L-Cystathionine as a Component of Ezomycins A1 and B1 from a Streptomyces

(1R,2S)-1-(3′-Chloro-4′-methoxyphenyl)-1,2- propanediol (Trametol, 3), a metabolite of the fungus Trametes sp. IVP-F640 and Bjerkandera sp. BOS55, was synthesized by employing Sharpless asymmetric dihydroxylation as the key step. Similarly, the (1R,2S)-isomer of 1-(3′,5′-dichloro-4′-methoxyphenyl)-1,2-propanediol (4), another metabolite of Bjerkandera sp. BOS55, was synthesized by asymmetric dihydroxylation.     

Simple and easy method for the determination of fungal growth and decolourative capacity in solid media

A technique was developed for studying the biodegradative ability of white rot fungi in different solid media. This technique enables the gravimetric determination of fungal growth (increase of biomass) and the spectrometric measurement of fungal decolourization ability (both by the determination of the production of the extracellular enzyme manganese-dependent peroxidase (MnP) and by the rate of decolourization of dyes). Bjerkandera sp., strain BOS55, was grown in different solid media. Its growth rate, decolourization of solophenil blue 2BL (azoic dye), neutral red (eurhodin dye), methyl green and crystal violet (triphenylmethane dyes) and the production of MnP were determined. Application of this technique enabled a spectrometric quantification of enzymatic activity. Assays indicate that greater amounts of MnP were present in agar plate cultures of Bjerkandera sp. than in liquid cultures.     

Use of cheese whey as a substrate to produce manganese peroxidase by Bjerkandera sp BOS55

Manganese peroxidase, MnP, is one of the major ligninolytic enzymes produced by a number of white-rot fungi. The ability of this enzyme to degrade lignin by the fungus Bjerkanderasp BOS55 has opened its application to related bioprocesses such as recalcitrant-compound degradation and effluent decolorization. The medium reported to induce MnP production is composed of chemical grade reagents, all with relatively high costs for application to detoxification purposes. The use of inexpensive sources for MnP production can bring its implementation closer. For this purpose, dairy residues from cheese processing were considered. MnP production obtained using crude whey as the sole substrate reached appreciable levels, around 190 U L⁻¹, values comparable to those found with synthetic media (between 175–250 U L⁻¹). Thus, this cheese-processing byproduct can be used as an inexpensive alternative for the large-scale production of MnP. Received 14 December 1998/ Accepted in revised form 29 April 1999     

Physiological Role of Chlorinated Aryl Alcohols Biosynthesized De Novo by the White Rot Fungus Bjerkandera sp. Strain BOS55

The white rot fungus Bjerkandera sp. strain BOS55 produces veratryl, anisyl, 3-chloroanisyl, and 3,5-dichloroanisyl alcohol and the corresponding aldehydes de novo from glucose. All metabolites are produced simultaneously with the extracellular ligninolytic enzymes and have an important physiological function in the fungal ligninolytic system. Both mono- and dichlorinated anisyl alcohols are distinctly better substrates for the extracellular aryl alcohol oxidases than veratryl alcohol. The aldehydes formed are readily recycled by reduction by washed fungal mycelium, thus creating an extracellular H₂O₂ production system regulated by intracellular enzymes. Lignin peroxidase does not oxidize the chlorinated anisyl alcohols either in the absence or in the presence of veratryl alcohol. It was therefore concluded that the chlorinated anisyl alcohols are well protected against the fungus's own aggressive ligninolytic enzymes. The relative amounts of veratryl alcohol and the chlorinated anisyl alcohols differ significantly according to the growth conditions, indicating that production of veratryl alcohol and the production of the (chlorinated) anisyl metabolites are independently regulated. We conclude that the chlorinated anisyl metabolites biosynthesized by the white rot fungus Bjerkandera sp. strain BOS55 can be purposefully produced for ecologically significant processes such as lignin degradation.     

Evaluation of different fungal strains in the decolourisation of synthetic dyes

Of seven fungal strains tested for their ability to decolourise three structurally diverse synthetic dyes, Phanerochaete sordida, Bjerkandera sp. BOS55, Phlebia radiata, and Phanerochaete chrysosporium had average values of maximum decolourisation rates higher than 0.2 [Absorbance] d^–1. All seven fungi produced manganese peroxidase (MnP) but laccase activity was detected only in Phlebia radiata. No lignin peroxidase (LiP) activity was observed.     

