Biochemical features of dye‐decolorizing peroxidases: Current impact on lignin degradation

Dye‐decolorizing peroxidases (DyP) were originally discovered in fungi for their ability to decolorize several different industrial dyes. DyPs catalyze the oxidation of a variety of substrates such as phenolic and nonphenolic aromatic compounds. Catalysis occurs in the active site or on the surface...

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Bibliographic Details
Published in:Biotechnology and applied biochemistry 2020-09, Vol.67 (5), p.751-759
Main Authors: Catucci, Gianluca, Valetti, Francesca, Sadeghi, Sheila J., Gilardi, Gianfranco
Format: Article
Language:English
Subjects:
Arginine
Aromatic compounds
Bacteria - enzymology
Bacteria - metabolism
Biocatalysis
Biocatalysts
Biodegradation
biofuel
Biofuels
Biofuels - analysis
Biofuels - microbiology
biotechnology
Biotechnology - methods
Catalysis
Catalytic Domain
Coloring Agents - chemistry
Coloring Agents - metabolism
Decoloring
decolorizing
Degradation
Directed evolution
dye
Dyes
DyP
energy
Enzymes
Fine chemicals
Fungi
Fungi - enzymology
Fungi - metabolism
Heme
Histidine
Hydrogen peroxide
Industrial applications
Iron
Lignin
Lignin - chemistry
Lignin - metabolism
Lignocellulose
Models, Molecular
Oxidation
peroxidase
Peroxidases - chemistry
Peroxidases - metabolism
Phenolic compounds
Phenols
Substrates
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Summary:Dye‐decolorizing peroxidases (DyP) were originally discovered in fungi for their ability to decolorize several different industrial dyes. DyPs catalyze the oxidation of a variety of substrates such as phenolic and nonphenolic aromatic compounds. Catalysis occurs in the active site or on the surface of the enzyme depending on the size of the substrate and on the existence of radical transfer pathways available in the enzyme. DyPs show the typical features of heme‐containing enzymes with a Soret peak at 404–408 nm. They bind hydrogen peroxide that leads to the formation of the so‐called Compound I, the key intermediate for catalysis. This then decays into Compound II yielding back Fe(III) at its resting state. Each catalytic cycle uses two electrons from suitable electron donors and generates two product molecules. DyPs are classified as a separate class of peroxidases. As all peroxidases they encompass a conserved histidine that acts as the fifth heme ligand, however all primary DyP sequences contain a conserved GxxDG motif and a distal arginine that is their characteristic. Given their ability to attack monomeric and dimeric lignin model compounds as well as polymeric lignocellulose, DyPs are a promising class of biocatalysts for lignin degradation that not only represents a source of valuable fine chemicals, but it also constitutes a fundamental step in biofuels production. Research efforts are envisioned for the improvement of the activity of DyPs against lignin, through directed evolution, ration protein design, or one‐pot combination with other enzymes to reach satisfactory conversion levels for industrial applications. Dye‐decolorizing peroxidases can be exploited to degrade lignin and produce biofuel.
ISSN:0885-4513
1470-8744
DOI:10.1002/bab.2015