Immobilizing white‐rot fungi laccase: Toward bio‐derived supports as a circular economy approach in organochlorine removal

Serbent, Maria Pilar; Magario, Ivana; Saux, Clara

doi:10.1002/bit.28591

Biotech & Bioengineering

2023

DOI: 10.1002/bit.28591

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Immobilizing white‐rot fungi laccase: Toward bio‐derived supports as a circular economy approach in organochlorine removal

Maria Pilar Serbent,

Ivana Magario,

Clara Saux

Abstract: Despite their high persistence in the environment, organochlorines (OC) are widely used in the pharmaceutical industry, in plastics, and in the manufacture of pesticides, among other applications. These compounds and the byproducts of their decomposition deserve attention and efficient proposals for their treatment. Among sustainable alternatives, the use of ligninolytic enzymes (LEs) from fungi stands out, as these molecules can catalyze the transformation of a wide range of pollutants. Among LEs, laccases (L… Show more

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2024

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Cited by 5 publications

References 201 publications

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A novel and sustainable composite of L@PSAC for superior removal of pharmaceuticals from different water matrices: Production, characterization, and application

Al-sareji,

Al-Samarrai,

Grmasha

et al. 2024

Environmental Research

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A novel and sustainable composite of L@PSAC for superior removal of pharmaceuticals from different water matrices: Production, characterization, and application

Al-sareji,

Al-Samarrai,

Grmasha

et al. 2024

Environmental Research

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Polymerization potential of a bacterial CotA-laccase for β-naphthol: enzyme structure and comprehensive polymer characterization

Refaat,

ElRakaiby,

El Hariri El Nokab

et al. 2024

Front. Microbiol.

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IntroductionLaccases are blue-multicopper containing enzymes that are known to play a role in the bioconversion of recalcitrant compounds. Their role in free radical polymerization of aromatic compounds for their valorization remains underexplored. In this study, we used a pBAD plasmid containing a previously characterized CotA laccase gene (abbreviated as Bli-Lacc) from Bacillus licheniformis strain ATCC 9945a to express this enzyme and explore its biotransformation/polymerization potential on β-naphthol.MethodsThe protein was expressed from TOP10 cells of Escherichia coli after successful transformation of the plasmid. Immobilized metal affinity chromatography (IMAC) was used to generate pure protein. The biocatalytic polymerization reaction was optimized based on temperature, pH and starting enzyme concentration. 1H and 13C solution nuclear magnetic resonance (NMR), Fourier transform infrared spectroscopy (FTIR), and solid-state NMR (ssNMR) were used to characterize the formed polymer. A one-gram conversion reaction was done to explore applicability of the reaction in a pilot-scale.ResultsThe polymerization reaction generated a brown precipitate, and its chemical structure was confirmed using 1H and 13C NMR and FTIR. SsNMR revealed the presence of two different orientational hydroxyl functional groups in the polymer in addition to the presence of a very small amount of ether linkages (< 2%). This analysis elucidated that polymerization occurred mainly on the carbons of the aromatic rings, rather than on the carbons attached to the hydroxyl groups, resulting in a condensed ring or polynuclear aromatic structure. The reaction was optimized, and the highest yield was attained under conditions of 37°C, pH 10 and a starting enzyme concentration of 440 nM in 50 mM phosphate buffer. A one-gram conversion yielded 216 mg of polymer as dry mass. The crystal structure of the enzyme was solved at 2.7 Å resolution using X-ray crystallography and presented with a hexagonal space group. The final structure was deposited in the Protein Databank (PDB) with an ID−9BD5.DiscussionThis article provides a green/enzymatic pathway for the remediation of phenolics and their valorization into potential useful polymeric materials. The comprehensive analysis of the formed polymer provides insight into its structure and functional moieties present. Based on the yield of the one-gram conversion, this synthetic method proves useful for a pilot-scale production level and opens opportunities to invest in using this polymer for industrial/environmental applications.

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Enhanced Thermostability of Laccase from Myceliophthora thermophila Through Conjugation with mPEG-SC

García,

Florindo,

Saez

et al. 2024

Catalysts

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The search for more sustainable reaction conditions has been necessary to obtain more selective processes. In this context, laccases have gained great notoriety in recent years. However, these enzymes are unstable in organic solvents and have low thermal stability. Alternatively, conjugation with PEG (PEGylation) can be essential to overcome these problems. In this work, the commercial laccase from Myceliophthora thermophila (LacMT) was subjected to PEGylation with PEG functionalized as succinimidyl carbonate (mPEG-SC), followed by assessing its thermal stability and catalytic activity. Mono-PEGylated LacMT derivatives were obtained, with less than 50% of the enzyme remaining in its native form. In addition, 10% of the bi-PEGylated species was successfully obtained according to gel electrophoresis analysis. The PEGylated derivatives showed a significantly reduced ABTS oxidation activity (98 ± 3 U/mg) compared to the native LacMT (407 ± 9 U/mg) but higher than the control enzyme without PEGylation (51 ± 2 U/mg), demonstrating that the addition of activated PEG to the protein resulted in better protection against the harmful action of the pH change required in the process. PEGylated LacMT retained more than twice the initial activity of the native protein at 40 °C during 24 h. In addition, PEGylated LacMT exhibited kinetic changes, whereas the catalytic turnover rate (kcat) of the PEGylated enzyme was reduced by 27% compared to the control. These findings are being reported for the first time. This sets precedents for constructing efficient catalytic systems involving laccases since no immobilized biocatalyst or commercial conjugate contains these proteins.

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Immobilizing white‐rot fungi laccase: Toward bio‐derived supports as a circular economy approach in organochlorine removal

Cited by 5 publications

References 201 publications

A novel and sustainable composite of L@PSAC for superior removal of pharmaceuticals from different water matrices: Production, characterization, and application

A novel and sustainable composite of L@PSAC for superior removal of pharmaceuticals from different water matrices: Production, characterization, and application

Polymerization potential of a bacterial CotA-laccase for β-naphthol: enzyme structure and comprehensive polymer characterization

Enhanced Thermostability of Laccase from Myceliophthora thermophila Through Conjugation with mPEG-SC

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