A novel and efficient oxidative functionalization of lignin by layer-by-layer immobilised Horseradish peroxidase

Horseradish peroxidase (HRP) was chemically immobilised onto alumina particles and coated by polyelectrolytes layers, using the layer-by-layer technique. The reactivity of the immobilised enzyme was studied in the oxidative functionalisation of softwood milled wood and residual kraft lignins and found higher than the free enzyme. In order to investigate the chemical modifications in the lignin structure, quantitative (31)P NMR was used. The immobilised HRP showed a higher reactivity with respect to the native enzyme yielding extensive depolymerisation of lignin.     

Purification and characterisation of lignin peroxidase from Pycnoporus sanguineus MTCC-137

Extracellular secretion of lignin peroxidase from Pycnoporus sanguineus MTCC-137 in the liquid culture growth medium amended with lignin containing natural sources has been shown. The maximum secretion of lignin peroxidase has been found in the presence of saw dust. The enzyme has been purified to homogeneity from the culture filtrate of the fungus using ultrafiltration and anion exchange chromatography on DEAE-cellulose. The purified lignin peroxidase gave a single protein band in sodium dodecylsulphate polyacrylamide gel electrophoresis corresponding to the molecular mass 40 kDa. The K(m)(, kcat) and k(cat)/K(m) values of the enzyme using veratryl alcohol and H2O2 as the substrate were 61 microM, 2.13 s(-1), 3.5 x 10(4) M(-1) s(-1) and 71 microM, 2.13 s(-1), 3.0 x 10(4) M(-1) s(-1) respectively at the optimum pH of 2.5. The temperature optimum of the enzyme was 25 degrees C.     

Increasing glucose determination range by flow injection analysis (FIA) using glucose oxidase immobilised on polyaniline

A Flow Injection Analysis (FIA) for glucose using glucose oxidase (E.C.1.1.3.4) was developed. The enzyme was immobilised on polyaniline chemically synthetized on internal surface of silicon tube (2.0 mm of diameter and length from 1 to 5 meters), using glutaraldehyde as a bifunctional agent. The system was able to measure glucose at levels from 5 to 500mM with a response time of 2min using 250l of sample. The system has been operated satisfactorily for one month with more than 300 assays with loss of 60% of activity.     

The oxidation of veratryl alcohol, dimeric lignin models and lignin by lignin peroxidase: The redox cycle revisited

Abstract: The mechanism of oxidation of veratryl alcohol and β-0–4 dimeric lignin models is reviewed. Veratryl alcohol radicals are intermediates in both oxidation pathways. The possible role of the veratryl alcohol radical cation as a mediator is discussed. The lignin peroxidase (LIP) redox cycle is analyzed in terms of the Marcus theory of electron transfer. Reduction of both LiP-Compound I (LiP-I) and LiP-Compound II (LiP-II) by veratryl alcohol occurs in the endergonic region of the driving force. The reduction of LiP-II has a higher reorganization energy due to the change in spin state and the accompanying conformational change in the protein. It is suggested that a reversible nucleophilic addition of a carbohydrate residue located at the entrance of the active site channel plays a key role in the LiP redox cycle. Moreover. (polymeric) hydroxysubstituted benzyl radicals may reduce LiP-II via long-range electron transfer.     

Use of a micro-expanded bed containing immobilised lysozyme for cell disruption in flow injection analysis

A method for cell disruption in Flow Injection Analysis (FIA) systems has been developed. The principle involves on-line cell disruption by means of immobilised lysozyme followed by an ultrasonic treatment. In order to avoid flow problems in the analytical system, the lysozyme was immobilised to Streamline^reg that was used in an expanded bed in the flow system. Samples of suspensions of Micrococcus lysodeikticus were treated and the success of the treatment was evaluated in terms of released protein and as a decrease in the optical density at 450 nm. The new technology offers a powerful tool in flow injection analyses for quantification of intracellular compounds. The concept of integration, i.e. combining cell disruption with handling of cell debris and assay procedure in one continuous flow process facilitates its use and increases the probability of reaching reproducible and reliable results.     

