Homologous expression of recombinant lignin peroxidase in Phanerochaete chrysosporium

Preparing the pure lignin peroxidase and exploring the effects of chemicals on the activity

Heterogous expression of lignin peroxidase (LiP) from Phanerochaete chrysosporium was performed in by E. coli prokaryotic expression system, and pure LiP was prepared by washing, refolding, and purification. The enzyme activity was measured by the resveratrol oxidation method. The effects of different chemicals on LiP activity were explored by adding different kinds of metal ions, acids/phenols, and surfactants. The optimal pH and temperature are 4.2 and 40 °C. The single-factor screening experiment showed that adding 1 mM Mn2+, 0.1 mM DL-lactic acid, and 2% PEG-4000 had the best promotion effect on the enzyme activity of recombinant LiP, which was 160.61%, 188.46%, and 247.83%, respectively. Further, the synergistic addition of Mn2+ and PEG-4000 achieved the best enzyme activity promotion effect of 277.51%. In addition, the addition of DL-lactic acid alone could promote LiP activity. However, the co-addition of lactic acid with Mn2+ and PEG-4000 contributed only 247.87%, which indicated that the addition of DL-lactic acid had an inhibitory effect when applied synergistically. For the first time, it was found that PEG-4000 increased LiP enzyme activity obviously and had a synergistic effect with Mn2+, serving as a reference for LiP in studies and applications pertaining to lignin breakdown.

Synergistic codon optimization and bioreactor cultivation toward enhanced secretion of fungal lignin peroxidase in Pichia pastoris: Enzymatic valorization of technical (industrial) lignins

Lignin peroxidase (LiP) is a well-recognized enzyme for its ability to oxidize lignins, but its commercial availability is limited, which hinders the biotechnological application of LiP-based bioprocesses in lignocellulose biorefineries. This study evaluated a combination strategy to improve the expression of LiP to promote its practical use. The strategy included optimization of the lipH8 gene of Phanerochaete chrysosporium according to the codon usage of Pichia pastoris, followed by fed-batch fermentation using a 14 L bioreactor (10 L working volume). The combination strategy achieved a maximum volumetric LiPH8 activity of 4480 U L^-1, protein concentration of 417 mg L^-1 and a specific activity of 10.7 U mg^-1, which was higher than previous reports. Biochemical characterization showed that the recombinant LiPH8 (rLiPH8) was optimum at pH 3.0, 25 ℃ and 0.4 mM H₂O₂. Using the optimized conditions, rLiPH8 was used to treat isolated technical lignins namely soda-anthraquinone (SAQ) lignin and steam explosion (S-E) lignin. High-performance gel permeation chromatography (HP-GPC) analysis showed that the molecular weight (Mw) of SAQ and S-E lignins were increased by 1.43-and 1.14-fold, respectively, after the enzymatic treatment. Thermogravimetric analysis (TGA) also showed that the thermal stability of the lignins was improved, indicating that the enzyme treatment of lignins with rLiPH8 resulted in lignin re-polymerization. As the first report on rLiPH8 production using P. pastoris, this study has shed light on the possible route for the enhancement of rLiPH8 production and its potential application for upgrading technical lignins.

Progress and obstacles in the production and application of recombinant lignin-degrading peroxidases

Lignin is 1 of the 3 major components of lignocellulose. Its polymeric structure includes aromatic subunits that can be converted into high-value-added products, but this potential cannot yet been fully exploited because lignin is highly recalcitrant to degradation. Different approaches for the depolymerization of lignin have been tested, including pyrolysis, chemical oxidation, and hydrolysis under supercritical conditions. An additional strategy is the use of lignin-degrading enzymes, which imitates the natural degradation process. A versatile set of enzymes for lignin degradation has been identified, and research has focused on the production of recombinant enzymes in sufficient amounts to characterize their structure and reaction mechanisms. Enzymes have been analyzed individually and in combinations using artificial substrates, lignin model compounds, lignin and lignocellulose. Here we consider progress in the production of recombinant lignin-degrading peroxidases, the advantages and disadvantages of different expression hosts, and obstacles that must be overcome before such enzymes can be characterized and used for the industrial processing of lignin.

