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Literature summary for 1.11.1.13 extracted from

  • Chowdhary, P.; Shukla, G.; Raj, G.; Ferreira, L.; Bharagava, R.
    Microbial manganese peroxidase a ligninolytic enzyme and its ample opportunities in research (2019), SN Appl. Sci., 1, 45 .
No PubMed abstract available

Application

Application Comment Organism
biofuel production microbial MnPs can convert lignin into biomass so that the sugar can be converted into biofuels Alcaligenes faecalis
biofuel production microbial MnPs can convert lignin into biomass so that the sugar can be converted into biofuels Bacillus subtilis
biofuel production microbial MnPs can convert lignin into biomass so that the sugar can be converted into biofuels Bacillus cereus
biofuel production microbial MnPs can convert lignin into biomass so that the sugar can be converted into biofuels Schizophyllum commune
biofuel production microbial MnPs can convert lignin into biomass so that the sugar can be converted into biofuels Irpex lacteus
biofuel production microbial MnPs can convert lignin into biomass so that the sugar can be converted into biofuels Ganoderma lucidum
biofuel production microbial MnPs can convert lignin into biomass so that the sugar can be converted into biofuels Gelatoporia subvermispora
biofuel production microbial MnPs can convert lignin into biomass so that the sugar can be converted into biofuels Acinetobacter baumannii
biofuel production microbial MnPs can convert lignin into biomass so that the sugar can be converted into biofuels Trametes villosa
biofuel production microbial MnPs can convert lignin into biomass so that the sugar can be converted into biofuels Phanerodontia chrysosporium
biofuel production microbial MnPs can convert lignin into biomass so that the sugar can be converted into biofuels Cerrena unicolor
biofuel production microbial MnPs can convert lignin into biomass so that the sugar can be converted into biofuels Agrocybe praecox
biofuel production microbial MnPs can convert lignin into biomass so that the sugar can be converted into biofuels Phlebia radiata
biofuel production microbial MnPs can convert lignin into biomass so that the sugar can be converted into biofuels Trametes sp. 48424
environmental protection manganese peroxidases have a potential for degradation of many xenobiotic compounds and produce polymeric products formulated them into valuable tools for bioremediation purposes Alcaligenes faecalis
environmental protection manganese peroxidases have a potential for degradation of many xenobiotic compounds and produce polymeric products formulated them into valuable tools for bioremediation purposes Bacillus subtilis
environmental protection manganese peroxidases have a potential for degradation of many xenobiotic compounds and produce polymeric products formulated them into valuable tools for bioremediation purposes Bacillus cereus
environmental protection manganese peroxidases have a potential for degradation of many xenobiotic compounds and produce polymeric products formulated them into valuable tools for bioremediation purposes Schizophyllum commune
environmental protection manganese peroxidases have a potential for degradation of many xenobiotic compounds and produce polymeric products formulated them into valuable tools for bioremediation purposes Irpex lacteus
environmental protection manganese peroxidases have a potential for degradation of many xenobiotic compounds and produce polymeric products formulated them into valuable tools for bioremediation purposes Ganoderma lucidum
environmental protection manganese peroxidases have a potential for degradation of many xenobiotic compounds and produce polymeric products formulated them into valuable tools for bioremediation purposes Gelatoporia subvermispora
environmental protection manganese peroxidases have a potential for degradation of many xenobiotic compounds and produce polymeric products formulated them into valuable tools for bioremediation purposes Acinetobacter baumannii
environmental protection manganese peroxidases have a potential for degradation of many xenobiotic compounds and produce polymeric products formulated them into valuable tools for bioremediation purposes Trametes villosa
environmental protection manganese peroxidases have a potential for degradation of many xenobiotic compounds and produce polymeric products formulated them into valuable tools for bioremediation purposes Phanerodontia chrysosporium
environmental protection manganese peroxidases have a potential for degradation of many xenobiotic compounds and produce polymeric products formulated them into valuable tools for bioremediation purposes Cerrena unicolor
environmental protection manganese peroxidases have a potential for degradation of many xenobiotic compounds and produce polymeric products formulated them into valuable tools for bioremediation purposes Agrocybe praecox
environmental protection manganese peroxidases have a potential for degradation of many xenobiotic compounds and produce polymeric products formulated them into valuable tools for bioremediation purposes Phlebia radiata
environmental protection manganese peroxidases have a potential for degradation of many xenobiotic compounds and produce polymeric products formulated them into valuable tools for bioremediation purposes Trametes sp. 48424
additional information maganese peroxidase (MnP) has a great application potential and ample opportunities in diverse area, such as alcohol, pulp and paper, biofuel, agriculture, cosmetic, textile, and food industries detailed overview Phlebia radiata
additional information maganese peroxidase (MnP) has a great application potential and ample opportunities in diverse area, such as alcohol, pulp and paper, biofuel, agriculture, cosmetic, textile, and food industries, detailed overview Alcaligenes faecalis
additional information maganese peroxidase (MnP) has a great application potential and ample opportunities in diverse area, such as alcohol, pulp and paper, biofuel, agriculture, cosmetic, textile, and food industries, detailed overview Bacillus cereus
additional information maganese peroxidase (MnP) has a great application potential and ample opportunities in diverse area, such as alcohol, pulp and paper, biofuel, agriculture, cosmetic, textile, and food industries, detailed overview Schizophyllum commune
additional information maganese peroxidase (MnP) has a great application potential and ample opportunities in diverse area, such as alcohol, pulp and paper, biofuel, agriculture, cosmetic, textile, and food industries, detailed overview Irpex lacteus
additional information maganese peroxidase (MnP) has a great application potential and ample opportunities in diverse area, such as alcohol, pulp and paper, biofuel, agriculture, cosmetic, textile, and food industries, detailed overview Ganoderma lucidum
additional information maganese peroxidase (MnP) has a great application potential and ample opportunities in diverse area, such as alcohol, pulp and paper, biofuel, agriculture, cosmetic, textile, and food industries, detailed overview Gelatoporia subvermispora
additional information maganese peroxidase (MnP) has a great application potential and ample opportunities in diverse area, such as alcohol, pulp and paper, biofuel, agriculture, cosmetic, textile, and food industries, detailed overview Acinetobacter baumannii
additional information maganese peroxidase (MnP) has a great application potential and ample opportunities in diverse area, such as alcohol, pulp and paper, biofuel, agriculture, cosmetic, textile, and food industries, detailed overview Trametes villosa
additional information maganese peroxidase (MnP) has a great application potential and ample opportunities in diverse area, such as alcohol, pulp and paper, biofuel, agriculture, cosmetic, textile, and food industries, detailed overview Phanerodontia chrysosporium
additional information maganese peroxidase (MnP) has a great application potential and ample opportunities in diverse area, such as alcohol, pulp and paper, biofuel, agriculture, cosmetic, textile, and food industries, detailed overview Cerrena unicolor
additional information maganese peroxidase (MnP) has a great application potential and ample opportunities in diverse area, such as alcohol, pulp and paper, biofuel, agriculture, cosmetic, textile, and food industries, detailed overview Agrocybe praecox
additional information maganese peroxidase (MnP) has a great application potential and ample opportunities in diverse area, such as alcohol, pulp and paper, biofuel, agriculture, cosmetic, textile, and food industries, detailed overview Trametes sp. 48424
additional information maganese peroxidase (MnP) has a great application potential and ample opportunities in diverse area, such as alcohol, pulp and paper, biofuel,agriculture, cosmetic, textile, and food industries, detailed overview Bacillus subtilis

