Optimized production of lignolytic manganese peroxidase in immobilized cultures of <Emphasis Type="Italic">Phanerochaete chrysosporium</Emphasis>

Manganese peroxidase (MnP) is a key enzyme involved in the lignolysis of white-rot fungi. The purpose of this study is to investigate the effect of immobilization and culture conditions on MnP production in cultures of Phanerochaete chrysosporium grown on polyurethane foam. Higher concentrations of foam and lower levels of spore inoculums resulted in the formation of scattered mycelial pellets, increased autolysis of chlamydospore-like cells (a reservoir of MnP), and a higher activity of MnP. Even though MnP was a secondary metabolite, the addition of 5 times more glucose and diammonium tartrate, as carbon and nitrogen sources, resulted in a 4 fold increase in the dry cell mass. However, MnP activity decreased under these conditions to less than half, due to the formation of increasingly dense pellets and the inhibited lysis of chlamydospore-like cells.     

Extracellular ligninolytic enzyme production by Phanerochaete chrysosporium in a new solid-state bioreactor

The production of manganese-dependent peroxidase (MnP) and lignin peroxidase (LiP) by the fungus Phanerochaete chrysosporium (ATCC 24725) in a new bioreactor, the Immersion Bioreactor, which grows cells under solid-state conditions, was studied. Maximum MnP and LiP activities were 987 U l^–1 and 356 U l^–1, respectively. The polymeric dye, Poly R-478, was degraded at 2.4 mg l^–1 min^–1 using the extracellular culture filtrate.     

Amelioration of ligninolytic enzyme production by Phanerochaete chrysosporium in airlift bioreactors

Maximum activities of manganese-dependent peroxidase (MnP) and lignin peroxidase (LiP) in free cultures of Phanerochaete chrysosporium (ATCC 24725) were 258 U l^–1 and 103 U l^–1, respectively, in an airlift bioreactor. Immobilisation of the fungus on an inert carrier as well as several design modifications of the bioreactor employed gave MnP activities around 500–600 U l^–1 during 9 days' operation. The continuous operation of the latter led to MnP and LiP activities about 140 U l^–1 and 100 U l^–1, respectively, for two months, without operational problems. Furthermore, the extracellular liquid secreted decolourised the polymeric dye Poly R-478 about 56%.     

Production of the ligninolytic enzymes by immobilized <Emphasis Type="Italic">Phanerochaete chrysosporium</Emphasis> in an air atmosphere

Summary The production of the ligninolytic enzymes by Phanerochaete chrysosporium immobilized on polyurethane foam cubes in air was investigated by adopting different sizes and amounts of the carriers, different medium C/N ratios and different glucose-feeding strategies. No lignin peroxidase (LiP) activity was observed under nitrogen limitation (C/N ratio, expressed as glucose/NH₄⁺, 56/2.2 mM) with two sizes and three amounts of the carriers, while comparable levels of manganese peroxidase (MnP) activities were detected only in non-immersed cultures with two sizes of the carriers. A non-immersed state also stimulated LiP formation under carbon limitation (C/N ratio 28/44 mM). High peak activities of LiP, 197 and 164 U/l, were obtained in non-immersed cultures under carbon limitation at the C/N ratios of 28/44 and 56/44 mM, respectively, the occurrence of the activities coinciding with the complete consumption of glucose. A very low level of MnP was measured at the C/N ratio of 28/44 mM compared with the similar activities at 56/2.2 and 56/44 mM. An addition of 2 g glucose/l after its complete depletion improved both the production of LiP and MnP markedly in non-immersed culture at the initial C/N ratio of 28/44 mM, whereas a replenishment of 5 g/l, still enhancing the formation of MnP, inhibited the production of LiP first before the later reactivation. It is suggested that non-immersed liquid culture under carbon limitation reinforced by a suitable glucose feeding strategy is one potential way to realize high production of the ligninolytic enzymes by P. chrysosporium in air.     

