Importance of Mediators for Lignin Degradation by Fungal Laccase

Longe, Lionel; Couvreur, Julien; Grandchamp, Mathilde Leriche; Garnier, Gil; Allais, Florent; Saito, Kei

doi:10.1021/acssuschemeng.8b01426

Cited by 86 publications

(56 citation statements)

References 59 publications

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“…T. versicolor (or turkey tail, in layman terms) is a Basidiomycetes that grows on rotting wood; it employs laccase to degrade lignin to adhere to the wood and scavenge it for nutrients. Therefore, laccase activity is central to its ecological role, and it is reasonable to assume that it has undergone a constant selective pressure to refine its interaction with lignin, an interaction often mediated by accessory interactors [27]. The progressive evolution of a lignin degrading, laccase-based enzymatic system has led to an active site of the highest redox potential among multi-copper oxidases, which is a good asset to degrade the aromatic moieties of aflatoxins.…”

Section: Discussionmentioning

confidence: 99%

“…To calculate the binding site, we performed KS-DFT calculations on the docked enzyme-toxin system using the linear scaling mode of the BigDFT code [27], [28] with the PBE approximation, HGH pseudopotentials, and a grid spacing of 0.4 atomic units. The charge of the enzyme was determined by minimizing the energy of the gas phase enzyme with respect to the number of electrons.…”

Section: Docking Of Afs Withmentioning

confidence: 99%

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Full quantum mechanical modeling of the enzyme-substrate system: how laccase detoxifies aflatoxin

Zaccaria

Dawson

Kish

et al. 2020

Preprint

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This work focuses on: 1) the development of a methodology to perform a full Quantum Mechanics (QM) characterization of enzymatic activity; 2) the development of a rational approach to laccase engineering as a food bioremediator. Aflatoxins are among the most dangerous natural carcinogens, and regularly contaminate reserves of staple crops worldwide. Decontamination of aflatoxin-polluted food is of great interest for ensuring food safety, and bioremediation is regarded as the most promising solution. The fungal isoforms of laccase display the rare potential to detoxify aflatoxin by tackling its aromatic moieties.. Yet, because of a generally low efficiency, large-scale application of naturally occurring isoforms has so far been unfeasible. We perform a combination of quantitative experimentation and quantum mechanical modeling on aflatoxin and reveal that:(1) detoxification efficiency is limited by the low enzymatic affinity for the substrate; and (2) aflatoxin is not detoxified by oxidative activity of laccase alone, but requires additional stimulation from the environment. QM modeling also allowed identification of the residues in the laccase tertiary structure that determine affinity of the enzymatic pocket for aflatoxin. We conclude that, for our case-study, a full QM approach is mandatory as a first step towards rational optimization. We detail a feasible approach towards this endeavor and argue that our full QM characterization can serve as a roadmap for enzyme development in other applications pertaining laccase as well as other enzymes.

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Section: Discussionmentioning

confidence: 99%

Section: Docking Of Afs Withmentioning

confidence: 99%

Full quantum mechanical modeling of the enzyme-substrate system: how laccase detoxifies aflatoxin

Zaccaria

Dawson

Kish

et al. 2020

Preprint

View full text Add to dashboard Cite

show abstract

“…A wide array of compounds has been used in the literature as mediators, such as 2,2,6,6-tetramethyl-1-piperidinyloxy (TEMPO), ABTS ( [14], 1-hydroxybenzotriazole (1-HBT) [38], syringaldehyde, vanillin, α-naphthol [39], and others. The laccase-mediator system (LMS) has been used for the removal of residual lignin in biomass [13,40], or the treatment of recalcitrant pollutants, such as antibiotics [39] or other drugs [41], pesticides [42], industrial textile wastewater [43], and even synthetic fragrances [44]. LMS has been also used for the oxidative synthesis of platform chemicals [45].…”

Section: Structural Aspects Mode Of Action and Redox Properties Of mentioning

confidence: 99%

“…Extensive literature is available on laccases from basidiomycetes, especially white-rot fungi [12], while some laccases have also been characterized from ascomycete saprotrophs and ectomycorrhizal species. Many studies focus on lignin degradation and wood modification by laccases, with or without the use of mediators [13][14][15], and as a result, laccases are now considered essential enzymes in fungal lignocellulose degradation.Most bacterial laccases are active in a wide range of temperatures and pH values (30-85 • C and 3.0-9.0, respectively) [16], but the most extremophilic laccases found so far are of bacterial origin,…”

mentioning

confidence: 99%

Applications of Microbial Laccases: Patent Review of the Past Decade (2009–2019)

et al. 2019

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There is a high number of well characterized, commercially available laccases with different redox potentials and low substrate specificity, which in turn makes them attractive for a vast array of biotechnological applications. Laccases operate as batteries, storing electrons from individual substrate oxidation reactions to reduce molecular oxygen, releasing water as the only by-product. Due to society’s increasing environmental awareness and the global intensification of bio-based economies, the biotechnological industry is also expanding. Enzymes such as laccases are seen as a better alternative for use in the wood, paper, textile, and food industries, and they are being applied as biocatalysts, biosensors, and biofuel cells. Almost 140 years from the first description of laccase, industrial implementations of these enzymes still remain scarce in comparison to their potential, which is mostly due to high production costs and the limited control of the enzymatic reaction side product(s). This review summarizes the laccase applications in the last decade, focusing on the published patents during this period.

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“…In particular, laccase ability to break aromatic moieties makes it promising against the most recalcitrant hydrocarbons. On laccase and its potential applications, existing work [48,[57][58][59][60][61] can be used as a solid ground for further developments.…”

Section: Box 2 Laccase: a Multicopper Oxidase As The Ideal Training mentioning

confidence: 99%

Designing a bioremediator: mechanistic models guide cellular and molecular specialization

Zaccaria

Dawson

Cristiglio

et al. 2019

Preprint

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Rational, mechanistic design can substantially improve the performance of bioremediators for applications including waste treatment and food safety. We highlight how such improvement can be informed at the cellular level by theoretical observations especially in the context of phenotype plasticity, cell signaling, and community assembly. At the molecular level, we suggest enzyme design using techniques such as Small Angle Neutron Scattering and Density Functional Theory. To provide an example of how these techniques could be synergistically combined, we present the case-study of the interaction of the enzyme laccase with the food pollutant aflatoxin B1. In designing bioremediators, we encourage interdisciplinary, mechanistic research to transition from an observation-oriented approach to a principle-based one.

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Importance of Mediators for Lignin Degradation by Fungal Laccase

Cited by 86 publications

References 59 publications

Full quantum mechanical modeling of the enzyme-substrate system: how laccase detoxifies aflatoxin

Full quantum mechanical modeling of the enzyme-substrate system: how laccase detoxifies aflatoxin

Applications of Microbial Laccases: Patent Review of the Past Decade (2009–2019)

Designing a bioremediator: mechanistic models guide cellular and molecular specialization

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