Oxidation of a tetrameric nonphenolic lignin model compound by lignin peroxidase

The present study maps the active site of lignin peroxidase in respect to substrate size using either fungal or recombinant wild type, as well as mutated, recombinant lignin peroxidases. A nonphenolic tetrameric lignin model was synthesized that contains beta-O-4 linkages. The fungal and recombinant wild type lignin peroxidase both oxidized the tetrameric model forming four products. The four products were identified by mass spectral analyses and compared with synthetic standards. They were identified as tetrameric, trimeric, dimeric, and monomeric carbonyl compounds. All four of these products were also formed from single turnover experiments. This indicates that lignin peroxidase is able to attack any of the C(alpha)-C(beta) linkages in the tetrameric compound and that the substrate-binding site is well exposed. Mutation of the recombinant lignin peroxidase (isozyme H8) in the heme access channel, which is relatively restricted and was previously proposed to be the veratryl alcohol-binding site (E146S), had little effect on the oxidation of the tetramer. In contrast, mutation of a Trp residue (W171S) in the alternate proposed substrate-binding site completely inhibited the oxidation of the tetrameric model. These results are consistent with lignin peroxidase having an exposed active site capable of directly interacting with the lignin polymer without the advent of low molecular weight mediators.     

Molecular analysis of a Bjerkandera adusta lignin peroxidase gene

Summary A cDNA clone, LPO-1, encoding a major lignin peroxidase from the basidiomycete Bjerkandera adusta was isolated and characterized. The nucleotide sequence of LPO-1 predicts a mature protein consisting of 349 amino acids with a molecular weight of 37,225 preceded by a signal peptide of 23 amino acid residues. We have also cloned and sequenced the gene encoding lignin peroxidase from B. adusta. Comparison of these sequences reveals a lignin peroxidase gene structure consisting of 1,116 bp of protein-encoding DNA that is interrupted by four intervening sequences. The putative eukaryotic regulatory sequence, a TATA box, is present at position — 75 relative to the translational initiation codon. Amino acid sequence homology between the coding regions of LPO-1 and of the lignin peroxidase cDNA clone ML-1 from Phanerochaete chrysosporium is 61%. Offprint requests to: M. Kuwahara     

Continuous production of lignin peroxidase by Phanerochaete chrysosporium

Phanerochaete chrysosporium spores were immobilized both in agarose and agar gel beads, and used for the production of lignin peroxidase in repeated batch cultures on carbon-limited medium both with 0.5 g l⁻¹ glucose and without glucose. Veratryl alcohol was used as an activator of enzyme production. The biocatalyst was more stable in agarose gel with the maximum activity of 245 U l⁻¹ obtained in a 70 h batch. The biocatalyst could be used for at least 12 batches on the glucose medium with a gradual decrease in lignin peroxidase activity after the sixth batch. Further, mycelium pellets grown on carbon-limited medium were employed both in vertical and horizontal column reactors for the continuous production of lignin peroxidase. The bioreactor produced lignin peroxidase for at least 20 days in the horizontal system at 49 h residence time, with a maximum activity of 95 U l⁻¹.     

Electroenzymatic oxidation of veratryl alcohol by lignin peroxidase

This paper reports the formation of veratraldehyde by electroenzymatic oxidation of veratryl alcohol (3,4-dimethoxybenzyl alcohol) hybridizing both electrochemical and enzymatic reactions and using lignin peroxidase. The novel electroenzymatic method was found to be effective for replacement of hydrogen peroxide by an electrochemical reactor, which is essential for enzyme activity of lignin peroxidase. The effects of operating parameters such as enzyme dosage, pH, and electric potential were investigated. Further, the kinetics of veratryl alcohol oxidation in an electrochemical reactor were compared to oxidation when hydrogen peroxide was supplied externally.     

Purification, characterisation and coal depolymerisation activity of lignin peroxidase from Lenzitus betulina MTCC-1183

Lignin peroxidase from the culture filtrate of Lenzitus betulina MTCC-1183 has been purified to homogeneity using concentration by ultrafiltration and anion exchange chromatography on DEAE cellulose. The molecular weight of the purified lignin peroxidase using SDS-PAGE analysis was 43 kDa. Specific activity of the enzyme was 29.58 IU/mg. The K _m values for veratryl alcohol and H₂O₂ for the purified enzyme were 54 and 81 μM, respectively. The k _cat value of the purified enzyme was 2.3 s^?1 using 3,4-dimethoxybenzyl alcohol as the substrate. The optimal conditions for the lignin peroxidase assay were detected at pH 2.4 and 22°C. Thermal stability of the purified enzyme has also been studied and its activation energy for deactivation was 287 kJ/mol. The purified lignin peroxidase depolymerised humic acid in presence of H₂O₂. Depolymerisation of coal by the L. betulina MTCC-1183 has been demonstrated using humic acid as a model of coal.     

