Characterization of a Yellow Laccase from Botrytis cinerea 241

Radveikienė, Ingrida; Vidžiūnaitė, Regina; Meškienė, Rita; Meškys, Rolandas; Časaitė, Vida

doi:10.3390/jof7020143

Cited by 13 publications

(7 citation statements)

References 71 publications

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“…GluLac and TmtLac optimal temperature was similar to reported ones (do Rosário Freixo et al, 2012;Radveikien ė et al, 2021). Some laccases showed higher optimal temperatures up to 80 • C from strains of T. versicolor (Freixo et al, 2008b) and T. oriantalis (Zheng et al, 2017).…”

Section: Crude Glulacsupporting

confidence: 86%

“…AA. Leontievsky et al, 1997) but many other theories have been proposed afterwards, to understand the mechanism monitoring the shifting of the blue laccase to yellow one, including changes in oxidation level (Radveikien ė et al, 2021), structural sphere (Mate et al, 2013), glycosylation state (Mot ¸ et al, 2012), and interaction with metal ions (Radveikien ė et al, 2021). The evidence to be sought from an industrial standpoint will be whether the difference in color of the yellow laccase produced on lignocellulosic waste has an impact on its catalytic activity.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Yellow laccase produced by Trametes versicolor K1 on tomato waste: A comparative study with the blue one produced on semi-synthetic medium

Chaoua

Chaouche

Songulashvili

et al. 2023

Journal of Biotechnology

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Section: Crude Glulacsupporting

confidence: 86%

Section: Introductionmentioning

confidence: 99%

Yellow laccase produced by Trametes versicolor K1 on tomato waste: A comparative study with the blue one produced on semi-synthetic medium

Chaoua

Chaouche

Songulashvili

et al. 2023

Journal of Biotechnology

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“…In general, a typical laccase molecule contains four copper atoms with three types of copper sites (T1, T2, and T3), both type I and type III copper ions have the characteristic absorption in the UV–vis spectrum except for type II (Dwivedi et al 2011 ; Rivera-Hoyos et al 2013 ). Herein, the absorption peak at 610 nm represents the T1 copper site of typical blue laccase, while the shoulder around 330 nm represents the T3 copper site of laccase (Radveikienė et al 2021 ). The UV–vis spectrum of CGLac performed a characteristic absorption peak of protein near 280 nm, but no peak near 610 nm and 330 nm (Fig.…”

Section: Resultsmentioning

confidence: 99%

“…In addition, the types of laccases probably relate to strains and growth conditions. Radveikienė et al ( 2021 ) reported Botrytis cinerea 241 secreted two different laccases (blue and yellow laccases) depending on the cultivation conditions. They found the medium with lower copper concentration was more efficient for yellow laccase production.…”

Section: Discussionmentioning

confidence: 99%

Green production of a yellow laccase by Coriolopsis gallica for phenolic pollutants removal

Cen

Cao

et al. 2022

AMB Expr

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As a group of green biocatalysts, fungal laccases have aroused great interest in diverse biotechnological fields. Therein, yellow laccase has advantages over blue laccase in catalytic performance, but it is not common in the reported fungal laccases. Here, we report a yellow laccase from white-rot fungus Coriolopsis gallica NCULAC F1 about its production, purification, characterization, and application. Laccase production in the co-fermentation of pomelo peel and wheat bran reached the enzyme activity by 10,690 U/L after 5 days with a 13.58-time increase. After three steps of purification, laccase increased the specific activity from 30.78 to 188.79 U/mg protein with an activity recovery of 45.64%. The purified C. gallica laccase (CGLac) showed a molecular mass of about 57 kDa. CGLac had a yellow color and no absorption peaks at 610 nm and 330 nm, suggesting that it’s a yellow laccase. CGLac exhibited stability towards temperature (40–60 °C) and neutral pH (6.0–8.0). Fe3+ and Mn2+ strongly stimulated CGLac activity by 162.56% and 226.05%, respectively. CGLac remained high activities when exposed to organic reagents and putative inhibitors. Additionally, CGLac contributed to 90.78%, 93.26%, and 99.66% removal of phenol, p-chlorophenol and bisphenol A after 120 min, respectively. In conclusion, a green efficient production strategy was introduced for fungal laccase, and the obtained CGLac presented great enzymatic properties and catalytic potential in the removal of phenolic pollutants.

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“…The absorption of the T1 site at 605 nm (in the Lac from Trametes versicolor ) is the cause of the blue color of Lac [ 8 ]. However, some laccases with an altered catalytic site structure may appear “yellow“ or “white“ [ 8 , 9 , 10 ]. We refer to previous studies [ 1 , 7 , 8 , 11 , 12 ] for an explanation of the catalytic mechanism and the structure-activity relationships in Lacs.…”

Section: Introductionmentioning

confidence: 99%

Laccases and Tyrosinases in Organic Synthesis

Martı́nková

Křístková

Křen

2022

IJMS

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Laccases (Lac) and tyrosinases (TYR) are mild oxidants with a great potential in research and industry. In this work, we review recent advances in their use in organic synthesis. We summarize recent examples of Lac-catalyzed oxidation, homocoupling and heterocoupling, and TYR-catalyzed ortho-hydroxylation of phenols. We highlight the combination of Lac and TYR with other enzymes or chemical catalysts. We also point out the biological and pharmaceutical potential of the products, such as dimers of piceid, lignols, isorhamnetin, rutin, caffeic acid, 4-hydroxychalcones, thiols, hybrid antibiotics, benzimidazoles, benzothiazoles, pyrimidine derivatives, hydroxytyrosols, alkylcatechols, halocatechols, or dihydrocaffeoyl esters, etc. These products include radical scavengers; antibacterial, antiviral, and antitumor compounds; and building blocks for bioactive compounds and drugs. We summarize the available enzyme sources and discuss the scalability of their use in organic synthesis. In conclusion, we assume that the intensive use of laccases and tyrosinases in organic synthesis will yield new bioactive compounds and, in the long-term, reduce the environmental impact of industrial organic chemistry.

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Characterization of a Yellow Laccase from Botrytis cinerea 241

Cited by 13 publications

References 71 publications

Yellow laccase produced by Trametes versicolor K1 on tomato waste: A comparative study with the blue one produced on semi-synthetic medium

Yellow laccase produced by Trametes versicolor K1 on tomato waste: A comparative study with the blue one produced on semi-synthetic medium

Green production of a yellow laccase by Coriolopsis gallica for phenolic pollutants removal

Laccases and Tyrosinases in Organic Synthesis

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