The physiology of anthracene biodegradation by the white-rot fungus Bjerkandera sp. strain BOS55

A recently isolated white-rot strain, Bjerkandera sp. strain BOS55, displays high extracellular peroxidase activity, and rapidly degrades polycyclic aromatic hydrocarbons (PAH). In this study, the culture conditions for the biodegradation of the model PAH compound, anthracene, were optimized with respect to O₂, N, and C. An additional objective was to determine if the decolorization of the polymeric ligninolytic indicator dye, Poly R-478, could be correlated to anthracene biodegradation observed under a wide range of culture conditions. The supply of O₂ was found to be the most important parameter in the biodegradation of anthracene. Increasing culture aeration enhanced the biodegradation of anthracene and the accumulation of its peroxidase-mediated oxidation product anthraquinone. Decolorization of Poly R-478 was less affected by inadequate aeration. Provided that ample aeration was supplied, the degradation of anthracene under different culture conditions was strongly correlated with the ligninolytic activity as indicated by the rate of Poly R-478 decolorization. Concentrations up to 22 mM NH₄ ⁺ N did not repress anthracene biodegradation and only caused a 0%–40% repression of the Poly R-478 decolorizing activity in various experiments. A cosubstrate requirement of 100 mg glucose / mg anthracene biodegraded was observed in this study.     

Oxidation of anthracene in water/solvent mixtures by the white-rot fungus,Bjerkandera sp. strain BOS55

Polycyclic aromatic hydrocarbons (PAH) are persistent priority pollutants of soil and sediments. The use of white-rot fungi has been proposed as a means of bioremediating PAH-polluted sites. However, higher PAH compounds of low bioavailability in polluted soil are biodegraded slowly. In order to enhance their bioavailability, PAH solubilization, can be increased in water/solvent mixtures. The oxidation of a model PAH compound, anthracene, in the presence of cosolvents by the white-rot fungus, Bjerkandera sp. strain BOS55 was investigated. Acetone and ethanol at 5% were toxic to this fungus when added at the time of inoculation. However, when solvents up to 20% (v/v) were added to 9-day-old cultures, ligninolytic activity as indicated by Poly R-478 dye decolorization and anthracene oxidation was evident for several days. Since 20% solvent was toxic to cells, the oxidation of anthracene can be attributed to extracellular peroxidases, which were shown to tolerate the solvent. Solvent additions of 11%–21% (v/v) acetone or ethanol increased the rate of anthracene bioconversion to anthraquinone in liquid medium by a factor of 2–3 compared to fungal cultures receiving 1%–3% solvent.     

Stimulation of Ligninolytic Peroxidase Activity by Nitrogen Nutrients in the White Rot Fungus Bjerkandera sp. Strain BOS55

Bjerkandera sp. strain BOS55, a newly isolated wild-type white rot fungus, produced lignin peroxidase (LiP) in nitrogen (N)-sufficient glucose-peptone medium, whereas no LiP was detectable in N-limited medium. The production of LiP was induced by the peptide-containing components of this medium and also by soy bean protein. Furthermore, the production of manganese-dependent peroxidase was stimulated by organic N sources, although lower production was also evident in N-limited medium. Further research showed that the induction of LiP depended on the combination of pH and the type of N source. An amino acid mixture and ammonium induced LiP only at either pH 6 or 7.3, respectively. Peptone induced LiP activity at all pH values tested; however, the highest activity was observed at pH 7.3. The results presented here indicate that Bjerkandera spp. are distinct from the model white rot fungus, Phanerochaete chrysosporium, which produces ligninolytic peroxidases in response to N limitation.     

The ability of white-rot fungi to degrade the endocrine-disrupting compound nonylphenol

Phanerochaete chrysosporium, Pleurotus ostreatus, Trametes versicolor and Bjerkandera sp. BOL13 were tested for their ability to degrade the endocrine-disrupting compound nonylphenol at an initial concentration of 100 mg l^–1. The highest removals were achieved with T. versicolor and Bjerkandera sp. BOL13, which were able to degrade 97 mg l^–1 and 99 mg l^–1 of nonylphenol in 25 days of incubation, respectively. Nonylphenol removal was associated with the production of laccase by T. versicolor, but the levels of laccase, manganese peroxidase and lignin peroxidase produced by Bjerkandera sp. BOL13 were very low. At 14°C, T. versicolor and Bjerkandera sp. BOL13 sustained the removal of 88 mg l^–1 and 79 mg l^–1 of nonylphenol, respectively. No pollutant removal was recorded at 4°C, although both fungi could grow at this temperature in the absence of nonylphenol. A microtoxicity assay showed that the fungi produced compounds that were toxic to Vibrio fischerii; and thus a reduction in toxicity could not be correlated with nonylphenol metabolism. T. versicolor and Bjerkandera sp. BOL13 were capable of colonizing soil artificially contaminated with 430 mg kg^–1 of nonylphenol. Only 1.3±0.1% of nonylphenol remained in the soil after 5 weeks of incubation.     