Degradation of synthetic lignin by the protoplasts of Phanerochaete chrysosporium in the presence of lignin peroxidase or manganese peroxidase

Lignin was mineralized in the experiments in which ¹⁴C-lignin was incubated with lignin peroxidase or manganese peroxidase in a tartrate buffer in the presence of cycloheximide-treated protoplasts obtained from the ligninolytic mycelia of Phanerochaete chrysosporium. The rate of lignin mineralization was dependent on the lignin peroxidase or manganese peroxidase concentration in the medium. In the experiments in which lignin was incubated with lignin peroxidase or manganese peroxidase, lignin was repolymerized irrespective of the presence of protoplasts mineralizing lignin, suggesting that an active degradation of lignin and repolymerization took place. Taking into account that lignin peroxidase and manganese peroxidase were the only extracellular enzymes in the experiments in which lignin was mineralized by the protoplasts, it is postulated that lignin peroxidase and/or manganese peroxidase can degrade lignin into small fragments which can then be further absorbed by the fungal cells and subsequently degraded to CO₂.     

Influence of lignin peroxidase concentration and localisation in lignin biodegradation by Phanerochaete chrysosporium

Summary The lignin mineralization rate in cultures of Phanerochaete chrysosporium increases with lignin peroxidase concentration up to 20 nkat ml^–1. At higher concentrations the rate of lignin mineralization decreases with increasing lignin peroxidase concentration. The amount of mycelium is not a limiting factor for lignin mineralization at high exocellular lignin peroxidase in association with the mycelium as pellets and no free exocellular enzyme induce a lignin mineralization rate equivalent to cultures reconstituted with washed pellets supplemented with 15 nkat ml^–1 of exogenous free enzyme. These results show that although lignin degradation by lignin peroxidase seems to be facilitated when lignin peroxidase is localised on the surface of the mycelium, free exocellular lignin peroxidase can also efficiently enhance mineralization of lignin by P. chrysosporium.     

Production of laccase, manganese peroxidase and lignin peroxidase by Brazilian marine-derived fungi

Marine-derived fungi are a potential for the search of new compounds with relevant features. Among these, the ligninolytic enzymes have potential applications in a large number of fields, including the environmental and industrial sectors. This is the work aimed to evaluate the enzymatic activities of three marine-derived fungi (Aspergillus sclerotiorum CBMAI 849, Cladosporium cladosporioides CBMAI 857 and Mucor racemosus CBMAI 847) under different carbon sources and salinity conditions by using statistical experimental design. MnP, LiP and laccase were detected when these fungi were cultured in malt extract, however when grown on basal medium containing glucose and wheat bran LiP was not detected and yet an increase in MnP and laccase was observed. Statistical analysis through surface responses was performed and results showed high values of MnP and laccase activities under 12.5% and 23% (w/v) salinity, highlighting the potential use of these fungi for industrial applications and in bioremediation of contaminated sites having high salt concentrations. The highest values for LiP (75376.34 UI L⁻¹), MnP (4484.30 IU L⁻¹) and laccase (898.15 UI L⁻¹) were obtained with the fungus M. racemosus CBMAI 847 and it is the first report concerning ligninolytic enzymes production by a zygomycete from this genus.     

Initial steps of ferulic acid polymerization by lignin peroxidase

The major products of the initial steps of ferulic acid polymerization by lignin peroxidase included three dehydrodimers resulting from beta-5' and beta-beta'coupling and two trimers resulting from the addition of ferulic acid moieties to decarboxylated derivatives of beta-O-4'- and beta-5'-coupled dehydrodimers. This is the first time that trimers have been identified from peroxidase-catalyzed oxidation of ferulic acid, and their formation appears to be favored by decarboxylation of dehydrodimer intermediates. After initial oxidation, the coupling reactions appear to be determined by the chemistry of ferulic acid phenoxy radicals, regardless of the enzyme and of whether the reaction is performed in vitro or in vivo. This claim is supported by our finding that horseradish peroxidase provides a similar product profile. Furthermore, two of the dehydrodimers were the two products obtained from laccase-catalyzed oxidation (Tatsumi, K. S., Freyer, A., Minard, R. D., and Bollag, J.-M. (1994) Environ. Sci. Technol. 28, 210-215), and the most abundant dehydrodimer is the most prominent in grass cell walls (Ralph, J., Quideau, S., Grabber, J. H., and Hatfield, R. D. (1994) J. Chem. Soc. Perkin Trans. 1, 3485-3498). Our results also indicate that the dehydrodimers and trimers are further oxidized by lignin peroxidase, suggesting that they are only intermediates in the polymerization of ferulic acid. The extent of polymerization appears to be dependent on the ionization potential of formed intermediates, H(2)O(2) concentration, and, probably, enzyme stability.     