Optimization of manganese peroxidase and laccase production in the South American fungus<Emphasis Type="Italic"> Fomes sclerodermeus</Emphasis> (Lév.) Cke

Fomes sclerodermeus produces manganese peroxidase (MnP) and laccase as part of its ligninolytic system. A Doehlert experimental design was applied in order to find the optimum conditions for MnP and laccase production. The factors studied were Cu²⁺, Mn²⁺ and asparagine. The present model and data analysis allowed us not only to define optimal media for production of both laccase and MnP, but also to show the combined effects between the factors. MnP was strongly influenced by Mn²⁺, which acts as an inducer. Under these conditions Cu²⁺ negatively affected MnP activity. At 13 days of growth 0.75 U ml^–1 were produced in the optimized culture medium supplemented with 1 mM MnSO₄ and 4 g l^–1 asparagine. The laccase titer under optimized conditions reached maximum values at 16 days of growth: 13.5 U ml^–1 in the presence of 0.2 mM CuSO₄, 0.4 mM MnSO₄ and 6 g l^–1 asparagine. Mn²⁺ promoted production of both enzymes. There were important interactions among the nutrients evaluated, the most significant being those between Cu²⁺ and asparagine.     

Use of Phanerochaete chrysosporium Immobilized on Kissiris for Synthetic Dye Decolourization: Involvement of Manganese Peroxidase

The mineral Kissiris, which is formed from the thickened foam of volcanic lava, was tested to approximate its mineral composition using energy-dispersive X-ray (EDX) analysis. The solid mineral contains silicon dioxide at about 16 (w/w). The considerable surface roughness of Kissiris along with its extensive porosity made this natural solid cell support an attractive candidate for manganese peroxidase (MnP) production for synthetic dye decolourization, at low cost. The white rot fungus Phanerochaete chrysosporium immobilized on the mineral Kissiris was grown in both stationary and agitated cultures (rotary shaker, 100 rev/min) using either carbon- or nitrogen-limited growth medium to study the ability of the fungus to degrade the synthetic dye methylene blue (MB). The value of residual dye for MB used at 60 ppm was 6% within 8 days of the incubation of the nitrogen-limited culture under the shaken conditions. Production of (MnP) occurred simultaneously in nitrogen-limited culture medium with the added MnSO₄ at 100 ppm. The MnP activity was at relatively high level (170 U/l).     

两种方法形成菌丝球固定2-氯酚降解菌的对比

【目的】系统研究吸附法和同时培养法对所形成混合菌丝球的外观形态、内部结构及其去除2-氯酚效果的影响。【方法】采用吸附法和同时培养法将可降解2-氯酚的光合细菌PSB-1D固定在黄孢原毛平革菌(Phanerochaete chrysosporium)DH-1发酵而成的菌丝球上,形成混合菌丝球。以单一菌丝球为对照,利用光学显微镜、扫描电镜等仪器观察混合菌丝球的外观形态和内部结构,考察2种方法对混合菌丝球成球效果的影响;以无菌培养液为空白对照,考察游离光合细菌、单一菌丝球、2种方法形成混合菌丝球对2-氯酚的降解效能。【结果】在吸附法形成的混合菌丝球上,光合细菌主要集中在过渡区;而同时培养法将光合细菌牢固地包埋在菌丝球内核区,并大量簇状附着生长在菌丝交联的空隙处和每根菌丝上。在接种等量孢子和光合细菌的前提下,同时培养法较吸附法操作时间更短,成球数量更多,形成菌丝球干湿比更大,单位菌丝干重上固定的细菌数量更多。菌丝球降解体系和游离光合细菌对2-氯酚的降解均符合一级动力学特征。同时培养法形成的混合菌丝球降解效果最好,7 d内对初始浓度为50 mg/L的2-氯酚降解率可达89%以上,降解速率常数为0.3286 mg/(L·d),2-氯酚半衰期t1/2为2.8 d。【结论】首次报道黄孢原毛平革菌包埋固定化光合细菌形成混合菌丝球。该研究为生物质固定化材料的实际应用提供理论依据。     

Parameter optimization for production of ligninolytic enzymes using agro-industrial wastes by response surface method

Lignin and manganese peroxidase (LiP, MnP) and laccase production by Phanerocheate chrysosporium was optimized by response surface methodology for brewery waste and apple pomace. The effect of moisture, copper sulphate, and veratryl alcohol (VA) concentrations on enzyme production was studied. Moisture and VA had significant positive effect on MnP and LiP production and the viability of P. chrysosporium (p < 0.05) and copper sulphate produced a negative effect. However, moisture and copper sulphate had a significant positive (p < 0.05) effect on laccase production, but VA had an insignificant positive effect (p < 0.05). Higher values of MnP, LiP and viability of P. chrysosporium on apple pomace (1287.5 U MnP/gds (units/gram dry substrate), 305 U LiP/gds, and 10.38 Log 10 viability) and brewery waste (792 U MnP/gds and 9.83 Log 10 viability) were obtained with 80% moisture, 3 mmol/kg VA, and 0.5 mmol/kg copper. LiP production in brewery waste (7.87 U/gds) was maximal at 70% moisture, 2 mmol/kg VA, and 1 mmol/kg copper. Higher production of laccase in apple pomace (789 U/gds) and brewery waste (841 U/gds) were obtained with 80% moisture, 3 mmol/kg VA, and 1.5 mmol/kg copper. Thus, moisture along with VA and copper sulphate was pertinent for the production of ligninolytic enzymes and increased cell viability.     

