Aims: Exploitation of natural biodiversity in species Pycnoporus coccineus and Pycnoporus sanguineus to screen for a new generation of laccases with properties suitable for the lignin‐processing sector. Methods and Results: Thirty strains originating from subtropical and tropical environments, mainly isolated from fresh specimens collected in situ, were screened for laccase activity. On the basis of levels of enzyme activity and percentage of similarity between protein sequences, the laccases from strains BRFM 938, BRFM 66 and BRFM 902 were selected for purification and characterization. Each BRFM 938, BRFM 66 and BRFM 902 laccase gene encoded a predicted protein of 518 amino acids; the three deduced proteins showed 68·7–97·5% similarity with other Polyporale laccases. The three laccases (59·5–62·9 kDa with 7–10% carbohydrate content) had high redox potentials (0·72–0·75 V vs normal hydrogen electrode at pH 6), remained highly stable up to 75–78°C and at pH 5–7 mixtures, and were resistant to methyl and ethyl alcohols, acetonitrile and dimethylsulfoxide at concentrations as high as 50% (v/v). The best laccase‐1‐hydroxybenzotriazole systems permitted almost 100% of various polyphenolic dye decolourization and oxidation of adlerol and veratryl alcohol. Conclusions: The three laccases showed complementary biochemical features. BRFM 938 laccase had the highest thermo‐ and pH stability, catalytic efficiency towards 2,2′‐azino‐bis‐[3‐ethylthiazoline‐6‐sulfonate] and resistance to alcoholic solvents. BRFM 66 laccase had the highest rates of dye decolourization and oxidation of nonphenolic compounds. Significance and Impact of the Study: This study identified P. coccineus and P. sanguineus as outstanding producers of high redox potential laccases, easy to purify and scale‐up for industrial production. Three new laccases proved to be suitable models for white biotechnology processes and for further molecular breeding to create a new generation of tailor‐made enzymes.
The Pycnoporus fungi are white-rot basidiomycetes listed as food- and cosmetic-grade microorganisms. Three high redox potential laccases from Pycnoporus coccineus and Pycnoporus sanguineus were tested and compared, with the commercial Suberase® as reference, for their ability to synthesise natural active oligomers from rutin (quercetin-3-rutinoside, one of the best-known naturally occurring flavonoid glycosides). The aim of this work was to develop a process with technical parameters (solvent, temperature, reaction time and raw materials) that were easy to scale up for industrial production and compatible with cosmetic and pharmaceutical formulation guidelines. The aqueous mixture of glycerol/ethanol/buffer described in this study met this requirement and allowed the solubilisation of rutin and its oxidative bioconversion into oligomers. The four flavonoid oligomer mixtures synthesised using laccases as catalysts were analysed by high performance liquid chromatography-diode array detection-negative electrospray ionisation-multistage mass spectrometry. Their chromatographic elution profiles were compared and 16 compounds were characterised and identified as dimers and trimers of rutin. The oligorutins were different in Suberase® and Pycnoporus laccase reaction mixtures. They were evaluated for their antioxidant, anti-inflammatory and anti-ageing activities on specific enzymatic targets such as cyclooxygenase (COX-2) and human matrix metalloproteinase 3 (MMP-3). Expressed in terms of IC(50), the flavonoid oligomers displayed a 2.5- to 3-fold higher superoxide scavenging activity than monomeric rutin. Pycnoporus laccase and Suberase® oligorutins led to an inhibition of COX-2 of about 35% and 70%, respectively, while monomeric rutin showed a near-negligible inhibition effect, less than about 10%. The best results on MMP-3 activity were obtained with rutin oligomers from P. sanguineus IMB W006-2 laccase and Suberase® with about 70-75% inhibition.
Laccases have numerous biotechnological applications, among them food processing. The widespread use of laccases has increased the demand for an inexpensive and safe source of recombinant enzyme. We explored the use of a rice-based system for the production of two fungal laccases derived from the ascomycete Melanocarpus albomyces and the basidiomycete Pycnoporus cinnabarinus. High-expression levels of active recombinant laccases were achieved by targeting expression to the endosperm of rice seeds. The laccase cDNAs were fused to a plant-derived signal sequence for targeting to the secretory pathway, and placed under the control of a constitutive seed-specific promoter fused to an intron for enhanced expression. This construct enabled the recovery of on average 0.1-1% of soluble laccase in total soluble proteins (TSP). The highest yields of recombinant laccases obtained in rice seeds were 13 and 39 ppm for riceMaL and ricePycL, respectively. The rice-produced laccases were purified and characterized. The wild-type and the recombinant proteins showed similar biochemical features in terms of molecular mass, pI, temperature and optimal pH and the N-terminus was correctly processed. Although presenting lower kinetic parameters, the rice-produced laccases were also suitable for the oxidative cross-linking of a food model substrate [maize-bran feruloylated arabinoxylans (AX)].
The genus Pycnoporus forms a group of four species known especially for producing high redox potential laccases suitable for white biotechnology. A sample of 36 Pycnoporus strains originating from different geographical areas was studied to seek informative molecular markers for the typing of new strains in laboratory culture conditions and to analyse the phylogeographic relationships in this cosmopolitan group. ITS1-5.8S-ITS2 ribosomal DNA and partial regions of β-tubulin and laccase lac3-1 gene were sequenced. Phylogenetic trees inferred from these sequences clearly differentiated the group of Pycnoporus cinnabarinus strains from the group of Pycnoporus puniceus strains into strongly supported clades (100% bootstrap value). Molecular clustering based on lac 3-1 sequences enabled the distribution of Pycnoporus sanguineus and Pycnoporus coccineus through four distinct, well supported clades and sub-clades. A neotropical sub-clade, grouping the P. sanguineus strains from French Guiana and Venezuela, corresponded to P. sanguineus sensu stricto. A paleotropical sub-clade, clustering the strains from Madagascar, Vietnam and New Caledonia, was defined as Pycnoporus cf. sanguineus. The Australian clade corresponded to P. coccineus sensu stricto. The Eastern Asian region clade, clustering the strains from China and Japan, formed a P. coccineus-like group. Laccase gene (lac 3-1) analysis within the Pycnoporus species can highlight enzyme functional diversity associated with biogeographical origin.
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