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.     

Induction,purification, and characterization of a thermo and pH stable laccase from Abortiporus biennis J2 and its application on the clarification of litchi juice

A fungus J2 producing laccase with high yield was screened in soils and identified as Abortiporus biennis. The production of laccase was induced by 0.1 mM Cu²⁺, 0.1 mM tannic acid, and 0.5 M ethanol. The laccase from Abortiporus biennis J2 was purified to electrophoretic homogeneity by a couple of steps. The N-terminal amino acid sequence of the enzyme was AIGPTADLNISNADI. The properties of the purified laccase were investigated. The result showed the laccase from Abortiporus biennis J2 is a thermo and pH stable enzyme. The laccase activity was inhibited by Hg²⁺, Cd²⁺, Fe²⁺, Ag⁺, Cu²⁺, and Zn²⁺, while promoted by Mg²⁺, Mn²⁺ at 10 mM level. Purified laccase was used to the clarification of litchi juice. After treatment with this laccase, the phenolic content of litchi juice had been found to be greatly reduced along with an increase in the clarity of the juice. The result indicated the potential of this laccase for application in juice procession.     

Overproduction of laccase by a monokaryotic strain of Pycnoporus cinnabarinus using ethanol as inducer

AIMS: Laccase production by the monokaryotic strain Pycnoporus cinnabarinus ss3 was studied using ethanol as inducer in the culture medium. METHODS AND RESULTS: The effect of ethanol was tested at 10, 20, 30, 35 and 45 g l-1 and compared with that of ferulic acid, known until now as the most efficient inducer for laccase expression by P. cinnabarinus ss3. In the presence of 35 g l-1 ethanol, laccase activity (266 600 U l-1) and productivity (19 000 U l-1 day-1) were nine and fivefold higher compared with ferulic acid-induced cultures, and 155- and 65-fold higher compared with non-induced cultures, respectively. In vivo, ethanol added to the culture medium of P. cinnabarinus ss3 favoured a continuous and high expression of laccase gene. Under these conditions, P. cinnabarinus ss3 produced preferentially the isoenzyme LAC I. Ethanol added in vitro to the purified P. cinnabarinus ss3 laccase typically inhibited the enzymatic activity. CONCLUSIONS: In spite of an initial inhibitory effect on mycelial growth, ethanol was shown to be a very strong inducer for laccase expression by P. cinnabarinus ss3 allowing an average yield of 1-1.5 g l-1 laccase. SIGNIFICANCE AND IMPACT OF THE STUDY: This study identified P. cinnabarinus ss3 as an outstanding producer of laccase in the presence of ethanol as inducer. Ethanol is an inexpensive agricultural by-product and the process is simple to scale-up for industrial production.     

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.     

Induction of a white laccase from the deuteromycete Myrothecium verrucaria NF-05 and its potential in decolorization of dyes

Myrothecium verrucaria NF-05 is a deuteromycete fungus capable of producing a white laccase. The optimal concentration of Cu²⁺ for laccase production by this strain is 0.2 mM (43.23 ± 1.16 U mL^{? 1}). A comprehensive investigation of the induction demonstrated that NF-05 laccase production could be synergistically enhanced by various inducers, including aromatic phenols, amines and recalcitrant dyes, in the presence of 0.2 mM Cu²⁺. Sixteen phenols, fourteen amines and four dyes exhibited significant inductive effects on laccase production. The best inducer was 3, 3’-dimethylbenzidine, which increased laccase production to 258.1 ± 11.1 U mL^{? 1}. These results suggest that M. verrucaria NF-05 is a promising industrial laccase producer. Based on the increased production, purified NF-05 laccase was used to decolorize dyes of various structural types in the presence of six redox mediators. Among the 26 tested dyes, the decolorization rate of six azo dyes, chromotrope 2R, orange G6, Congo red, Ponceau S, amaranth and reactive yellow 135 and two arylmethane dyes, fast green 3 and neutral red, were significantly increased by each of the six mediators. These results demonstrate the potential use of the NF-05 laccase for the decolorization of recalcitrant dyes in dye bleaching and effluent detoxification.     