Role of Organic Acids in the Manganese-Independent Biobleaching System of Bjerkandera sp. Strain BOS55

Bjerkandera sp. strain BOS55 is a white rot fungus that can bleach EDTA-extracted eucalyptus oxygen-delignified kraft pulp (OKP) without any requirement for manganese. Under manganese-free conditions, additions of simple physiological organic acids (e.g., glycolate, glyoxylate, oxalate, and others) at 1 to 5 mM stimulated brightness gains and pulp delignification two- to threefold compared to results for control cultures not receiving acids. The role of the organic acids in improving the manganese-independent biobleaching was shown not to be due to pH-buffering effects. Instead, the stimulation was attributed to enhanced production of manganese peroxidase (MnP) and lignin peroxidase (LiP) as well as increased physiological concentrations of veratryl alcohol and oxalate. These factors contributed to greatly improved production of superoxide anion radicals, which may have accounted for the more extensive biobleaching. Optimum biobleaching corresponded most to the production of MnP. These results suggest that MnP from Bjerkandera is purposefully produced in the absence of manganese and can possibly function independently of manganese in OKP delignification. LiP probably also contributed to OKP delignification when it was present.     

Manganese Peroxidase production by Bjerkandera sp. BOS55

The use of ligninolytic enzymes in biotechnological applications requires a highly effective production system, with sufficient amounts of the enzymes to be applied in experimental research and herein after at large-scale operations. To reach this final goal, we propose scale-up of ligninolytic production of one of the most well-known enzymes, Manganese Peroxidase (MnP), by Bjerkandera sp. BOS55. Taking into account previous results obtained in shaken flask cultures, MnP production was attempted in stirred fermenters of 2, 10 and 50 l, with levels of activity comparable to those obtained at a lower scale. Additionally, environmental factors as agitation rate, fungus immobilisation and use of buffer were evaluated to maximise MnP production. A fed-batch strategy was proved to reactivate MnP production and to maintain MnP activity for a longer period of time. Operational parameters, such as pH and Redox potential, monitored along the fermentation were found to be useful indicators of MnP production. These variables experimented drastic changes at the MnP peak production, signalling the right moment to collect the enzyme.     

Isolation and characterization of a white rot fungus <Emphasis Type="Italic">Bjerkandera</Emphasis> sp. strain capable of oxidizing phenanthrene

Strain BOL13 was selected from 18 fungal strains isolated from an oil-spill contaminated site in Oruro, Bolivia. It was identified as a basidiomycete with high homology to Bjerkandera. The fungus degraded 100 mg phenanthrene l⁻¹ at 0.17 mg l⁻¹ d⁻¹ at 30 °C at pH 7. During phenanthrene degradation, a maximum manganese peroxidase activity of 100–120 U l⁻¹ was measured after 10 days of incubation. The ability of Bjerkandera sp. to produce lignin-modifying enzymes and to oxidize phenanthrene under various pH and temperature conditions was confirmed.     

Reduction of aryl acids by white-rot fungi for the biocatalytic production of aryl aldehydes and alcohols

Ligninolytic basidiomycetes were screened for their ability to reduce aryl acids to the corresponding aldehydes and alcohols. Seven fungal strains converted p-anisic acid in high molar yields to the reduced products. The white-rot fungus Bjerkandera sp. strain BOS55 was one of the best reducing strains and was highly tolerant towards high concentrations of different aromatic acids. It was tested for the reduction of p-anisic, veratric, 3-chloro-4-methoxybenzoic, 3,5-dichloro-4-methoxybenzoic, 3,4-dichlorobenzoic, 4-fluorobenzoic, and 3-nitrobenzoic acids. All of these compounds were reduced to their corresponding aldehydes and alcohols. Received: 22 March 1999 / Received revision: 12 July 1999 / Accepted: 1 August 1999     

Decolorization and detoxification of Congo red and textile industry effluent by an isolated bacterium <Emphasis Type="Italic">Pseudomonas</Emphasis> sp. SU-EBT

