启动子替代构建糙皮侧耳漆酶高产菌株

POXC是糙皮侧耳合成最多的一种漆酶。应用启动子替代技术,用构巢曲霉的甘油醛-3-磷酸脱氢酶基因（gpd）启动子替代POXC基因的启动子,构建了超量表达POXC糙皮侧耳转化子。转化子中POXC基因表达量比出发菌株提高了0.72–3倍。在PDA平板培养、PD摇瓶培养和棉籽壳试管培养条件下,转化子漆酶活力显著提高,比出发菌株提高了1.5倍以上。用棉籽壳栽培,转化子菇产量比出发菌株提高了16.2%,培养料中木质素含量比出发菌株减少21%。结果表明,应用高效启动子替代能够显著提高糙皮侧耳漆酶基因的表达量、漆酶活力及其木质纤维素降解能力。     

Structural characterization of heterodimeric laccases from <Emphasis Type="Italic">Pleurotus ostreatus</Emphasis>

The subfamily of POXA3 laccase isoenzymes produced by the fungus Pleurotus ostreatus has been characterized as an example of the complexity and heterogeneity of fungal isoenzyme patterns. Two isoenzymes, POXA3a and POXA3b, were previously purified, exhibiting an unusual heterodimeric structure composed of a large (67 kDa) and a small (18 or 16 kDa) subunit. A unique gene encodes the large subunit of both POXA3a and POXA3b, but alternative splicing produces two variants—differing for an insertion of four amino acids—for each isoenzyme. Two genes encoding POXA3a and POXA3b small subunits have been identified, and the corresponding amino acid sequences show only two amino acid substitutions. The 18- and 16-kDa subunits of both POXA3a and POXA3b differ for N-glycosylation at Asn150 of the 16-kDa subunit. The POXA3 large subunit 3D model allows us to highlight peculiarities of this molecule with respect to the laccases whose 3D structures are known.     

Recombinant expression of Pleurotus ostreatus laccases in Kluyveromyces lactis and Saccharomyces cerevisiae

Heterologous expression of Pleurotus ostreatus POXC and POXA1b laccases in two yeasts, Kluyveromyces lactis and Saccharomyces cerevisiae, was performed. Both transformed hosts secreted recombinant active laccases, although K. lactis was much more effective than S. cerevisiae. rPOXA1b transformants always had higher secreted activity than rPOXC transformants did. The lower tendency of K. lactis with respect to S. cerevisiae to hyperglycosylate recombinant proteins was confirmed. Recombinant laccases from K. lactis were purified and characterised. Specific activities of native and recombinant POXA1b are similar. On the other hand, rPOXC specific activity is much lower than that of the native protein, perhaps due to incomplete or incorrect folding. Both recombinant laccase signal peptides were correctly cleaved, with rPOXA1b protein having two C-terminal amino acids removed. The availability of the established recombinant expression system provides better understanding of laccase structure–function relationships and allows the development of new oxidative catalysts through molecular evolution techniques.     

Transgenic tobacco plants expressing a fungal laccase are able to reduce phenol content from olive mill wastewaters

A biotechnological approach was applied to reduce phenol content in olive mill wastewaters by transgenic tobacco plants. The cDNA laccase of poxC gene from Pleurotus ostreatus, carrying its own signal peptide for extracellular secretion, was transferred into the Nicotiana tabacum genome. Transgenic tobacco plants were obtained and the recombinant enzyme was secreted into the rhizosphere by the plant root apparatus, confirming the ability of the plant machinery to recognize the fungal POXC peptide signal leader appropriately as secretory tag. Total laccase activity assayed by ABTS in transgenic lines increased sharply compared to control plants. Moreover, plants cultivated in a hydroponic solution with the addition of olive mill wastewaters were able to reduce the total phenol content up to 70%.     