Influence of Several Activators on the Extracellular Laccase Activity and In vivo Decolourization of Poly R‐478 by Semi‐Solid‐State Cultures of Trametes versicolor

The effect of several laccase activity activators,such as ethanol (novel activator), veratryl alcohol, melanin production and aeration level, on the laccase production by Trametes versicolor (CBS100.29) was investigated. The microorganism was cultivated on nylon sponge, functioning as a physical support on which the mycelium was bound. The cultures with veratryl alcohol showed maximum laccase and manganese‐dependent peroxidase (MnP) activities of 238 U/l and 125 U/l, respectively. The laccase activity found is about two times higher than that attained in the control cultures. On the contrary, MnP activity did not appear to be influenced by the addition of this alcohol. Ethanol‐supplemented cultures led to maximum laccase and MnP activity levels of about 102 U/l and 101 U/l, respectively. These activities were approx. 40% lower than those achieved in the reference cultures. The decolourization of the polymeric dye Poly R‐478 by the above‐mentioned cultures was also investigated. A percentage of biological decolourization of around 90% was achieved with control and veratryl alcohol‐supplemented cultures, whereas with ethanol‐supplemented cultures a slightly lower percentage of around 85% was reached after seven days of dye incubation.     

Laccase production in solid‐state and submerged fermentation by Pleurotus ostreatus

A solid‐state fermentation (SSF) system for production of an industrially important enzyme laccase by Pleurotus ostreatus was developed by using potato dextrose yeast extract medium and polyurethane foam as a supporting material. The maximum laccase production in the SSF system was as high as 3×10⁵ U/L. Addition of inducers, such as copper and ferulic acid, further enhanced the laccase production in SSF. Moreover, the time required for the maximum laccase production was reduced to 6 days compared to 10 days reported earlier. The improvement achieved by the SSF system was investigated by comparing it to a submerged fermentation system (SmF), both experimentally and by using a standard theoretical model along with a parameter sensitivity analysis. Laccase production in SSF was found to be twice of that in SmF. One of the main reasons for higher laccase production in SSF compared to SmF was possibly due to the presence of higher proteolytic activity in SmF. Strong proteolytic activity in SmF presumably caused subsequent laccase degradation, which lowered the ultimate laccase production in SmF compared to SSF.     

Efficient production of Al(OH)3‐immobilized laccase with a Heterobasidion annosum strain selected by microplate screening

Aims: Wild‐type white rot fungi are the most important production organisms for laccase, a promising oxidative biocatalyst with numerous applications. This study aimed at identifying novel highly productive strains, finding optimal cultivation conditions for laccase production and establishing a simple immobilization procedure. Methods and Results: By using a newly developed 96‐well microplate cultivation method, 23 species of white rot fungi, represented by 29 strains, were directly compared with regard to the amount of secreted laccase. Both, with glucose and spruce saw dust as growth substrate a Heterobasidion annosum strain and a Physisporinus vitreus strain were the most productive (730–2200 U l^?1 of secreted laccase). Cultivation conditions for laccase production with H. annosum were optimized in larger‐scale liquid cultures. Aeration with a sparger lead to a 3·8‐fold increase in laccase activity when compared to nonaerated flask cultures. More than 3000 U l^?1 laccase was produced in glucose medium supplemented with yeast extract and the inducer veratryl alcohol. Culture supernatant was incubated with short‐range ordered Al(OH)₃ particles to directly immobilize and concentrate laccase by adsorption. Active laccase was recovered in 40% yield and the Al(OH)₃‐adsorbed laccase was suitable for repeated decolourization of indigo carmine. Conclusions: Microplate cultivation allowed a large‐scale comparison of the capacity of different fungal species for laccase production. Laccase secretion of a highly productive H. annosum strain was found to vary strongly with different cultivation conditions. Adsorption to Al(OH)₃ proved to be suitable as direct immobilization technique. Significance and Impact of the Study: The microplate screening method simplifies strain and medium development for laccase production. Two novel fungal strains suitable for laccase production were identified. Procedures for simple and efficient production of immobilized H. annosum laccase were established.     

