Thermotolerant and thermostable laccases

Hildén, Kristiina; Hakala, Tapio; Lundell, Taina

doi:10.1007/s10529-009-9998-0

Cited by 185 publications

(129 citation statements)

References 94 publications

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“…The role of lignin-degrading enzymes in the treatment of contaminated effluent is also established, however their utilization demands a thorough understanding of lignin degrading organisms and their enzyme systems. Although oxidative enzymes produced by fungi are also used for the degradation of azo dyes, bacterial enzymes generally have greater heat stability and broader substrate specificity (Hilden et al, 2009;Lee et al, 2003;Reiss et al, 2011). Moreover, these can be produced in a short time, operating in aqueous solvent at neutral to basic pH (Wells et al, 2006), which is a common pH of real dyecontaminated textile wastewater.…”

Section: Oxidative Enzymesmentioning

confidence: 99%

“…Our review of the literature suggests that there has not yet been serious work aimed at the treatment of azo dyes using immobilized azoreductases. Some researchers reported decolorization of azo dyes using immobilized or spore-bound bacterial laccases (Held et al, 2005;Hilden et al, 2009). The crude enzyme mixture containing hydrolase was selfsustaining and the respective reaction occurred without any necessary cofactors.…”

Section: Enzyme Technology: Some Practical Considerationsmentioning

confidence: 99%

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Bacterial diversity and composition in major fresh produce growing soils affected by physiochemical properties and geographic locations

Ibekwe

Yang

et al. 2016

Science of The Total Environment

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Azo dyes and their intermediate degradation products are common contaminants of soil and groundwater in developing countries where textile and leather dye products are produced. The toxicity of azo dyes is primarily associated with their molecular structure, substitution groups and reactivity. To avoid contamination of natural resources and to minimize risk to human health, this wastewater requires treatment in an environmentally safe manner. This manuscript critically reviews biological treatment systems and the role of bacterial reductive and oxidative enzymes/processes in the bioremediation of dye-polluted wastewaters. Many studies have shown that a variety of culturable bacteria have efficient enzymatic systems that can carry out complete mineralization of dye chemicals and their metabolites (aromatic compounds) over a wide range of environmental conditions. Complete mineralization of azo dyes generally involves a two-step process requiring initial anaerobic treatment for decolorization, followed by an oxidative process that results in degradation of the toxic intermediates that are formed during the first step. Molecular studies have revealed that the first reductive process can be carried out by two classes of enzymes involving flavin-dependent and flavin-free azoreductases under anaerobic or low oxygen conditions. The second step that is carried out by oxidative enzymes that primarily involves broad specificity peroxidases, laccases and tyrosinases. This review focuses, in particular, on the characterization of these enzymes with respect to their enzyme kinetics and the environmental conditions that are necessary for bioreactor systems to treat azo dyes contained in wastewater.

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Section: Oxidative Enzymesmentioning

confidence: 99%

Section: Enzyme Technology: Some Practical Considerationsmentioning

confidence: 99%

Bacterial diversity and composition in major fresh produce growing soils affected by physiochemical properties and geographic locations

Ibekwe

Yang

et al. 2016

Science of The Total Environment

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“…88 Dentre as enzimas oxidativas, as lacases têm se aproximado rapidamente da aplicação comercial nos processos de biobranqueamento de pastas celulósicas, enquanto as MnPs ainda apresentam restrições devido à limitada capacidade de se produzir a enzima em escala comercial a preços baixos. 9,[89][90][91] O biobranqueamento com lacases está baseado na habilidade dessa enzima em oxidar alguns mediadores que, por sua vez, atuam como agentes oxidantes da lignina residual presente nas polpas celulósicas. A lignina oxidada é então removida por um processo de extração alcalina.…”

Section: Degradação De Materiais Lignocelulósicos Por Enzimas Sistemunclassified

Mecanismos envolvidos na biodegradação de materiais lignocelulósicos e aplicações tecnológicas correlatas

Aguiar¹,

Ferraz²

2011

Quím. Nova

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Recebido em 9/11/10; aceito em 21/6/11; publicado na web em 8/8/11MECHANISMS INVOLVED IN THE BIODEGRADATION OF LIGNOCELLULOSIC MATERIALS AND RELATED TECHNOLOGICAL APPLICATIONS. The biodegradation of lignocellulosic materials is an important natural process because it is responsible for the carbon recycling. When induced under controlled conditions, this process can be used for technological applications such as biopulping, biobleaching of cellulosic pulps, pre-treatment for subsequent saccharification and cellulosic-ethanol production, and increase of the digestibility in agroindustrial residues used for animal feed. In the present work, the enzymatic and non-enzymatic mechanisms involved in the biodegradation of lignocellulosic materials by fungi were reviewed. Furthermore, the technological applications of these extracellular metabolites are presented and discussed.Keywords: wood biodegradation; oxidative enzymes; Fenton reaction. INTRODUÇÃOA biodegradação dos materiais lignocelulósicos tem sido objeto de muitos estudos, pois, além de corresponder a uma importante etapa do ciclo do carbono na natureza, também pode ser aplicada em processos tecnológicos. As aplicações em questão são variadas e incluem desde a ação direta de fungos sobre a madeira, desenhada como uma etapa de pré-tratamento aos processos de fabricação de celulose e papel, 1,2 até processos que usam os fungos decompositores de materiais lignocelulósicos como agentes indutores da degradação de compostos xenobióticos, quer em solos contaminados 3 ou em efluentes industriais. 4 O pré-tratamento de materiais lignocelulósicos com fungos também tem sido apontado como uma forma de facilitar processos subsequentes de conversão da celulose em açúcares fermentescíveis destinados à bioconversão em etanol e outros produtos de interesse comercial. 5,6 Também na área de nutrição animal, a aplicação de fungos decompositores de materiais lignocelulósicos tem sido descrita. Nesse caso, o pré-tratamento biológico é usado para aumentar a digestibilidade de resíduos agroindustriais utilizados na alimentação de ruminantes e não ruminantes. Os fungos, principalmente os causadores de podridão branca seletivos na degradação de lignina, desestruturam a parede celular vegetal, promovendo a conversão dos polissacarídeos em açúcares de fácil assimilação. Além disso, a biomassa fúngica que se desenvolve sobre o lignocelulósico pode servir como fonte de proteína. 7 A aplicação de enzimas produzidas pelos fungos decompositores de materiais lignocelulósicos também tem ganhado muito interesse na atualidade. O uso de xilanases 8 e lacases 9,10 em processos de branqueamento de polpas celulósicas e a aplicação de celulases na hidrólise enzimática de celulose nos processos de produção de etanol de segunda geração, 11 são exemplos de como o avanço no entendimento da biodegradação dos lignocelulósicos tem permitido explorar aplicações tecnológicas de grande relevância para o mundo moderno.O desenvolvimento das aplicações mencionadas anteriormente tem ocorrido de forma simultânea à ger...