Use of diluted medium in repeated-batch fermentation for production of lignin peroxidase by <Emphasis Type="Italic">Phanerochaete chrysosporium</Emphasis>

Lignin peroxidase has been extensively studied due to the potential use of this enzyme in environmental pollution control. Important aspects of the production of the enzyme by the white rot fungus, Phanerochaete chrysosporium, include the improvement of yield results and cell maintenance. In the present work, Phanerochaete chrysosporium was immobilized in polyurethane foam and used for repeated-batch fermentations with various dilution of the initial medium (D), and lignin peroxidase production was investigated. The peak of 283 ± 17.5 U lignin peroxidase/l production rate was obtained at a D of 1/5, with significantly lower production rates seen at higher and lower dilution ratios. When six cycles of repeated-batch fermentation were conducted using a D of 1/5, the results revealed that at least four cycles of repeated-batch fermentation were possible with a high lignin peroxidase production rate under a cut-off value of 178 ± 3.87 U/l. Furthermore, the cell-free culture broth could be successfully concentrated to 2,800 U/l by ultrafiltration. Thus, the present study shows that optimizing the dilution of the utilized nutritional medium can improve repeated batch production of lignin peroxidase from immobilized P. chrysosporium, in terms of both cycle number and output.     

Color removal ability of <Emphasis Type="Italic">Phanerochaete chrysosporium</Emphasis> in relation to lignin peroxidase and manganese peroxidase produced in molasses wastewater

Decolorization of molasses wastewater (MWW) from an ethanolic fermentation plant by Phanerochaete chrysosporium was studied. By diluting MWW properly (10%v/v) and incubating it with an appropriate concentration of the spores (2.5 × 10⁶/ml), extensive decolorization occurred (75%) on day 5 of the incubation. The colour removal ability was found to be correlated to the activity of ligninolytic enzyme system: lignin peroxidase (LiP) activity was 185 U/l while manganese peroxidase (MnP) activity equaled 25 U/l. Effects of some selected operating variables were studied: manganese(II), veratryl alcohol (VA), glucose as a carbon source and urea and ammonium nitrate, each as a source of nitrogen. Results showed that the colour reduction and LiP activity were highest (76% and 186 U/l, respectively) either when no Mn(II) was added or added at the lowest level tested (0.16 mg/l to provide 0.3 mg/l). Activity of MnP was highest (25 U/l) when Mn(II) added to the diluted MWW at the highest level (100 ppm) while activity of LiP was lowest (7.1 U/l) at this level of added Mn(II). The colour reduction in the presence of the added VA was shown to be little less than in its absence (70 vs. 75%). When urea as an organic source of nitrogen for the fungus, was added to the MWW, the decolorizing activity of P. chrysosporium decreased significantly (15 vs. 75%) and no activities were detected for LiP and MnP. Use of ammonium nitrate as an inorganic source of nitrogen did not show such a decelerating effects, although no improvements in the metabolic behavior of the fungus (i.e., LiP and MnP activities) deaccelerating was observed. Effects of addition of glucose was also discussed.     

Degradation of dye-containing textile effluent by the agaric white-rot fungus Clitocybula dusenii

Raw mixed-dye wastewater from a textile dye-producing plant was partly decolorized by the agaric white-rot fungus, Clitocybula dusenii. The fungus had higher Mn peroxidase (MnP) and laccase activities when grown with dye effluent than in control cultures. The activity of MnP increased commensurately with the proportion of the raw dye wastewater in the medium (control: 20 U l^–1; 10% v/v effluent: 67 U l^–1; 25% v/v effluent: 130 U l^–1; and 33% v/v effluent: 180 U l^–1). Maximal decolorization rates were achieved over 20 d at 28 °C using four-fold diluted dye-containing effluent on a 5 d pre-grown mycelium.     