Recombinant expression of four oxidoreductases in Phanerochaete chrysosporium improves degradation of phenolic and non-phenolic substrates

Phanerochaete chrysosporium belongs to a group of lignin-degrading fungi that secretes various oxidoreductive enzymes, including lignin peroxidase (LiP) and manganese peroxidase (MnP). Previously, we demonstrated that the heterologous expression of a versatile peroxidase (VP) in P. chrysosporium recombinant strains is possible. However, the production of laccases (Lac) in this fungus has not been completely demonstrated and remains controversial. In order to investigate if the co-expression of Lac and VP in P. chrysosporium would improve the degradation of phenolic and non-phenolic substrates, we tested the constitutive co-expression of the lacIIIb gene from Trametes versicolor and the vpl2 gene from Pleurotus eryngii, and also the endogenous genes mnp1 and lipH8 by shock wave mediated transformation. The co-overexpression of peroxidases and laccases was improved up to five-fold as compared with wild type species. Transformant strains showed a broad spectrum in phenolic/non-phenolic biotransformation and a high percentage in synthetic dye decolorization in comparison with the parental strain. Our results show that the four enzymes can be constitutively expressed in a single transformant of P. chrysosporium in minimal medium. These data offer new possibilities for an easy and efficient co-expression of laccases and peroxidases in suitable basidiomycete species.

Ancestral amino acid substitution improves the thermal stability of recombinant lignin-peroxidase from white-rot fungi, Phanerochaete chrysosporium strain UAMH 3641

Stabilizing enzymes from mesophiles of industrial interest is one of the greatest challenges of protein engineering. The ancestral mutation method, which introduces inferred ancestral residues into a target enzyme, has previously been developed and used to improve the thermostability of thermophilic enzymes. In this report, we studied the ancestral mutation method to improve the chemical and thermal stabilities of Phanerochaete chrysosporium lignin peroxidase (LiP), a mesophilic fungal enzyme. A fungal ancestral LiP sequence was inferred using a phylogenetic tree comprising Basidiomycota and Ascomycota fungal peroxidase sequences. Eleven mutant enzymes containing ancestral residues were designed, heterologously expressed in Escherichia coli and purified. Several of these ancestral mutants showed higher thermal stabilities and increased specific activities and/or kcat/KM than those of wild-type LiP.

Oral vaccination of mice with Tremella fuciformis yeast-like conidium cells expressing HBsAg

Tremella fuciformis yeast-like conidium (YLC) cells were transformed by co-cultivation with Agrobacterium cells harboring the hepatitis B surface antigen (HBsAg) gene construct under the control of the CaMV35S promoter. Integration of HBsAg DNA into the YLC genome was confirmed by PCR and dot-blot hybridization. Immunoblotting verified expression of the recombinant protein. Oral administration of YLC cells expressing HBsAg in mice significantly increased anti-HBsAg antibody titer levels using a double prime-boost strategy that combined parenteral and oral HBsAg boosters.

High-yield production of manganese peroxidase, lignin peroxidase, and versatile peroxidase in Phanerochaete chrysosporium

The white-rot fungus Phanerochaete chrysosporium secretes extracellular oxidative enzymes during secondary metabolism, but lacks versatile peroxidase, an enzyme important in ligninolysis and diverse biotechnology processes. In this study, we report the genetic modification of a P. chrysosporium strain capable of co-expressing two endogenous genes constitutively, manganese peroxidase (mnp1) and lignin peroxidase (lipH8), and the codon-optimized vpl2 gene from Pleurotus eryngii. For this purpose, we employed a highly efficient transformation method based on the use of shock waves developed by our group. The expression of recombinant genes was verified by PCR, Southern blot, quantitative real-time PCR (qRT-PCR), and assays of enzymatic activity. The production yield of ligninolytic enzymes was up to four times higher in comparison to previously published reports. These results may represent significant progress toward the stable production of ligninolytic enzymes and the development of an effective fungal strain with promising biotechnological applications.