The 16S rRNA sequence and biochemical characteristics revealed the isolated organism as Pseudomonas sp. SU-EBT. This strain showed 97 and 90% decolorization of a recalcitrant dye, Congo red (100 mg l⁻¹) and textile industry effluent with 50% reduction in COD within 12 and 60 h, respectively. The optimum pH and temperature for the decolorization was 8.0 and 40°C, respectively. Pseudomonas sp. SU-EBT was found to tolerate the dye concentration up to 1.0 g l⁻¹. Significant induction in the activity of intracellular laccase suggested its involvement in the decolorization of Congo red. The metabolites formed after decolorization of Congo red, such as p-dihydroxy biphenyl, 8-amino naphthol 3-sulfonic acid and 3-hydroperoxy 8-nitrosonaphthol were characterized using FTIR and GC–MS. Phytotoxicity study revealed nontoxic nature of the degradation metabolites to Sorghum bicolor, Vigna radiata, Lens culinaris and Oryza sativa plants as compared to Congo red and textile industry effluent. Pseudomonas sp. SU-EBT decolorized several individual textile dyes, dye mixtures and textile industry effluent, thus it is a useful strain for the development of effluent treatment methods in textile processing industries.     

Manganese peroxidase production by Bjerkandera sp. BOS55

The white-rot fungus Bjerkandera sp. BOS55 has been suggested as a good alternative for the production of ligninolytic enzymes, specially Manganese peroxidase (MnP), by its potential ability to degrade complex compounds. However, the application of this fungus requires the complete knowledge of the fermentation pattern in submerged cultures, conditions similar to those existing in industrial size reactors. For this purpose, the nutritional and environmental factors enabling high ligninolytic activity were studied. According to the results, under limitation and sufficiency of nitrogen, there is a threshold concentration for nitrogen from which MnP is produced. However, under nitrogen excess, the ligninolytic stage of the fungus was coincident with growth, with no apparent substrate limitation according to existing levels of carbon and nitrogen. Concerning carbon concentration, MnP synthesis took place independently of glucose concentration, this indicating that carbon limitation does not seem to be the triggering factor for MnP secretion. Other two environmental factors were studied: oxygenation and agitation, but no significant effect on MnP production was observed, a quite different aspect from the behaviour of other known fungi like Phanerochaete chrysosporium.     

Screening of tetrachlorodibenzo-<Emphasis Type="Italic">p</Emphasis>-dioxin-degrading fungi capable of producing extracellular peroxidases under various conditions

Forty-six pulp-bleaching fungi were screened for production of key enzymes for conversion of polychlorinated dibenzo-p-dioxins—lignin peroxidase (LiP), manganese peroxidase (MnP), and manganese-independent peroxidase (MiP)—under various conditions that would allow their utilization in the environment. Of 38 MnP-producing strains with MiP activity, 22 produced LiP. Three of the new isolates, Bjerkandera sp. strains MS191, MS325, and MS1167, were the best producers of the three different peroxidases, and had reasonable growth rates. The most promising Bjerkandera sp. strain, MS325, exhibited significant levels of LiP and MnP activities under various conditions, e.g., nutrient nitrogen-sufficient or -limited conditions, conditions with or without Mn(II), and changes in temperature (15–37°C). Furthermore, the ability of this strain to degrade 1,3,6,8-tetrachlorodibenzo-p-dioxin was confirmed. The results presented here indicate that utilization of Bjerkandera sp. strain MS325 on a practical scale in the environment has several advantages over many white rot fungi, which produce extracellular peroxidases only under specific conditions such as nutrient limitation.     

Bioremediation Perspective of Navy Blue Rx–Containing Textile Effluent by Bacterial Isolate

The aim of the present study was to investigate the textile effluent degrading potential of an isolated bacterium, Proteus sp. SUK7. The strain had the capacity to decolorize Navy Blue Rx–containing textile effluent up to 83% within 96 h. The maximum decolorization was observed under static conditions at pH 7.0 and 30°C. Reduction in the chemical oxygen demand (COD) and biological oxygen demand (BOD) of textile effluent was observed after treatment with Proteus sp. SUK7. Induction in the activities of laccase and aminopyrine N-demethylase was observed after decolorization, which indicates involvement of these enzymes in the decolorization process. The presence of various inducers was also found to have a modulatory effect on enzyme activities and the decolorization process. Biodegradation was confirmed using various analytical techniques, such as ultraviolet-visible (UV-Vis) spectroscopy, Fourier transform infrared (FTIR), gas chromatography–mass spectrometry (GC-MS), and high-performance liquid chromatography (HPLC). A phytotoxicity study was performed to confirm the nontoxic nature of the degradation metabolites.     