Effect of aromatic compounds on the production of laccase and manganese peroxidase by white-rot basidiomycetes

Three white-rot fungi displayed a wide diversity in their response to supplemented aromatic compounds. Pyrogallol stimulated Cerrena unicolor laccase and manganese peroxidase (MnP) synthesis in synthetic medium 2.5- and 2-fold, respectively, whereas 2,4,6-trinitrotoluene (TNT) brought about a 2.8-fold increase in laccase yield by Trametes versicolor in submerged fermentation of ethanol production residue. No effect of the tested aromatic compounds on enzyme secretion by Ganoderma lucidum in mannitol-containing medium was detected. Nevertheless, G. lucidum is a potent producer of laccase in submerged fermentation of wheat bran and enzyme synthesis can be further increased by supplementation of medium with an appropriate inducer. The structure and the concentration of aromatic compounds play an important role in the regulation of enzyme synthesis. The supplementation of synthetic medium with 0.03–0.3 mM TNT or hydroquinone increased the differential rate of laccase synthesis by C. unicolor from 1,267 to 3,125–8,630 U mg biomass^?1 day^?1. Moreover, the same aromatic compound may function as either an inducer or a repressor, depending on the fungus and enzyme studied. Thus, hydroquinone increased 3-fold T. versicolor laccase activity decreasing 2- and 8-fold the yields of MnP and endoglucanase, respectively.     

Development of a Saccharomyces cerevisiae Strain with Enhanced Resistance to Phenolic Fermentation Inhibitors in Lignocellulose Hydrolysates by Heterologous Expression of Laccase

To improve production of fuel ethanol from renewable raw materials, laccase from the white rot fungus Trametes versicolor was expressed under control of the PGK1 promoter in Saccharomyces cerevisiae to increase its resistance to phenolic inhibitors in lignocellulose hydrolysates. It was found that the laccase activity could be enhanced twofold by simultaneous overexpression of the homologous t-SNARE Sso2p. The factors affecting the level of active laccase obtained, besides the cultivation temperature, included pH and aeration. Laccase-expressing and Sso2p-overexpressing S. cerevisiae was cultivated in the presence of coniferyl aldehyde to examine resistance to lignocellulose-derived phenolic fermentation inhibitors. The laccase-producing transformant had the ability to convert coniferyl aldehyde at a faster rate than a control transformant not expressing laccase, which enabled faster growth and ethanol formation. The laccase-producing transformant was also able to ferment a dilute acid spruce hydrolysate at a faster rate than the control transformant. A decrease in the content of low-molecular-mass aromatic compounds, accompanied by an increase in the content of high-molecular-mass compounds, was observed during fermentation with the laccase-expressing strain, illustrating that laccase was active even at the very low levels of oxygen supplied. Our results demonstrate the importance of phenolic compounds as fermentation inhibitors and the advantage of using laccase-expressing yeast strains for producing ethanol from lignocellulose.     

Growth and laccase production by Pleurotus ostreatus in submerged and solid-state fermentation

Pleurotus ostreatus showed atypical laccase production in submerged vs. solid-state fermentation. Cultures grown in submerged fermentation produced laccase at 13,000 U l⁻¹, with a biomass production of 5.6 g l⁻¹ and four laccase isoforms. However, cultures grown in solid-state fermentation had a much lower laccase activity of 2,430 U l⁻¹, biomass production of 4.5 g l⁻¹, and three laccase isoforms. These results show that P. ostreatus performs much better in submerged fermentation than in solid-state fermentation. This is the first report that shows such atypical behavior in the production of extracellular laccases by fungi.     

An alkalophilic laccase from Rheinheimera species isolate: Production and biobleaching of kraft pulp

Medium optimization was carried out to enhance laccase production from a novel Rheinheimera species, isolated from industrial effluent. Out of the 15 variables tested by Placket–Burman design (PBD)—yeast extract, soyabean meal, and peptone were the positively significant ones, enhancing laccase production. Both simple and complex sugars showed a negative effect on laccase production. Central composite design (CCD) of experiments, using the three positively significant variables in combinations, showed that laccase production was not affected by molar carbon, molar nitrogen levels or molar C/N ratio. Maximum laccase yield of 2.5 × 10⁵ nkat L^?1, 31 fold enhancement over the unoptimized medium, was achieved when soyabean meal (0.6%) was used alone as medium showing that laccase production was substrate dependent. Laccase was used, in the presence of 2 mM ABTS, for the biobleaching of eucalyptus kraft pulp resulting in kappa number reduction by 20% and brightness increase by 2.9%. Biobleaching improved further by sequential application of an alkalophilic xylanase (X) and laccase‐ABTS system (LAS) that decreased kappa number by 10, 15, and 35%, increased brightness by 2.7, 3.2, and 5.9% as compared to X treated, LAS treated and untreated control, respectively. XLAS treatment resulted in 15, 13, 10.9% increase in burst factor, tear factor, and viscosity with a 20% reduced consumption of elemental chlorine and hypochlorite. © 2012 American Institute of Chemical Engineers Biotechnol. Prog., 2012     