Decolorization of synthetic dyes and production of manganese-dependent peroxidase by new fungal isolates

Two yeasts, Debaryomyces polymorphus, Candida tropicalis, and two filamentous fungi, Umbelopsis isabellina, Penicillium geastrivorus, could completely decolorize 100 mg Reactive Black 5 (RB 5) l^–1 within 16–48 h. Manganese-dependent peroxidase (MnP) activities between 60 and 424 U l^–1 were detected in culture supernatants of three of these organisms indicating the color removal by enzymatic biodegradation but with P. geastrivorus there was no ligninolytic enzyme activity in its culture and the decolorization was mainly due to biosorption to mycelium. Extensive decolorization by D. polymorphus (69–94%) and C. tropicalis (30–97%) was obtained with five other azo dyes and one anthraquinone dye. Except for Reactive Brilliant Blue KNR and Reactive Yellow M-3R, the four azo dyes, Reactive Red M-3BE, Procion Scharlach H-E3G, Procion Marine H-EXL and Reactive Brilliant Red K-2BP, induced D. polymorphus to produce MnP (105–587 U l^–1). However, MnP activities of 198–329 U l^–1 were only detected in the culture of C. tropicalis containing Reactive Red M-3BE and Reactive Brilliant Red K-2BP, respectively.     

Mn(II) Regulation of Lignin Peroxidases and Manganese-Dependent Peroxidases from Lignin-Degrading White Rot Fungi

Two families of peroxidases—lignin peroxidase (LiP) and manganese-dependent lignin peroxidase (MnP)—are formed by the lignin-degrading white rot basidiomycete Phanerochaete chrysosporium and other white rot fungi. Isoenzymes of these enzyme families carry out reactions important to the biodegradation of lignin. This research investigated the regulation of LiP and MnP production by Mn(II). In liquid culture, LiP titers varied as an inverse function of and MnP titers varied as a direct function of the Mn(II) concentration. The extracellular isoenzyme profiles differed radically at low and high Mn(II) levels, whereas other fermentation parameters, including extracellular protein concentrations, the glucose consumption rate, and the accumulation of cell dry weight, did not change significantly with the Mn(II) concentration. In the absence of Mn(II), extracellular LiP isoenzymes predominated, whereas in the presence of Mn(II), MnP isoenzymes were dominant. The release of ¹⁴CO₂ from ¹⁴C-labeled dehydrogenative polymerizate lignin was likewise affected by Mn(II). The rate of ¹⁴CO₂ release increased at low Mn(II) and decreased at high Mn(II) concentrations. This regulatory effect of Mn(II) occurred with five strains of P. chrysosporium, two other species of Phanerochaete, three species of Phlebia, Lentinula edodes, and Phellinus pini.     

Selective hyperproduction of manganese peroxidases byPhanerochaete chrysosporium l-1512 immobilized on nylon net in a bubble-column reactor

Manganese peroxidases were overproduced byPhanerochaete chrysosporium I-1512 immobilized on nylon net in a bubble-column reactor. This study investigates a new design of bioreactor, a compromise between a pneumatic reactor and an immobilized biofilm reactor. The carrier, a sheet of nylon net, was maintained by a cylindrical stainless-steel frame installed vertically. It was characterized by its hydrophilic nature, its surface morphology and its surface roughness.P. chrysosporium adhesion was highly efficient; mycelial hyphae invaded the tridimensional structure and strengthened the bonding to the network, as shown by electron scanning microscopy. High levels of Mn peroxidases were produced by strain I-1512 under conditions of glycerol and nitrogen sufficiency when the medium was supplemented with phospholipid and veratryl alcohol. Yields of 3600 U/l Mn peroxidase were produced after 95 h of incubation, indicating significant productivity for industrial purposes (900 U day^–1 l^–1).     