Cloning and heterologous expression of a novel ligninolytic peroxidase gene from poroid brown-rot fungus Antrodia cinnamomea

A novel ligninolytic peroxidase gene (ACLnP) was cloned and characterized from a poroid brown-rot fungus, Antrodia cinnamomea. The genomic DNA of the fungus harboured two copies of ACLnP, with a length of 2111 bp, interlaced with 12 introns, while the full-length cDNA was 1183 bp, with a 66 bp signal peptide and an ORF of 990 bp. The three-dimensional molecular structure model was comparable to that of the versatile peroxidase of Pleurotus eryngii. ACLnP was cloned into vector pQE31, successfully expressed in Escherichia coli strain M15 under the control of the T5 promoter and produced a non-glycosylated protein of about 38 kDa, pI 5.42. The native and recombinant ACLnP was capable of oxidizing the redox mediator veratryl alcohol, and also decolorized bromophenol blue and 2,6-dimethoxyphenol dyes, implicating a functional extracellular peroxidase activity. The significance of discovering a functional ACLnP gene in A. cinnamomea in terms of wood degradation and colonization capacity in its unique niche is discussed.

The white-rot fungus Phanerochaete chrysosporium: conditions for the production of lignin-degrading enzymes

Investigating optimal conditions for lignin-degrading peroxidases production by Phanerochaete chrysosporium (P. chrysosporium) has been a topic for numerous researches. The capability of P. chrysosporium for producing lignin peroxidases (LiPs) and manganese peroxidases (MnPs) makes it a model organism of lignin-degrading enzymes production. Focusing on compiling and identifying the factors that affect LiP and MnP production by P. chrysosporium, this critical review summarized the main findings of about 200 related research articles. The major difficulty in using this organism for enzyme production is the instability of its productivity. This is largely due to the poor understanding of the regulatory mechanisms of P. chrysosporium responding to different nutrient sources in the culture medium, such as metal elements, detergents, lignin materials, etc. In addition to presenting the major conclusions and gaps of the current knowledge on lignin-degrading peroxidases production by P. chrysosporium, this review has also suggested further work, such as correlating the overexpression of the intra and extracellular proteins to the nutrients and other culture conditions to discover the regulatory cascade in the lignin-degrading peroxidases production process, which may contribute to the creation of improved P. chrysosporium strains leading to stable enzyme production.

Transformation by complementation of a uracil auxotroph of the hyper lignin-degrading basidiomycete Phanerochaete sordida YK-624

Phanerochaete sordida YK-624 is a hyper lignin-degrading basidiomycete possessing greater ligninolytic selectivity than either P. chrysosporium or Trametes versicolor. To construct a gene transformation system for P. sordida YK-624, uracil auxotrophic mutants were generated using a combination of ultraviolet (UV) radiation and 5-fluoroorotate resistance as a selection scheme. An uracil auxotrophic strain (UV-64) was transformed into a uracil prototroph using the marker plasmid pPsURA5 containing the orotate phosphoribosyltransferase gene from P. sordida YK-624. This system generated approximately 50 stable transformants using 2 x 10(7) protoplasts. Southern blot analysis demonstrated that the transformed pPsURA5 was ectopically integrated into the chromosomal DNA of all transformants. The enhanced green fluorescent protein (EGFP) gene was also introduced into UV-64. The transformed EGFP was expressed in the co-transformants driven by P. sordida glyceraldehyde-3-phosphate dehydrogenase gene promoter and terminator regions.