Production of laccase byBotrytis cinerea and fermentation studies with strain F226

After induction, seven strains ofBotrytis cinerea released into the culture broth considerable amounts of laccase in a brief production time. The set-up of a suitable production process was studied with a selected strain in a 10-L fermenter. The optimum fermentation conditions were a 3% inoculum with a high degree of sporulation, a simple medium containing 20 g L^–1 of glucose and 2 g L^–1 of yeast extract at pH 3.5, 2 g L^–1 gallic acid as inducer, added after 2 days of growth, an agitation speed of 300 rpm, an aeration rate of 1.2 vvm and a temperature of 24°C. By optimizing the culture conditions, the enzyme activity reached 28 U ml^–1 in 5 days with a specific activity of 560 U mg^–1 protein. The best procedure to obtain a suitable crude enzyme preparation was concentration of the supernatant medium to 10% of the initial volume by ultrafiltration, followed by a fractional precipitation with ethanol. The optimum pH and temperature for laccase activity were 5.5 and 40°C, respectively, with syringaldazine as the substrate.     

Increased production of extracellular laccase by the white rot fungus Coriolus versicolor MTCC 138

Summary The white rot fungus Coriolus versicolor MTCC 138 has been identified as an excellent producer of the industrially important enzyme laccase. The basal medium containing glucose gave laccase activity of 155 U/ml. Screening of different media components and their effects on laccase production by Coriolus versicolor was studied using one factor at a time and L₉ (3⁴) orthogonal array method. A two-fold increase (305 U/ml) in laccase production was observed using a combination of glucose and starch as carbon source and yeast extract as nitrogen source. This activity is very high as compared to most of the reported strains. Hence this strain was explored for enhancement in laccase. The formation of extracellular laccase could be considerably stimulated by the addition of copper in the optimized medium. Addition of 1 mM copper enhanced laccase activity to 460 U/ml. Laccase production was further enhanced using different aromatic inducers. Among different inducers used 2,5-xylidine was found to be the best, and gave maximum laccase activity of 820 U/ml with 1 mM concentration. Thus, this strain could be an efficient and attractive source for laccase production.     

Enhancement of laccase production by Pleurotus ostreatus and its use for the decolorization of anthraquinone dye

The white-rot fungus Pleurotus ostreatus strain 32 is an excellent producer of the industrially important enzyme laccase. Laccase was the only ligninolytic activity detected in the supernatant when the fungus was grown in liquid culture with or without shaking. Growth and laccase production in static cultivation were superior to that in agitated cultivation, and N-limited culture is of benefit to laccase production. When using cellobiose and peptone as carbon and nitrogen source, a higher activity level was obtained. 2,2′-Azino-di-(3-ethylbenzothialozin-6-sulfonic acid) (ABTS) (1 mM) was shown to be the best inducer of laccase production, reaching maximum values of about 400 U/ml. Cu²⁺ (1 mM) also had a positive effect on laccase production, activity being enhanced to 360 U/ml. In addition, anthraquinone dye SN4R can be effectively decolorized by crude laccase (30 U/ml), the rate of which was 66%. The decolorization rate was increased by 90% with ABTS (0.16%) addition as a mediator of laccase.     

Production of laccase by a newly isolated deuteromycete fungus <Emphasis Type="Italic">Pestalotiopsis</Emphasis> sp. and its decolorization of azo dye

The effect of various carbon and nitrogen sources on the production of laccase by newly isolated deuteromycete Pestalotiopsis sp. was tested under liquid-state fermentation. Twenty grams per liter of glucose and 10 g l⁻¹ ammonium tartrate were found to be the optimized concentrations of carbon and nitrogen sources, respectively. The influence of different inducers and inhibitors on the laccase production was also examined. Adding the Cu up to optimum concentration of 2.0 mM in medium (include 20 g l⁻¹ glucose and 10 g l⁻¹ ammonium tartrate), the highest laccase activity of 32.7 ± 1.7 U ml^−l was achieved. Cu had to be supplemented after 2 days of growth for its maximal effect, an addition after 6 days of growth, during which laccase activity was dominantly formed, resulted in distinctly reduced laccase activity. In addition, Direct Fast Blue B2RL can be effectively decolorized by crude laccase, the decolorization percentage of which was 88.0 ± 3.2% at pH 4.0 within 12 h. The results suggest that Pestalotiopsis sp. is a high potential producer of the industrially important enzyme laccase.     

