molecule, rendering it easily trappable by pockets of proteases. The proximal heme ligand is His184 in helix F (distance of N epsilon 2 ... Fe, 2.10 A), and one of several water molecules in the distal pocket of the heme bridges the iron atom and the N epsilon 2 of His56. The orientation of the imidazole ring of the distal histidine residue relative to the heme group in ARP differs significantly from that in LiP. The access channel to the distal side of the heme of ARP is markedly wider along the heme plane than that of LiP. Many of the amino acid residues that comprise the entrance of this channel differ for ARP and LiP. This may account for the differences in substrate specificity.

Amino acid sequence of Coprinus macrorhizus peroxidase and cDNA sequence encoding Coprinus cinereus peroxidase. A new family of fungal peroxidases

Sequence analysis and cDNA cloning of Coprinus peroxidase (CIP) were undertaken to expand the understanding of the relationships of structure, function and molecular genetics of the secretory heme peroxidases from fungi and plants. Amino acid sequencing of Coprinus macrorhizus peroxidase, and cDNA sequencing of Coprinus cinereus peroxidase showed that the mature proteins are identical in amino acid sequence, 343 residues in size and preceded by a 20-residue signal peptide. Their likely identity to peroxidase from Arthromyces ramosus is discussed. CIP has an 8-residue, glycine-rich N-terminal extension blocked with a pyroglutamate residue which is absent in other fungal peroxidases. The presence of pyroglutamate, formed by cyclization of glutamine, and the finding of a minor fraction of a variant form lacking the N-terminal residue, indicate that signal peptidase cleavage is followed by further enzymic processing. CIP is 40-45% identical in amino-acid sequence to 11 lignin peroxidases from four fungal species, and 42-43% identical to the two known Mn-peroxidases. Like these white-rot fungal peroxidases, CIP has an additional segment of approximately 40 residues at the C-terminus which is absent in plant peroxidases. Although CIP is much more similar to horseradish peroxidase (HRP C) in substrate specificity, specific activity and pH optimum than to white-rot fungal peroxidases, the sequences of CIP and HRP C showed only 18% identity. Hence, CIP qualifies as the first member of a new family of fungal peroxidases. The nine invariant residues present in all plant, fungal and bacterial heme peroxidases are also found in CIP. The present data support the hypothesis that only one chromosomal CIP gene exists. In contrast, a large number of secretory plant and fungal peroxidases are expressed from several peroxidase gene clusters. Analyses of three batches of CIP protein and of 49 CIP clones revealed the existence of only two highly similar alleles indicating less peroxidase polymorphism in C. cinereus strains than observed in plants and white-rot fungi.