Extracellular oxidative systems of the lignin-degrading Basidiomycete Phanerochaete chrysosporium

The US Department of Energy has assembled a high quality draft genome of Phanerochaete chrysosporium, a white rot Basidiomycete capable of completely degrading all major components of plant cell walls including cellulose, hemicellulose and lignin. Hundreds of sequences are predicted to encode extracellular enzymes including an impressive number of oxidative enzymes potentially involved in lignocellulose degradation. Herein, we summarize the number, organization, and expression of genes encoding peroxidases, copper radical oxidases, FAD-dependent oxidases, and multicopper oxidases. Possibly relevant to extracellular oxidative systems are genes involved in posttranslational processes and a large number of hypothetical proteins.

Exclusive overproduction of recombinant versatile peroxidase MnP2 by genetically modified white rot fungus, Pleurotus ostreatus

By combining a homologous recombinant gene expression system and optimization of the culture conditions, hyper overproduction of Pleurtous ostreatus MnP2 was achieved. Genetically modified P. ostreatus strains with the recombinant mnp2 sequence under the control of sdi1 expression signals, were subjected to agitated culture using media supplemented with wheat bran or its hot-water extract. The best result, whereby 7300 U/l of MnP was produced by a recombinant strain TM2-18, indicated that more than 30-fold overproduction of the recombinant MnP2 compared to the previous result was achieved. On the other hand, no MnP activity was detected for the wild-type strain under the same conditions. Accumulation of the recombinant, but not endogenous, mnp2 transcripts was demonstrated in reverse-transcription PCR experiments. These results indicated that the recombinant MnP2 was exclusively expressed by the recombinant strain. Purified recombinant MnP2 showed almost identical properties to native MnP2 in electrophoresis, spectroscopic and kinetic analyses, including determination of K(m) and V(max) values for Mn(II), H(2)O(2) and veratryl alcohol. Moreover, the recombinant MnP2 directly oxidized a high-molecularweight substrate RNase A in the absence of redox mediators, as does native MnP2. The homologous overproduction system will provide a plat form for exclusive production of mutant or variant peroxidases with a desired property in basidiomycete.

Highly efficient production of laccase by the basidiomycete Pycnoporus cinnabarinus

An efficient transformation and expression system was developed for the industrially relevant basidiomycete Pycnoporus cinnabarinus. This was used to transform a laccase-deficient monokaryotic strain with the homologous lac1 laccase gene placed under the regulation of its own promoter or that of the SC3 hydrophobin gene or the glyceraldehyde-3-phosphate dehydrogenase (GPD) gene of Schizophyllum commune. SC3-driven expression resulted in a maximal laccase activity of 107 nkat ml(-1) in liquid shaken cultures. This value was about 1.4 and 1.6 times higher in the cases of the GPD and lac1 promoters, respectively. lac1-driven expression strongly increased when 25 g of ethanol liter(-1) was added to the medium. Accordingly, laccase activity increased to 1,223 nkat ml(-1). These findings agree with the fact that ethanol induces laccase gene expression in some fungi. Remarkably, lac1 mRNA accumulation and laccase activity also strongly increased in the presence of 25 g of ethanol liter(-1) when lac1 was expressed behind the SC3 or GPD promoter. In the latter case, a maximal laccase activity of 1,393 nkat ml(-1) (i.e., 360 mg liter(-1)) was obtained. Laccase production was further increased in transformants expressing lac1 behind its own promoter or that of GPD by growth in the presence of 40 g of ethanol liter(-1). In this case, maximal activities were 3,900 and 4,660 nkat ml(-1), respectively, corresponding to 1 and 1.2 g of laccase per liter and thus representing the highest laccase activities reported for recombinant fungal strains. These results suggest that P. cinnabarinus may be a host of choice for the production of other proteins as well.