Natural Substrates/ Products (Substrates)

Natural Substrates Organism Comment (Nat. Sub.) Natural Products Comment (Nat. Pro.) Rev. Reac.
2 Mn(II) + 2 H+ + H2O2 Alcaligenes faecalis
-
2 Mn(III) + 2 H2O
-
?
2 Mn(II) + 2 H+ + H2O2 Bacillus subtilis
-
2 Mn(III) + 2 H2O
-
?
2 Mn(II) + 2 H+ + H2O2 Bacillus cereus
-
2 Mn(III) + 2 H2O
-
?
2 Mn(II) + 2 H+ + H2O2 Schizophyllum commune
-
2 Mn(III) + 2 H2O
-
?
2 Mn(II) + 2 H+ + H2O2 Irpex lacteus
-
2 Mn(III) + 2 H2O
-
?
2 Mn(II) + 2 H+ + H2O2 Ganoderma lucidum
-
2 Mn(III) + 2 H2O
-
?
2 Mn(II) + 2 H+ + H2O2 Gelatoporia subvermispora
-
2 Mn(III) + 2 H2O
-
?
2 Mn(II) + 2 H+ + H2O2 Acinetobacter baumannii
-
2 Mn(III) + 2 H2O
-
?
2 Mn(II) + 2 H+ + H2O2 Trametes villosa
-
2 Mn(III) + 2 H2O
-
?
2 Mn(II) + 2 H+ + H2O2 Phanerodontia chrysosporium
-
2 Mn(III) + 2 H2O
-
?
2 Mn(II) + 2 H+ + H2O2 Cerrena unicolor
-
2 Mn(III) + 2 H2O
-
?
2 Mn(II) + 2 H+ + H2O2 Agrocybe praecox
-
2 Mn(III) + 2 H2O
-
?
2 Mn(II) + 2 H+ + H2O2 Phlebia radiata
-
2 Mn(III) + 2 H2O
-
?
2 Mn(II) + 2 H+ + H2O2 Trametes sp. 48424
-
2 Mn(III) + 2 H2O
-
?
2 Mn(II) + 2 H+ + H2O2 Irpex lacteus CD2
-
2 Mn(III) + 2 H2O
-
?
2 Mn(II) + 2 H+ + H2O2 Irpex lacteus F17
-
2 Mn(III) + 2 H2O
-
?
2 Mn(II) + 2 H+ + H2O2 Irpex lacteus CCBAS238
-
2 Mn(III) + 2 H2O
-
?
2 Mn(II) + 2 H+ + H2O2 Schizophyllum commune IBL-06
-
2 Mn(III) + 2 H2O
-
?
2 Mn(II) + 2 H+ + H2O2 Ganoderma lucidum IBL-05
-
2 Mn(III) + 2 H2O
-
?
2 Mn(II) + 2 H+ + H2O2 Cerrena unicolor BBP6
-
2 Mn(III) + 2 H2O
-
?