Development of a Saccharomyces cerevisiae strain with enhanced resistance to phenolic fermentation inhibitors in lignocellulose hydrolysates by heterologous expression of laccase

To improve production of fuel ethanol from renewable raw materials, laccase from the white rot fungus Trametes versicolor was expressed under control of the PGK1 promoter in Saccharomyces cerevisiae to increase its resistance to phenolic inhibitors in lignocellulose hydrolysates. It was found that the laccase activity could be enhanced twofold by simultaneous overexpression of the homologous t-SNARE Sso2p. The factors affecting the level of active laccase obtained, besides the cultivation temperature, included pH and aeration. Laccase-expressing and Sso2p-overexpressing S. cerevisiae was cultivated in the presence of coniferyl aldehyde to examine resistance to lignocellulose-derived phenolic fermentation inhibitors. The laccase-producing transformant had the ability to convert coniferyl aldehyde at a faster rate than a control transformant not expressing laccase, which enabled faster growth and ethanol formation. The laccase-producing transformant was also able to ferment a dilute acid spruce hydrolysate at a faster rate than the control transformant. A decrease in the content of low-molecular-mass aromatic compounds, accompanied by an increase in the content of high-molecular-mass compounds, was observed during fermentation with the laccase-expressing strain, illustrating that laccase was active even at the very low levels of oxygen supplied. Our results demonstrate the importance of phenolic compounds as fermentation inhibitors and the advantage of using laccase-expressing yeast strains for producing ethanol from lignocellulose.     

Effect of Cu2+, Mn2+ and aromatic compounds on the production of laccase isoforms by Coprinus comatus

Six different extracellular laccase isoforms were identified in submerged cultures of the commercially important edible mushroom, Coprinus comatus. Although laccase activity (~55 IU/L) was readily detectable in unsupplemented control cultures containing 1.6 μM Cu²⁺ after 22-day incubation, mean enzyme levels (~150–185 IU/L) were 2.7–3.4-fold higher in cultures supplemented with 0.5–3.0 mM Cu²⁺. Laccase production was also stimulated by Mn supplementation over the range 0.05–0.8 mM Mn²⁺, and the peak value of ~225 IU/L recorded after 22 days in cultures containing 0.8 mM added Mn²⁺ was 4.5-fold higher compared with unsupplemented controls. Of 12 aromatic compounds tested for their effect on laccase isozyme production by C. comatus, highest laccase levels (~188 IU/L), equivalent to a 4.4-fold increase compared with unsupplemented controls (~43 IU/L), were recorded after 22 days in cultures supplemented with 3.0 mM caffeic acid. Other aromatic compounds tested all stimulated laccase production, with peak enzyme levels 1.3–3.3-fold higher compared with unsupplemented controls. Extracellular laccase levels in cultures supplemented with optimal concentrations of Mn²⁺ and caffeic acid together were 38% and 15% lower, respectively, compared with cultures containing the separate supplements. Lac1 was the most abundant laccase isoform produced under all the conditions tested, but marked differences were observed in the production patterns of Lac2–Lac6.     

Production and characterization of laccase from Pleurotus ferulae in submerged fermentation

Pleurotus ferulae is a mushroom typically found in arid steppe that is distributed widely in the Junggar Basin of Xinjiang, China. In this work, laccase production by P. ferulae JM30X was optimized in terms of medium composition and culture conditions. After optimization, the highest laccase activity obtained was 6,832.86 U/L. A single isozyme with a molecular weight of 66 kDa was observed by SDS-PAGE and native-PAGE. Optimum pH and temperature were 3.0 and 50–70 °C, respectively. The best laccase substrate was ABTS, for which the Michaelis-Menten constant (K _m) and catalytic efficiency (K _cat/K _m) value for P. ferulae laccase were 0.193 mM and 2.73?×?10⁶ (mM s)^?1, respectively. The activity of purified laccase was increased by more than four-fold by Cu²⁺, Mn²⁺ and Mg²⁺, while it was completely inhibited by Fe²⁺ and Fe³⁺. The production of laccase was influenced by the initial pH and K⁺ concentration, and the activity of purified laccase was enhanced by Cu²⁺, Mn²⁺ and Mg²⁺. This Pleurotus genus laccase from P. ferulae JM30X was analyzed by MS spectrum and the results are conducive to furthering our understanding of Pleurotus genus laccases.