Overproduction of recombinant laccase using a homologous expression system in Coriolus versicolor

One of the major extracellular enzymes of the white-rot fungus Coriolus versicolor is laccase, which is involved in the degradation of lignin. We constructed a homologous system for the expression of a gene for laccase III (cvl3) in C. versicolor, using a chimeric laccase gene driven by the promoter of a gene for glyceraldehyde-3-phosphate dehydrogenase (gpd) from this fungus. We transformed C. versicolor successfully by introducing both a gene for hygromycin B phosphotransferase (hph) and the chimeric laccase gene. In three independent experiments, we recovered 47 hygromycin-resistant transformants at a transformation frequency of 13 transformants microg(-1) of plasmid DNA. We confirmed the introduction of the chimeric laccase gene into the mycelia of transformants by a polymerase chain reaction in nine randomly selected transformants. Overproduction of extracellular laccase by the transformants was revealed by a colorimetric assay for laccase activity. We examined the transformant (T2) that had the highest laccase activity and found that its activity was significantly higher than that of the wild type, particularly in the presence of copper (II). Our transformation system should contribute to the efficient production of the extracellular proteins of C. versicolor for the accelerated degradation of lignin and aromatic pollutants.

Homologous expression of Phanerochaete chrysosporium manganese peroxidase, using bialaphos resistance as a dominant selectable marker

Manganese peroxidase (MnP) is a major extracellular component of the lignin-degrading system of the white-rot fungus, Phanerochaete chrysosporium. Homologous expression of recombinant MnP isozyme 1 (rMnP1) in P. chrysosporium was achieved using a novel transformation system for this fungus, which utilizes the Streptomyces hygroscopicus bialaphos-resistant gene, bar, as the selectable marker. The transformation frequency for this system is approximately 100 bialaphos-resistant transformants per microgram of plasmid DNA. Transformed strains all contain plasmid DNA, ectopically integrated into the fungal genome. Using this transformation system, the promoter region of the P. chrysosporium translation elongation factor gene was used to drive expression of mnp1, encoding MnP1, in primary metabolic cultures of P. chrysosporium, where endogenous MnP was not expressed. Approximately 2-3 mg of active recombinant MnP1 per liter of extracellular medium was produced in agitated cultures of transformants.

Biophysical and structural analysis of a novel heme B iron ligation in the flavocytochrome cellobiose dehydrogenase

The fungal extracellular flavocytochrome cellobiose dehydrogenase (CDH) participates in lignocellulose degradation. The enzyme has a cytochrome domain connected to a flavin-binding domain by a peptide linker. The cytochrome domain contains a 6-coordinate low spin b-type heme with unusual iron ligands and coordination geometry. Wild type CDH is only the second example of a b-type heme with Met-His ligation, and it is the first example of a Met-His ligation of heme b where the ligands are arranged in a nearly perpendicular orientation. To investigate the ligation further, Met65 was replaced with a histidine to create a bis-histidyl ligated iron typical of b-type cytochromes. The variant is expressed as a stable 90-kDa protein that retains the flavin domain catalytic reactivity. However, the ability of the mutant to reduce external one-electron acceptors such as cytochrome c is impaired. Electrochemical measurements demonstrate a decrease in the redox midpoint potential of the heme by 210 mV. In contrast to the wild type enzyme, the ferric state of the protoheme displays a mixed low spin/high spin state at room temperature and low spin character at 90 K, as determined by resonance Raman spectroscopy. The wild type cytochrome does not bind CO, but the ferrous state of the variant forms a CO complex, although the association rate is very low. The crystal structure of the M65H cytochrome domain has been determined at 1.9 A resolution. The variant structure confirms a bis-histidyl ligation but reveals unusual features. As for the wild type enzyme, the ligands have a nearly perpendicular arrangement. Furthermore, the iron is bound by imidazole N delta 1 and N epsilon 2 nitrogen atoms, rather than the typical N epsilon 2/N epsilon 2 coordination encountered in bis-histidyl ligated heme proteins. To our knowledge, this is the first example of a bis-histidyl N delta 1/N epsilon 2-coordinated protoporphyrin IX iron.

Fungal peroxidases: molecular aspects and applications

Peroxidases are oxidoreductases that utilize hydrogen peroxide to catalyze oxidative reactions. A large number of peroxidases have been identified in fungal species and are being characterized at the molecular level. In this manuscript we review the current knowledge on the molecular aspects of this type of enzymes. We present an overview of the research efforts undertaken in deciphering the structural basis of the catalytic properties of fungal peroxidases and discuss molecular genetics and protein homology aspects of this enzyme class. Finally, we summarize the potential biotechnological applications of these enzymes and evaluate recent advances on their expression in heterologous systems for production purposes.