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“…15 The plots of v 0 (initial rate) vs. pH (Figure 9 for complex 1, and S2 for complex 2) show sigmoid-shape profiles and reveal pK a values of 9…”

mentioning

confidence: 94%

“…14 Considering the high academic and industrial interest on these enzyme systems, and that their use is sometimes limited mainly because of the optimal pH and temperature ranges, 15 model complexes are considered as an alternative. Because of this, several compounds have been synthesized, characterized and tested as catalysts for oxidative processes involving molecular oxygen and hydrogen peroxide.…”

Section: Introductionmentioning

confidence: 99%

Binuclear CuII complexes as catalysts for hydrocarbon and catechol oxidation reactions with hydrogen peroxide and molecular oxygen

Martins¹,

Souza²,

Fernandez³

et al. 2010

J. Braz. Chem. Soc.

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Dois ligantes tridentados, HL1, [(2-hidroxibenzil)(2-(imidazol-2-il)etil)]amina, e HL2, [(2-hidroxibenzil)(2-(piridil-2-il)etil]amina, foram usados na síntese dos complexos binucleares [Cu 2 (L1) 2 ]Cl 2• 2H 2 O, complexo 1, e [Cu 2 (L2) 2 ] (ClO 4 ) 2• 1.5H 2 O, complexo 2, para serem empregados como catalisadores em processos de oxidação. Os complexos foram caracterizados por análise elementar e espectroscopias na região do infravermelho, ultravioleta-visível e ressonância paramagnética eletrônica. Foram também estudados por voltametria cíclica e titulação potenciométrica, a fim de caracterizar seus comportamentos em solução. A resolução da estrutura cristalina do complexo 1 mostrou um cátion binuclear contendo dois grupos fenóxido em ponte. Este arranjo possui uma distância Cu … Cu de 3.043(10) Å, similar à observada na catecol oxidase (2.90 Å). Os comportamentos catalíticos destes complexos foram investigados nas oxidações de cicloexano e de catecol. Na oxidação de cicloexano observou-se baixa atividade para ambos os complexos, que pode ser atribuída ao estereoimpedimento produzido pela falta de coplanaridade entre os anéis aromáticos do arcabouço dos ligantes, sugerindo que a aproximação entre o substrato e o centro ativo binuclear é uma etapa determinante no mecanismo da reação. Com relação à atividade de catecolase, foram observadas altas eficiências, com o complexo 2 sendo mais ativo que o complexo 1. Isto indica que o ligante piridina é capaz de estabilizar melhor o intermediário proposto para esse processo, que contém o centro Cu • 1.5H 2 O, complex 2, in order to obtain catalysts for oxidative processes. Both complexes were characterized by elemental analysis, IR, UV-Vis and EPR spectroscopies. In addition, they were studied by cyclic voltammetry and potentiometric titration in order to investigate their behavior in solution. The crystal structure of complex 1 revealed a binuclear cation where the metal centers are bridged by two phenoxo groups. This arrangement provides a Cu … Cu distance of 3.043(10) Å, which is similar to the observed for catechol oxidase (2.90 Å). The catalytic reactivities of both complexes were investigated for hydrocarbon and catechol oxidations. Complexes 1 and 2 led to low overall hydrocarbon oxidation conversion values of 6.34 % and 7.15 %, respectively. However, for complex 1, only cyclohexanol (Cy-OH) and cyclohexanone (Cy=O) were isolated as reaction products, with selectivities of 68.1% for Cy-OH. This low overall conversion is tentatively attributed to steric hindrance effects produced by the non-coplanar aromatic rings of the ligand scaffolds, which suggest that the access of the hydrocarbon molecule to the binuclear active center is a determinant step in the reaction mechanism. Investigation of catecholase activities has shown high efficiencies, with complex 2 being more active than complex 1. It indicates that the pyridine-containing ligand is able to stabilize the intermediate Cu I Cu I center which is proposed to be formed in this process. This is corroborated by t...

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Thermotolerant and thermostable laccases

Cited by 185 publications

References 94 publications

Bacterial diversity and composition in major fresh produce growing soils affected by physiochemical properties and geographic locations

Bacterial diversity and composition in major fresh produce growing soils affected by physiochemical properties and geographic locations

Mecanismos envolvidos na biodegradação de materiais lignocelulósicos e aplicações tecnológicas correlatas

Binuclear CuII complexes as catalysts for hydrocarbon and catechol oxidation reactions with hydrogen peroxide and molecular oxygen

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