Molecular determinants of peculiar properties of a Pleurotus ostreatus laccase: Analysis by site-directed mutagenesis

A comparison of laccase sequences highlighted the presence of a C-terminal extension of sixteen amino acids in POXA1b laccase – that represents the most thermostable isoenzyme among Pleurotus ostreatus laccases and exhibits a notable stability at alkaline pH (t_1/2 at pH 10 = 30 days) – whereas this tail is missing in the other analysed laccases from basidiomycetes. Site-directed mutagenesis experiments allowed us to demonstrate a role of the C-terminal tail of POXA1b in affecting its catalytic and stability properties. The truncated mutants lose the high stability at pH 10, while they show an increased stability at pH 5. The effect of substituting the residue Asp205 of POXA1b with an arginine was also analysed in the mutant POXA1bD205R. Following the mutation POXA1bD205R, a remarkable worsening of catalytic properties along with a decrease of substrate affinity and of enzyme stability were found. It was demonstrated that introducing Arg205 mutation in a highly conserved region perturbs the structural local environment in POXA1b, leading to a large rearrangement of the enzyme structure. Hence, a single substitution in the binding site introduces a local conformational change that not only leads to very different catalytic properties, but can also significantly destabilize the protein.     

Molecular determinants of peculiar properties of a Pleurotus ostreatus laccase: Analysis by site-directed mutagenesis

A comparison of laccase sequences highlighted the presence of a C-terminal extension of sixteen amino acids in POXA1b laccase – that represents the most thermostable isoenzyme among Pleurotus ostreatus laccases and exhibits a notable stability at alkaline pH (t_1/2 at pH 10 = 30 days) – whereas this tail is missing in the other analysed laccases from basidiomycetes. Site-directed mutagenesis experiments allowed us to demonstrate a role of the C-terminal tail of POXA1b in affecting its catalytic and stability properties. The truncated mutants lose the high stability at pH 10, while they show an increased stability at pH 5. The effect of substituting the residue Asp205 of POXA1b with an arginine was also analysed in the mutant POXA1bD205R. Following the mutation POXA1bD205R, a remarkable worsening of catalytic properties along with a decrease of substrate affinity and of enzyme stability were found. It was demonstrated that introducing Arg205 mutation in a highly conserved region perturbs the structural local environment in POXA1b, leading to a large rearrangement of the enzyme structure. Hence, a single substitution in the binding site introduces a local conformational change that not only leads to very different catalytic properties, but can also significantly destabilize the protein.     

Development of new laccases by directed evolution: functional and computational analyses

Laccases are blue multicopper oxidases that couple the four-electron reduction of oxygen with the oxidation of a broad range of aromatic substrates. These fungal enzymes can be used for many applications such as bleaching, organic synthesis, bioremediation, and in laundry detergents. Laccases from Pleurotus ostreatus have been successfully heterologously expressed in yeasts. The availability of established recombinant expression systems has allowed the construction of mutated, "better performing" enzymes through molecular evolution techniques. In the present work, random mutagenesis experiments on poxc and poxa1b cDNAs, using error prone PCR (EP-PCR) have been performed. By screening a library of 1100 clones the mutant 1M9B was selected, it shows a single mutation (L112F) leading to an enzyme more active but less stable with respect to the wild-type enzyme (POXA1b) in all the analyzed conditions. This mutant has been used as a template for a second round of EP-PCR. From this second generation library of 1200 clones, three mutants have been selected. Properties of the four mutants, 1M9B screened from the first library, and 1L2B, 1M10B, and 3M7C from the second library, were analyzed. The better performing mutant 3M7C presents, besides L112F, only one substitution (P494T) responsible both for the significantly increased stability and for the exhibited higher activity of this mutant. Molecular dynamics simulations have been performed on three-dimensional models of POXA1b, 1M9B, and 3M7C, and hypotheses on the structure-function relationships of these proteins have been formulated.     