Site-directed mutagenesis of the heme axial ligands in the hemoflavoenzyme cellobiose dehydrogenase

Cellobiose dehydrogenase (CDH) from Phanerochaete chrysosporium is an extracellular 90-kDa hemoflavoenzyme, organized into an N-terminal heme domain and a C-terminal flavin domain. The amino acid residues Met65 and His114 or His163 were suggested to be heme iron ligands. Mutations of these residues were made and mutant proteins were characterized. H114A mutant cultures produce a stable hemoflavoenzyme with spectral and kinetic characteristics similar to those of wild-type CDH. The M65A and H163A transformants secrete a 90-kDa hemoflavoenzyme, which oxidizes cellobiose in the presence of 2,6-dichlorophenol-indophenol (DCPIP), but is unable to reduce cytochrome c. The heme domains of the M65A and H163A CDH variants are, however, unstable and susceptible to degradation, both yielding a 70-kDa cellobiose-oxidizing flavoenzyme. The spectral and kinetic characteristics of these truncated variants suggest that they contain only their respective flavin domains. The yield of the 90-kDa proteins was low and the proteins could not be purified to homogeneity; however, absorption spectra indicate that the 90-kDa proteins do contain the heme domain. Like the truncated flavoenzymes, the 90-kDa variants reduce DCPIP but are unable to transfer electrons to cytochrome c, in contrast to wild-type CDH. These findings suggest that H163 and M65 are the axial heme ligands and that both ligands are required for the reactivity and structural integrity of the heme domain.

The green fluorescent protein gene functions as a reporter of gene expression in Phanerochaete chrysosporium

The enhanced green fluorescent protein (GFP) gene (egfp) was used as a reporter of gene expression driven by the glyceraldehyde-p-dehydrogenase (gpd) gene promoter and the manganese peroxidase isozyme 1 (mnp1) gene promoter in Phanerochaete chrysosporium. Four different constructs were prepared. pUGGM3' and pUGiGM3' contain the P. chrysosporium gpd promoter fused upstream of the egfp coding region, and pUMGM3' and pUMiGM3' contain the P. chrysosporium mnp1 promoter fused upstream of the egfp gene. In all constructs, the egfp gene was followed by the mnp1 gene 3' untranslated region. In pUGGM3' and pUMGM3', the promoters were fused directly with egfp, whereas in pUGiGM3' and pUMiGM3', following the promoters, the first exon (6 bp), the first intron (55 bp), and part of the second exon (9 bp) of the gpd gene were inserted at the 5' end of the egfp gene. All constructs were ligated into a plasmid containing the ura1 gene of Schizophyllum commune as a selectable marker and were used to transform a Ural1 auxotrophic strain of P. chrysosporium to prototrophy. Crude cell extracts were examined for GFP fluorescence, and where appropriate, the extracellular fluid was examined for MnP activity. The transformants containing a construct with an intron 5' of the egfp gene (pUGiGM3' and pUMiGM3') exhibited maximal fluorescence under the appropriate conditions. The transformants containing constructs with no introns exhibited minimal or no fluorescence. Northern (RNA) blots indicated that the insertion of a 5' intron resulted in more egfp RNA than was found in transformants carrying an intronless egfp. These results suggest that the presence of a 5' intron affects the expression of the egfp gene in P. chrysosporium. The expression of GFP in the transformants carrying pUMiGM3' paralled the expression of endogenous mnp with respect to nitrogen and Mn levels, suggesting that this construct will be useful in studying cis-acting elements in the mnp1 gene promoter.

