Functional And Structural Analysis Of Catalase-phenol Oxidase From Scytalidium Thermophilum

Yuzugullu, Yonca

01 February 2010

Scytalidium thermophilum produces a novel phenol oxidase, which has turned out to be a bifunctional catalase-phenol oxidase (CATPO) during the course of this work, by other researchers of our group. Therefore, in the beginning of the studies, substrate specificity and inhibitor assays were conducted on the crude enzyme, followed by production, purification, cloning, expression, and mutagenesis and crystallography studies for further functional and structural analysis of CATPO. Accordingly, substrate specificity and inhibitory tests applied for crude enzyme characterisation presented the similarity of the phenol oxidase nature of CATPO essentially to catechol oxidase. Production studies were performed to investigate the effects of different factors including induction time, growth temperature, exogenous iron and hydrogen peroxide addition. In view of that, CATPO is constitutively produced in a growth associated manner. However, some phenolic compounds enhance its production. In this study, 15 phenolic compounds were tested for their ability to affect CATPO production. Of the phenolic compounds tested, catechol, resorcinol and vanillic acid caused repression of CATPO production. On the other hand, caffeic acid, myricetin and resveratrol enhanced CATPO production. As a biocatalyst, the efficiency of CATPO was examined and found to be a good candidate for getting pharmaceutically important drug intermediates. Its dual mechanism was analysed through side-directed mutagenesis. Two conserved residues (His101 and Val142) were mutated to discriminate catalase and phenol oxidase activities. Spectroscopic and mutagenesis studies exhibited the presence of heme d centre. Lastly, its structure was analysed by X-ray crystallography and found to have a tetrameric structure.

QH General Biology 301-705

Analysis Of Phenol Oxidation Products By Scytalidium Thermophilum Bifunctional Catalase/phenol Oxidase (catpo)

Avci, Gulden

01 June 2011

This thesis was aimed to analyze phenol oxidation by the bifunctional catalase/phenol oxidase of the thermophilic fungus Scytalidium thermophilum. Several reactive oxygen species (ROS) are continuously produced in fungi under oxidative stress. Depending on the nature of the ROS species, some are highly toxic and are rapidly detoxified by various cellular enzymatic mechanisms, including the production of catalase. S. thermophilum produces a novel bifunctional catalase-phenol oxidase (CATPO) which is capable of oxidizing phenolics in the absence of hydrogen peroxide. Phenol oxidases convert phenolic compounds to quinones, which are then polymerized mainly by free- radical mediated reactions. In this study, 14 phenolic compounds were selected according to their different chemical structures and functional properties and were analyzed as substrates of CATPO. Among 14 phenolic compounds, only in catechol, chlorogenic acid, catechin and caffeic acid distinct oxidation products were observed by HPLC. The oxidation products of catechol, caffeic acid, chlorogenic acid and catechin were characterized by LC-ESI-MS. Dimer, trimer, tetramer and oligomer formations were detected. While the maximum conversion efficiency, at 1 hour of reaction, was observed with catechin, minimum conversion efficiency was attained by caffeic acid, under the specified conditions. The oxidation products observed after oxidation of catechol, chlorogenic acid, catechin and caffeic acid by CATPO was compared with the same phenolic compounds oxidation products oxidized by laccase and tyrosinase. CATPO was incapable of oxidizing tyrosinase and laccase-specific substrates tyrosine and ABTS respectively. However, the oxidizing spectrum of substrates indicates that the nature of phenol oxidation by CATPO appears to resemble mainly those of laccase.

QH General Biology 301-705

Utilization Of Scytalidium Thermophilum Phenol Oxidase In Bioorganic Synthesis

Kaptan, Yelda

01 September 2004

ABSTRACT UTILIZATION OF SCYTALIDIUM THERMOPHILUM PHENOL OXIDASE IN BIOORGANIC SYNTHESES Kaptan, Yelda M.S., Department of Biotechnology Supervisor: Prof. Dr. Z&uuml / mr&uuml / t B. &Ouml / gel Co-supervisor: Prof Dr. Ufuk Bakir September 2004, 90 pages In this study, the ultimate aim was to utilize phenol oxidases of Scytalidium thermophilum in bioorganic syntheses. For this purpose, studies were conducted towards enhancing the production of phenol oxidases by Scytalidium thermophilum, developing a suitable method for laccase activity assays, analyzing the effects of organic solvents on phenol oxidase activity and analysis of the biotransformation of a number of organic substrates by phenol oxidases of Scytalidium thermophilum. In order to enhance the production of phenol oxidases, induction experiments were carried out with gallic acid, syringaldazine and chlorogenic acid. Gallic acid was found as the most effective inducer for phenol oxidase production. Inductive effect of edible mushroom Agaricus bisporus was also assayed, however, the phenolic compounds released by mushroom did not represent any induction for phenol oxidase activity of Scytalidium thermophilum. Different substrates were tested and catechol was determined as the most suitable substrate rather than syringaldazine and ABTS. Molar extinction coefficient (e) of catechol was calculated as 3450 M-1 cm-1 and 3700 M-1 cm-1 by using &ldquo / substrate blank&rdquo / and &ldquo / enzyme blank&rdquo / respectively at 420 nm. Kinetic parameters, Km and Vmax for the enzymatic reactions in which catechol was used as substrate were calculated as 52.03 mM and 0.253 U/ml respectively from Lineweaver-Burk plot and as 41.25 mM and 0.2055 U/ml from Hanes-Woolf plot. Effect of some organic solvents on phenol oxidases of Scytalidium thermophilum was assayed and DMSO was found as an appropriate solvent for the organic substrates. Phenol oxidase containing culture supernatant could oxidize benzoin, hydrobenzoin and benzoyl benzoin.