Heterologous expression of heterodimeric laccase from Pleurotus ostreatus in Kluyveromyces lactis

Among the laccases produced by the white-rot fungus Pleurotus ostreatus, there are two closely related atypical isoenzymes, POXA3a and POXA3b. These isoenzymes are endowed with quaternary structure, consisting of two subunits very different in size. The POXA3 large subunit is clearly homologous to other known laccases, while the small subunit does not show significant homology with any protein in data banks. To investigate on the singular structure of the POXA3 complex, a new system for recombinant expression of heterodimer proteins in the yeast Kluyveromyces lactis has been set up. A unique expression vector has been used and the cDNAs encoding the two subunits have been cloned under the control of the same bi-directionally acting promoter. Expression of the large subunit alone and co-expression of both subunits in the same host have been demonstrated and the properties of the recombinant proteins have been compared. Clones expressing the large subunit alone exhibited always notably lower activity than those expressing both subunits. In addition to the activity increase, the presence of the small subunit led to a significant increase of laccase stability. Therefore, a role of the small subunit in POXA3 stabilisation is suggested.     

Random mutants of a Pleurotus ostreatus laccase as new biocatalysts for industrial effluents bioremediation

Aims: To select better performing laccase variants among the 2300 randomly mutated variants of Pleurotus ostreatus POXA1b laccase to develop improved laccase‐based biocatalysts. Methods and Results: Screening of collections of 2300 randomly mutated variants of POXA1b was performed by assaying activity towards the phenolic substrate 2,6‐dimethoxyphenol. Two new variants endowed with higher enzyme activity than the wild‐type laccase were characterized, and their ability to decolourize industrial dyes with complex trisazo‐, polyazo‐ and stilbene‐type structures, in the absence of mediators, was demonstrated. One of the mutants (2L4A) was also proved to be highly stable at both acidic and alkaline pH values (displaying a half‐life of around 1 month at the pH levels of both 5 and 10). Conclusions: In comparison with the wild‐type laccase, the new selected 2L4A mutant shows a significant increase in stability at acidic pH, whilst storing its high stability at alkaline pH. This variant also represents a more versatile enzyme with respect to both the variety of xenobiotics degraded and the operative conditions. Significance and Impact of the Study: This work represents the first example of improvement of a basidiomycete laccase for industrial effluents bioremediation by directed evolution.     

Structural and kinetic characterization of native laccases from Pleurotus ostreatus, Rigidoporus lignosus, and Trametes trogii

A comparative study has been performed on five native laccases purified from the three basidiomycete fungi Pleurotus ostreatus, Rigidoporus lignosus, and Trametes trogii to relate their different catalytic capacities to their structural properties. Spectroscopic absorption features and EPR spectra at various pH values of the five enzymes are very similar and typical of the blue oxidases. The analysis of the dependence of kinetic parameters on pH suggested that a histidine residue is involved in the binding of nonphenolic substrates, whereas both a histidine and an acidic residue may be involved in the binding of phenolic compounds. His and an Asp residue are indeed found at the bottom of a cavity which may be regarded as a suitable substrate channel for approaching to type 1 copper in the 3D homology models of the two laccases from Pleuorotus ostreatus (POXC and POXA1b) whose sequences are known.     

Evidence for a radical mechanism in biocatalytic degradation of synthetic dyes by fungal laccases mediated by violuric acid

The bleaching activity of the Pleurotus ostreatus POXC laccase isoenzyme has been tested against selected single textile acid dyes (two anthraquinonic and two azo dyes), as well as towards a solution mimicking a real acid dye waste-water for wool. The catalytic reaction of POXC has been investigated both in the presence and in the absence of the synthetic mediator violuric acid (VIO) (–NOH type of mediator). In all the cases tested, the presence of the mediator enhanced the reaction rate and the percentage of decolorization, apart from one of the dyes (Acid Blue 62), which is itself a good substrate for the laccase-catalyzed oxidation. Electron paramagnetic resonance (EPR) experiments, after the addition of an excess of VIO to the solution of laccase, showed the presence of a strong and stable radical signal that was assigned to a neutral radical form of VIO.     