Heterologous Expression of a Thermostable Manganese Peroxidase from Dichomitus squalens in Phanerochaete chrysosporium

Dichomitus squalens belongs to a group of white-rot fungi which express manganese peroxidase (MnP) and laccase but do not express lignin peroxidase (LiP). To facilitate structure/function studies of MnP from D. squalens, we heterologously expressed the enzyme in the well-studied basidiomycete, Phanerochaete chrysosporium. The glyceraldehyde-3-phosphate-dehydrogenase (gpd) promoter of P. chrysosporium was fused to the coding region of the mnp2 gene of D. squalens, 5 bp upstream of the translation start site, and placed in a vector containing the ural gene as a selectable marker. Purified recombinant protein (rDsMnP) was similar in kinetic and spectral characteristics to both the wild-type MnPs from D. squalens and P. chrysosporium (PcMnP). The N-terminal amino acid sequence of the rDsMnP was determined and was identical to the predicted sequence. Cleavage of the propeptide followed a conserved amino acid motif (A-A-P-S/T) in both rDsMnP and PcMnP. However, the protein from D. squalens was considerably more thermostable than its P. chrysosporium homolog with half-lives 15- to 40-fold longer at 55 degrees C. As previously demonstrated for PcMnP, addition of exogenous MnII and CdII conferred additional thermal stability to rDsMnP. However, unlike PcMnP, ZnII also confers some additional thermal stability to rDsMnP at 55 degrees C. Some differences in the metal-specific effects on thermal stability of rDsMnP at 65 degrees C were noted.

MnII is not a productive substrate for wild-type or recombinant lignin peroxidase isozyme H2

The glyceraldehyde-3-phosphate dehydrogenase (gpd) gene promoter was used to drive the homologous expression of the lignin peroxidase (LiP) isozyme H2 gene in primary metabolic cultures of Phanerochaete chrysosporium. The molecular mass, pI, and optical absorption spectra of purified recombinant LiPH2 (rLiPH2) were essentially identical to those of wild-type LiPH2 (wtLiPH2). wtLiPH2 was prepared by growing cells in the absence of MnII, conditions under which P. chrysosporium manganese peroxidase (MnP) is not expressed, ensuring that wtLiPH2 was not contaminated with MnP. The kinetics of veratryl alcohol (VA) oxidation were essentially identical for rLiPH2 and wtLiPH2. The rLiPH2, wtLiPH2, and wild-type LiP isozyme H8 (wt-LiPH8) enzymes were used to reexamine previous claims that LiPH2 can oxidize Mn" at a rate sufficient to promote catalytic turnover of the enzyme. Our results demonstrate that rLiPH2, wtLiPH2, and LiPH8 do not turn over under steady-state conditions, when MnII is the sole reducing substrate. Furthermore, transient-state kinetic analyses show that the reduction rate of the catalytic intermediate, LiP compound I, by VA was at least 2 x 10(3)-fold higher than the rate of reduction in the presence of MnII. No reduction of LiP compound II was observed in the presence of MnII. In contrast to previous claims, these data strongly suggest that MnII is not a productive substrate for LiPH2 or LiPH8.

Studies on the production of fungal peroxidases in Aspergillus niger

To get insight into the limiting factors existing for the efficient production of fungal peroxidase in filamentous fungi, the expression of the Phanerochaete chrysosporium lignin peroxidase H8 (lipA) and manganese peroxidase (MnP) H4 (mnp1) genes in Aspergillus niger has been studied. For this purpose, a protease-deficient A. niger strain and different expression cassettes have been used. Northern blotting experiments indicated high steady-state mRNA levels for the recombinant genes. Manganese peroxidase was secreted into the culture medium as an active protein. The recombinant protein showed specific activity and a spectrum profile similar to those of the native enzyme, was correctly processed at its N terminus, and had a slightly lower mobility on sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Recombinant MnP production could be increased up to 100 mg/liter upon hemoglobin supplementation of the culture medium. Lignin peroxidase was also secreted into the extracellular medium, although the protein was not active, presumably due to incorrect processing of the secreted enzyme. Expression of the lipA and mnp1 genes fused to the A. niger glucoamylase gene did not result in improved production yields.