Increasing manganese peroxidase productivity of Phanerochaete chrysosporium by optimizing carbon sources and supplementing small molecules

Aims: To overproduce manganese peroxidase (MnP) using Phanerochaete chrysosporium. Effects of carbon sources, agricultural by‐products and small molecules were tested to enhance the MnP productivity. Methods and Results: Various carbon sources and agricultural by‐products were compared as the basal medium. A MnP activity of 4·7 ± 0·31 U ml^?1 was obtained using mannose as a carbon source. The enzyme productivity further reached 7·36 ± 0·05 and 8·77 ± 0·23 U ml^?1 when the mannose medium was supplemented with cyclic adenosine monophosphate (cAMP) and S‐adenosylmethionine, respectively. Conclusions: This study revealed the highest MnP productivity obtained by optimizing the carbon sources and supplementing small molecules. It can provide insight for: (i) making high quantities of enzymes by optimizing media resources and (ii) engineering the global regulatory genes in P. chrysosporium for the onsite production of MnP. Significance and Impact of the Study: As MnP is an important enzyme to hydrolyse lignin polymers which protects the plant cell wall from exposing of cellulose fibres, the production of the enzyme is a current demand for biofuel biotechnology. The knowledge generated from this study can help to advance the technology for stable production of MnP.     

Enhanced ligninolytic enzyme production and degrading capability of Phanerochaete chrysosporium and Trametes versicolor

Ligninolytic enzyme production by the white-rot fungi Phanerochaete chrysosporium and Trametes versicolor precultivated with different insoluble lignocellulosic materials (grape seeds, barley bran and wood shavings) was investigated. Cultures of Phanerochaete chrysosporium precultivated with grape seeds and barley bran showed maximum lignin peroxidase (LiP) and manganese-dependent peroxidase (MnP) activities (1000 and 1232 U/l, respectively). Trametes versicolor precultivated with the same lignocellulosic residues showed the maximum laccase activity (around 250 U/l). For both fungi, the ligninolytic activities were about two-fold higher than those attained in the control cultures. In vitro decolorization of the polymeric dye Poly R-478 by the extracellular liquid obtained in the above-mentioned cultures was monitored in order to determine the respective capabilities of laccase, LiP and MnP. It is noteworthy that the degrading capability of LiP when P. chrysosporium was precultivated with barley bran gave a percentage of Poly R-478 decolorization of about 80% in 100 s, whereas control cultures showed a lower percentage, around 20%, after 2 min of the decolorization reaction.     

Indigo production in hairy root cultures of Polygonum tinctorium Lour.

The transformed root culture of Polygonum tinctorium Lour. was established by infecting leaf explants with Agrobacterium rhizogenes A4. These cultures were examined for their growth and indigo content under various culture conditions. Among the four different culture media tested, SH medium showed the highest yield for root growth (28 mg dry wt/30 ml) and indigo production (152 g/dry wt). In SH medium, 30 g sucrose l^–1, 2500 mg KNO₃ l^–1, 300 mg NH₄H₂PO₄ l^–1 were the best conditions for indigo production at pH 5.7. The production of indigo in hairy roots slightly increased with the addition of 200 mg chitosan l^–1 (186 g/dry wt) and 20 U pectinase l^–1 (181 g/dry wt).     

Immobilization ofPhanerochaete chrysosporium on porous polyurethane particles with application to biodegradation of 2-chlorophenol

Porous polyurethane particles were prepared and used for the immobilization of white rot fungusPhanerochaete chrysosporium. The immobilized cells were employed for the production of lignin peroxidase. Polyurethane immobilized spores, or mycelial pellets ofPhanerochaete chrysosporium as well as freely suspended mycelial pellets of fungus were used as biocatalyst for the degradation of 2-chlorophenol. The polyurethane carriers appear to be superior to the other carriers already used for the immobilization of fungus.     

A scalable membrane gradostat reactor for enzyme production using Phanerochaete chrysosporium

This is the first demonstration of process scale-up of a membrane gradostat reactor for continuous enzyme production using Phanerochaete chrysosporium ME446. The fungus was immobilised by reverse filtration on to externally unskinned, ultrafiltration capillary membranes and then nutrient gradients were induced across the biofilm. A 10-fold scale-up from a single capillary bioreactor to a 2.4 l multi-capillary unit resulted in a 7-fold increase in enzyme productivity with a peak at 209 U l^–1 d^–1. Subsequent scale effects on the spore distribution, continuous manganese peroxidase production profile and biofilm development are discussed.     

Continuous production of lignin-degrading enzymes by Bjerkandera adusta immobilized on polyurethane foam

Continuous production of lignin-degrading enzymes by Bjerkandera adusta immobilized on polyurethane foam gave maximum activities of 220 U lignin peroxidase ml^–1, 150 U manganese peroxidase ml^–1, 50 U laccase ml^–1 and 6.2 U protease ml^–1 at the retention time of 24 h for 60 days. Protease secretion destabilized the produced lignin peroxidase, manganese peroxidase and laccase.