Morphology and laccase production of white-rot fungi grown on wheat bran flakes under semi-solid-state fermentation conditions

In this paper, we studied the laccase production and the growth morphology of different white-rot fungi, i.e. Pleurotus ostreatus, Trametes pubescens, Cerrena unicolor and Trametes versicolor, cultured under semi-solid-state fermentation conditions using wheat bran flakes as a natural low-cost support substrate. Trametes versicolor exhibited the highest laccase activity per gram of total dry matter, followed by P. ostreatus (63.5 and 58.2Ug(-1) , respectively). In addition, they showed a time profile of laccase production that was quite similar. Growth morphology was studied using environmental microscopic images and analyzed by discrete Fourier transformation-based software to determine the mean diameter of the hyphae, the number of hypha layers and the global micromorphology. The four strains exhibited different micromorphologies of growth. Pleurotus ostreatus presented narrow hyphae, which formed many thick clumps, T. pubescens and T. versicolor showed clumps of different sizes and C. unicolor showed thick hyphae that formed larger clumps, but in less amounts.     

A Semi-Rational Approach to Engineering Laccase Enzymes

In order to develop improved laccase-based bio-catalysts, semi-rational mutagenesis of the laccase POXA1b from Pleurotus ostreatus was performed through a combination of directed evolution with elements of rational enzyme modification. The R4 laccase was prepared by joining mutations of previously selected POXA1b random variants. An enhancement of stability features was thus obtained, making the novel enzyme R4 more appropriate as scaffold for directed evolution. A library of 1000 randomly mutated variants of R4 was prepared and screened for the ability of oxidising 2,2′-azino-bis(3-ethylbenzothiazoline-6-sulphonic acid) (ABTS). One of the variants selected (V148L) for improved activity was also proved to show higher stability than R4 at pH 5, and to retain its high stability at pH 7 and 10. In comparison with the POXA1b wild-type laccase, the semi-rational approach allowed us to develop a more efficient bio-catalyst, rising specific activity on ABTS up to around 5-fold. The new variant was also proved to be both more versatile and more durable than the wild-type enzyme, exhibiting higher activity in wide temperature and pH ranges and higher stability at acidic (t _1/2 at pH 5 = 35 days), neutral (t _1/2 at pH 7 = 38 days) and alkaline (t _1/2 at pH 10 = 62 days) pH values.     

Manganese peroxidase isoenzymes produced by Pleurotus ostreatus grown on wood sawdust

The white rot basidiomycete Pleurotus ostreatus produces two manganese peroxidase (MnP) isoenzymes when grown in solid stationary conditions on poplar sawdust, whereas a lower production of these same enzymes is observed on fir sawdust. Addition of Mn(2+) to poplar culture resulted in a threefold increase of MnP activity; the same addition to fir culture was able to increase tenfold the MnP production. The two MnP isoenzymes (MnP2 and MnP3) were purified from P. ostreatus poplar culture. The isoenzymes differ in their pI values, molecular masses, and N-terminal sequences. MnP3 has the same N-terminal sequence as that of a P. ostreatus MnP previously reported. Both isoenzymes exhibit Mn(2+)-dependent and Mn(2+)-independent peroxidase activities when tested on phenolic substrates. The gene coding for the new isoenzyme MnP2 was cloned and sequenced and the promoter region analyzed. Furthermore, the chromosomal localization of all known P. ostreatus genes was determined.     