Homologous expression of recombinant cellobiose dehydrogenase in Phanerochaete chrysosporium

Cellobiose dehydrogenase (CDH) is a novel extracellular hemoflavoenzyme from Phanerochaete chrysosporium and is produced only in cultures supplemented with cellulose. In this report, CDH from P. chrysosporium has been homologously expressed in cultures supplemented with glucose as the sole carbon source when no endogenous CDH is expressed. This was achieved by placing the cdh-1 gene under the control of the D-glyceraldehyde-3-phosphate dehydrogenase (gpd) promoter (1.1 kb) fused upstream of the ATG start codon of cdh-1. The gpd promoter-chd-1 construct was inserted into the multiple cloning site of the expression vector pOGI18, which contained the Schizophyllum commune ade5 as a selectable marker. The P. chrysosporium ade1 auxotrophic strain OGC107-1 was transformed with the pAGC1 construct, and the prototrophic transformants were assayed for CDH activity. Approximately 50% of the Ade(+) transformants exhibited CDH activity in the extracellular medium of stationary cultures. At least one of the transformants produced high levels (500-600 U/liter) of recombinant CDH (rCDH). Purification by ammonium sulfate precipitation, Sephacryl S-200 chromatography, and FPLC using a Mono-Q 5/5 column yielded homogeneous rCDH. Physical, spectral, and kinetic characteristics of purified homologously expressed rCDH were similar to those of wild-type CDH. This expression system will enable site-directed mutagenesis studies to be carried out on CDH.

Efficient heterologous expression in Aspergillus oryzae of a unique dye-decolorizing peroxidase, DyP, of Geotrichum candidum Dec 1

Efficient expression of the dye-decolorizing peroxidase, DyP, from Geotrichum candidum Dec 1 in Aspergillus oryzae M-2-3 was achieved by fusing mature cDNA encoding dyp with the A. oryzae alpha-amylase promoter (amyB). The activity yield of the purified recombinant DyP (rDyP) was 42-fold compared with that of the purified native DyP from Dec 1. No exogenous heme was necessary for the expression of rDyP in A. oryzae. From the N-terminal amino acid sequence analyses of native DyP and rDyP, the absence of a histidine residue in both DyPs, which was considered to be important for heme binding of DyP, was confirmed. These results suggest that rDyP without a typical heme-binding region produced by A. oryzae exhibits a function similar to that of native DyP.

Effects of cadmium on manganese peroxidase competitive inhibition of MnII oxidation and thermal stabilization of the enzyme

Inhibition of manganese peroxidase by cadmium was studied under steady-state and transient-state kinetic conditions. CdII is a reversible competitive inhibitor of MnII in the steady state with Ki approximately 10 microM. CdII also inhibits enzyme-generated MnIII-chelate-mediated oxidation of 2,6-dimethoxyphenol with Ki approximately 4 microM. CdII does not inhibit direct oxidation of phenols such as 2,6-dimethoxyphenol or guaiacol (2-methoxyphenol) in the absence of MnII. CdII alters the heme Soret on binding manganese peroxidase and exhibits a Kd approximately 8 microM, similar to Mn (Kd approximately 10 microM). Under transient-state conditions, CdII inhibits reduction of compound I and compound II by MnII at pH 4.5. However, CdII does not inhibit formation of compound I nor does it inhibit reduction of the enzyme intermediates by phenols in the absence of MnII. Kinetic analysis suggests that CdII binds at the MnII-binding site, preventing oxidation of MnII, but does not impair oxidation of substrates, such as phenols, which do not bind at the MnII-binding site. Finally, at pH 4.5 and 55 degrees C, MnII and CdII both protect manganese peroxidase from thermal denaturation more efficiently than CaII, extending the half-life of the enzyme by more than twofold. Furthermore, the combination of half MnII and half CdII nearly quadruples the enzyme half-life over either metal alone or either metal in combination with CaII.