Oxidation of 1-hydroxybenzotriazole by laccase and lignin peroxidase

A method to measure laccase and lignin peroxidase (LiP) activity at 408 nm (402–410 nm) using 1-hydroxybenzotriazole (HBT) was developed. The assay can be performed either as a kinetic measurement or as a stopped reaction using 5 mM Na-azide which improves the spectrum. Only white-rot fungal laccases and LiP were found to oxidize HBT to give shoulders or peaks at 402-410 nm. Phanerochaete and Phlebia manganese peroxidases did not give absorbance increase at 402–410 nm. © Rapid Science Ltd. 1998     

Production of lignin peroxidase and laccase by Phlebia radiata

Summary A cultivation method using carrierbound mycelium was developed for the production of lignin-modifying enzymes by Phlebia radiata. Laccase and lignin peroxidase were produced in batch and semi-continuous cultivations. Laccase activity was clearly enhanced by veratryl alcohol. The presence of both veratryl alcohol and Tween 80 was required for lignin peroxidase production in submerged cultivations. During the course of the semi-continuous cultivations production of lignin peroxidase activity increased fourfold compared with static cultivations.     

Inactivation of lignin peroxidase by phenylhydrazine and sodium azide

Lignin peroxidase (LiP) is rapidly inactivated in a concentration-dependent manner by H2O2 and either phenylhydrazine or sodium azide. Full inactivation of isozyme 2b (H8) requires approximately 50 eq of phenylhydrazine or 80 eq of sodium azide. Anaerobic incubation of isozyme 2b with [14C]phenylhydrazine and H2O2 results in 77% loss of catalytic activity and covalent binding of 0.45 mol radiolabel/mol of enzyme. Comparable but not identical results are obtained with an isozyme mixture. A lag period is observed before the peroxidative activity can be measured when an aliquot of an incubation with sodium azide is diluted into the mixture used to assay residual catalytic activity. This lag is associated with reversible accumulation of a catalytically inert species with a Compound III-like spectrum. No meso-phenyl, iron-phenyl, or N-phenyl adducts are formed with phenylhydrazine but a low yield of what appears to be delta-meso-azidoheme is obtained with sodium azide. LiP is thus less susceptible to meso heme additions and more susceptible to oxidative heme degradation than horseradish peroxidase. The data suggest that the active of LiP resembles the closed structure of horseradish peroxidase more than it does the open structure of the globins, catalase, chloroperoxidase, or cytochrome P450.     

Production of Phanerochaete chrysosporium lignin peroxidase

Liginin peroxidase (ligninase) of the white rot fungus Phanerochaete chrysosporium Burdsall was discovered in 1982 as a secondary metabolite. Today multiple isoenzymes are known, which are often collectively called as lignin peroxidase. Lignin peroxidase has been characterized as a veratryl alcohol oxidizing enzyme, but it is a relatively unspecific enzyme catalyzing a variety of reactions with hydrogen peroxide as the electron acceptor. P. chrysosporium ligninases are heme glycoproteins. At least a number of isoenzymes are also phosphorylated. Two of the major isoenzymes have been crystallized. Until recently lignin peroxidase could only be produced in low yields in very small scale stationary cultures owing to shear sensitivity. Most strains produce the enzyme only after grown under nitrogen or carbon limitation, although strains producing lignin peroxidase under nutrient sufficiency have also been isolated. Activities over 2000 U dm(-3) (as determined at 30 degrees to 37 degrees C) have been reported in small scale Erlenmeyer cultures with the strain INA-12 grown on glycerol in the presence of soybean phospholipids under nitrogen sufficiency. In about 8 dm(3) liquid volume pilot scale higher than 100 U dm(-3) (as determined at 23 degrees C) have been obtained under agitation with immobilized P. chrysosporium strains ATCC 24725 or TKK 20512. Good results have been obtained for example with nylon web, polyurethane foam, sintered glass or silicon tubing as the carrier. The immobilized biocatalyst systems have also made large scale repeated batch and semicontinuous production possible. With nylon web as the carrier, lignin peroxidase production has recently been scaled up to 800 dm(3) liquid volume semicontinuous industrial production process.