QD Biochemistry 415-436

Fungal Pigment Formation in Wood Substrate

Tudor, Daniela

14 January 2014

A number of fungi produce spalted wood, which is characterized by accumulation of black pigment in fine demarcation lines, often accompanied by discoloration or staining on the wood fibers. Specific spalting fungi were identified by molecular analysis. From a total of 19 isolates and 140 clones studied, 11 fungal species were identified. The two Chlorociboria species from North America were investigated and their anamorphs were unambiguously identified for the first time. Fungal pigment formation under the influence of moisture content and pH variation was investigated in sugar maple, American beech and agar inoculated with spalting fungi. Maximum pigment production occurred at treatment with pH 4.5 for sugar maple and beech inoculated with Trametes versicolor. Xylaria polymorpha produced external pigmentation in beech treated with buffer at pH 5 and sugar maple at pH 4.5. Fungal pigmentation by Trametes versicolor and Xylaria polymorpha was stimulated at low moisture content in both wood species tested. Melanin production by Inonotus hispidus and Polyporus squamosus was stimulated above 22-28% and 34-38% moisture content in beech and in sugar maple respectively. Fomes fomentarius and Polyporus brumalis produced maximum pigmentation in beech at 26 - 41% and in sugar maple at 59 - 96% moisture content. The variation of the moisture content and pH values of wood substrates can stimulate the intensity of pigmentation of specific fungi in wood. To investigate melanin synthesis from a variety of melanin precursors, experimental research on three spalting fungi tested their reaction to catechol and L-Dopa melanin precursors in wood and agar substrate. The results indicate multiple biosynthesis pathways for melanin assembly in Trametes versicolor, Xylaria polymorha and Inonotus hispidus, and catechol produced most pigmentation in all spalting fungi investigated. Microscopic analysis by light, fluorescence, electron and confocal microscopy also indicates a bi- or multi-modal activity of melanin production and assembly by several spalting fungi. Possible variations of melanin assembly were identified based on fungal and wood species. Immunofluorescence and immunogold labelling with Mab 6D2 melanin antibody confirmed the melanin nature of the pigments produced by Oxyporus populinus, Trametes versicolor, Xylaria polymorpha, Fomes fomentarius, and Inonotus hispidus.

spalting

wood degradation

staining fungi

white rot fungi

fungal melanin

fungal pigment

Trametes versicolor

Xylaria plymorpha

Chlorociboria

Scytalidium cuboideum

Wood technology 0746

Microbiology 0410

Fungal Pigment Formation in Wood Substrate

Tudor, Daniela

14 January 2014

A number of fungi produce spalted wood, which is characterized by accumulation of black pigment in fine demarcation lines, often accompanied by discoloration or staining on the wood fibers. Specific spalting fungi were identified by molecular analysis. From a total of 19 isolates and 140 clones studied, 11 fungal species were identified. The two Chlorociboria species from North America were investigated and their anamorphs were unambiguously identified for the first time. Fungal pigment formation under the influence of moisture content and pH variation was investigated in sugar maple, American beech and agar inoculated with spalting fungi. Maximum pigment production occurred at treatment with pH 4.5 for sugar maple and beech inoculated with Trametes versicolor. Xylaria polymorpha produced external pigmentation in beech treated with buffer at pH 5 and sugar maple at pH 4.5. Fungal pigmentation by Trametes versicolor and Xylaria polymorpha was stimulated at low moisture content in both wood species tested. Melanin production by Inonotus hispidus and Polyporus squamosus was stimulated above 22-28% and 34-38% moisture content in beech and in sugar maple respectively. Fomes fomentarius and Polyporus brumalis produced maximum pigmentation in beech at 26 - 41% and in sugar maple at 59 - 96% moisture content. The variation of the moisture content and pH values of wood substrates can stimulate the intensity of pigmentation of specific fungi in wood. To investigate melanin synthesis from a variety of melanin precursors, experimental research on three spalting fungi tested their reaction to catechol and L-Dopa melanin precursors in wood and agar substrate. The results indicate multiple biosynthesis pathways for melanin assembly in Trametes versicolor, Xylaria polymorha and Inonotus hispidus, and catechol produced most pigmentation in all spalting fungi investigated. Microscopic analysis by light, fluorescence, electron and confocal microscopy also indicates a bi- or multi-modal activity of melanin production and assembly by several spalting fungi. Possible variations of melanin assembly were identified based on fungal and wood species. Immunofluorescence and immunogold labelling with Mab 6D2 melanin antibody confirmed the melanin nature of the pigments produced by Oxyporus populinus, Trametes versicolor, Xylaria polymorpha, Fomes fomentarius, and Inonotus hispidus.

spalting

wood degradation

staining fungi

white rot fungi

fungal melanin

fungal pigment

Trametes versicolor

Xylaria plymorpha

Chlorociboria

Scytalidium cuboideum

Wood technology 0746

Microbiology 0410