Fungal laccases: versatile tools for lignocellulose transformation

Conversion of lignocellulosic materials to useful, high value products normally requires a pre-treatment step to transform or deconstruct the recalcitrant and heterogeneous lignin fraction. The development of "green tools" for the transformation of lignocellulosic feedstocks is in high demand for a sustainable exploitation of such resources. This multi-faceted challenge is being addressed by an ever-increasing suite of ligninolytic enzymes isolated from various sources. Among these, fungal laccases are known to play an important role in lignin degradation/modification processes. The white-rot fungus Pleurotus ostreatus expresses multiple laccase genes encoding isoenzymes with different properties. The availability of established recombinant expression systems for P.?ostreatus laccase isoenzymes has allowed to further enrich the panel of P.?ostreatus laccases by the construction of mutated, "better performing" enzymes through molecular evolution techniques. New oxidative catalysts with improved activity and stability either at high temperature and at acidic and alkaline pH have been isolated and characterized.     

Laccase isoenzymes of Pleurotus eryngii: characterization, catalytic properties, and participation in activation of molecular oxygen and Mn2+ oxidation.

Two laccase isoenzymes produced by Pleurotus eryngii were purified to electrophoretic homogeneity (42- and 43-fold) with an overall yield of 56.3%. Laccases I and II from this fungus are monomeric glycoproteins with 7 and 1% carbohydrate content, molecular masses (by sodium dodecyl sulfate-polyacrylamide gel electrophoresis) of 65 and 61 kDa, and pIs of 4.1 and 4.2, respectively. The highest rate of 2,2'-azino-bis(3-ethylbenzothiazoline-6-sulfonate) oxidation for laccase I was reached at 65 degrees C and pH 4, and that for laccase II was reached at 55 degrees C and pH 3.5. Both isoenzymes are stable at high pH, retaining 60 to 70% activity after 24 h from pH 8 to 12. Their amino acid compositions and N-terminal sequences were determined, the latter strongly differing from those of laccases of other basidiomycetes. Antibodies against laccase I reacted with laccase II, as well as with laccases from Pleurotus ostreatus, Pleurotus pulmonarius, and Pleurotus floridanus. Different hydroxy- and methoxy-substituted phenols and aromatic amines were oxidized by the two laccase isoenzymes from P. eryngii, and the influence of the nature, number, and disposition of aromatic-ring substituents on kinetic constants is discussed. Although both isoenzymes presented similar substrate affinities, the maximum rates of reactions catalyzed by laccase I were higher than those of laccase II. In reactions with hydroquinones, semiquinones produced by laccase isoenzymes were in part converted into quinones via autoxidation. The superoxide anion radical produced in the latter reaction dismutated, producing hydrogen peroxide. In the presence of manganous ion, the superoxide union was reduced to hydrogen peroxide with the concomitant production of manganic ion. These results confirmed that laccase in the presence of hydroquinones can participate in the production of both reduced oxygen species and manganic ions.     

Selection of Trichoderma strains capable of increasing laccase production by Pleurotus ostreatus and Agaricus bisporus in dual cultures

Aims:  To select Trichoderma strains for enhanced laccase production in Pleurotus ostreatus or Agaricus bisporus cultures.
Methods and Results:  Laccase production by P. ostreatus and A. bisporus was evaluated in liquid (axenic) and solid (dual cultures) malt extract medium. Oxidation of ABTS, DMP and syringaldazine was evaluated in order to assess the potential of Trichoderma strains to enhance laccase production by basidiomycetes. Selected Pleurotus–Trichoderma interactions yielded higher increases in laccase volumetric activity and an additional laccase isoform was produced. By contrast, Agaricus–Trichoderma interactions lead to smaller increases on laccase volumetric activity, probably as result of repression (or degradation) towards one of the laccases isoforms.
Conclusions:  The strains of P. ostreatus and A. bisporus assessed in this work showed good potential as laccase producers. The Trichoderma -mediated biological stimulation of laccase production by P. ostreatus and A. bisporus is relevant in order to develop highly productive processes.
Significance and Impact of the Study:  Extracellular laccases from basidiomycetes are produced only in small amounts. It is therefore important to increase process productivity for potential industrial applications. The results from this study enable the selection Trichoderma strains capable of increasing laccase production by P. ostreatus or A. bisporus in dual cultures.