Significant reduction in toxicity,BOD, and COD of textile dyes and textile industry effluent by a novel bacterium <Emphasis Type="Italic">Pseudomonas</Emphasis> sp. LBC1

The 16S rRNA sequence analysis and biochemical characteristics were confirmed that the isolated bacterium is Pseudomonas sp. LBC1. The commonly used textile dye, Direct Brown MR has been used to study the fate of biodegradation. Pseudomonas sp. LBC1 showed 90% decolorization of Direct Brown MR (100 mg/L) and textile industry effluent with significant reduction in COD and BOD. The optimum condition for decolorization was 7.0 pH and 40°C. Significant increase in a activity of extracellular laccase suggested their possible involvement in decolorization of Direct Brown MR. Biodegradation metabolites viz. 3,6-dihydroxy benzoic acid, 2-hydroxy-7-aminonaphthol-3-sulfonic acid, and p-dihydroperoxybenzene were identified on the basis of mass spectra and using the 1.10 beta Shimadzu NIST GC–MS library. The Direct Brown MR and textile industry effluent were toxic to Sorghum bicolor and Vigna radiata plants as compared to metabolites obtained after decolorization. The Pseudomonas sp. LBC1 could be useful strain for decolorization and detoxification of textile dyes as well as textile industry effluent.     

Complete decolorization of the anthraquinone dye Reactive blue 5 by the concerted action of two peroxidases from Thanatephorus cucumeris Dec 1

It is useful to identify and examine organisms that may prove useful for the treatment of dye-contaminated wastewater. Here, we report the purification and characterization of a new versatile peroxidase (VP) from the decolorizing microbe, Thanatephorus cucumeris Dec 1 (TcVP1). The purified TcVP1 after Mono P column chromatography showed a single band at 43 kDa on sodium dodecyl sulfate–polyacrylamide gel electrophoresis. Amino acid sequencing revealed that the N terminus of TcVP1 had the highest homology to Trametes versicolor MPG1, lignin peroxidase G (LiPG) IV, Bjerkandera adusta manganese peroxidase 1 (MnP1), and Bjerkandera sp. RBP (12 out of 14 amino acid residues, 86% identity). Mn²⁺ oxidizing assay revealed that TcVP1 acted like a classical MnP at pH ∼5, while dye-decolorizing and oxidation assays of aromatic compounds revealed that the enzyme acted like a LiP at pH ∼3. TcVP1 showed particularly high decolorizing activity toward azo dyes. Furthermore, coapplication of TcVP1 and the dye-decolorizing peroxidase (DyP) from T. cucumeris Dec 1 was able to completely decolorize a representative anthraquinone dye, Reactive blue 5, in vitro. This decolorization proceeded sequentially; DyP decolorized Reactive blue 5 to light red-brown compounds, and then TcVP1 decolorized these colored intermediates to colorless. Following extended reactions, the absorbance corresponding to the conjugated double bond from phenyl (250–300 nm) decreased, indicating that aromatic rings were also degraded. These findings provide important new insights into microbial decolorizing mechanisms and may facilitate the future development of treatment strategies for dye wastewater.     

Biodegradation of disperse dye brown 3REL by microbial consortium of Galactomyces geotrichum MTCC 1360 and Bacillus sp. VUS

The consortium-GB (Galactomyces geotrichum MTCC 1360 and Bacillus sp. VUS) exhibited 100% decolorization ability with the dye Brown 3REL within 2 h at shaking condition with optima of pH 7 and at 50°C. However, G. geotrichum MTCC 1360 showed 39% decolorization within 24 h and Bacillus sp. VUS took 5 h for 100% decolorization, when incubated individually. Additional carbon and nitrogen sources like, starch, peptone, and urea were found to enhance decolorization. Induction in lignin peroxidase, tyrosinase, and riboflavin reductase was observed in consortium as that of individual organisms. GCMS identification showed different metabolites formed using consortium (2-(6,8-dichloro-quinazolin-4yloxy)-acetyl-urea and 2-(6,8-dichloro-quinazolin-4yloxy)-acetyl-formamide) and Bacillus sp. VUS (6,8-dichloro-4 methoxy-quinazoline) after 2 h of incubation with Brown 3REL. G. geotrichum MTCC 1360 showed minor modifications in structure of Brown 3REL. Phytotoxicity revealed non toxic nature of metabolites. This consortium-GB was also able to decolorize various industrial dyes.