Organism

Organism UniProt Comment Textmining
Acinetobacter baumannii
-
-
-
Agrocybe praecox G4WG41
-
-
Alcaligenes faecalis
-
-
-
Bacillus cereus
-
-
-
Bacillus subtilis
-
-
-
Cerrena unicolor A0A7D5FUQ6
-
-
Cerrena unicolor BBP6 A0A7D5FUQ6
-
-
Ganoderma lucidum
-
-
-
Ganoderma lucidum A0A1I9KRQ0
-
-
Ganoderma lucidum IBL-05
-
-
-
Gelatoporia subvermispora
-
Cerrena subvermispora
-
Irpex lacteus
-
-
-
Irpex lacteus A0A1S6KK55
-
-
Irpex lacteus S4W784
-
-
Irpex lacteus CCBAS238
-
-
-
Irpex lacteus CD2 A0A1S6KK55
-
-
Irpex lacteus F17 S4W784
-
-
Phanerodontia chrysosporium Q02567
-
-
Phlebia radiata Q70LM3
-
-
Schizophyllum commune
-
-
-
Schizophyllum commune IBL-06
-
-
-
Trametes sp. 48424
-
-
-
Trametes villosa
-
-
-

Source Tissue

Source Tissue Comment Organism Textmining
culture condition grown on potato dextrose agar Ganoderma lucidum
-
culture condition grown on potato dextrose agar Irpex lacteus
-
culture condition grown on banana waste Schizophyllum commune
-
culture condition grown on bark mulch and wood chips Agrocybe praecox
-
culture condition grown on dyes containing agar plates Cerrena unicolor
-
culture condition grown on GPYM agar plates Alcaligenes faecalis
-
culture condition grown on GPYM agar plates Bacillus cereus
-
culture condition grown on Japanese beech and cedar wood, Eucalyptus grandis wood, and Bamboo culms Gelatoporia subvermispora
-
culture condition grown on MEG agar slant Irpex lacteus
-
culture condition grown on mineral salt media Bacillus subtilis
-
culture condition grown on potato dextrose broth (PDB) Trametes sp. 48424
-
culture condition grown on solid-state fermentation medium Irpex lacteus
-
culture condition grown on wheat straw, rice straw, agriculture byproducts, or agro-industrial wastes Phanerodontia chrysosporium
-
culture condition:rice straw-grown cell
-
Acinetobacter baumannii
-
culture condition:sugarcane bagasse-grown cell
-
Trametes villosa
-
culture condition:wheat bran-grown cell
-
Ganoderma lucidum
-
culture condition:wheat straw-grown cell
-
Phlebia radiata
-

Substrates and Products (Substrate)

Substrates Comment Substrates Organism Products Comment (Products) Rev. Reac.
2 Mn(II) + 2 H+ + H2O2
-
Alcaligenes faecalis 2 Mn(III) + 2 H2O
-
?
2 Mn(II) + 2 H+ + H2O2
-
Bacillus subtilis 2 Mn(III) + 2 H2O
-
?
2 Mn(II) + 2 H+ + H2O2
-
Bacillus cereus 2 Mn(III) + 2 H2O
-
?
2 Mn(II) + 2 H+ + H2O2
-
Schizophyllum commune 2 Mn(III) + 2 H2O
-
?
2 Mn(II) + 2 H+ + H2O2
-
Irpex lacteus 2 Mn(III) + 2 H2O
-
?
2 Mn(II) + 2 H+ + H2O2
-
Ganoderma lucidum 2 Mn(III) + 2 H2O
-
?
2 Mn(II) + 2 H+ + H2O2
-
Gelatoporia subvermispora 2 Mn(III) + 2 H2O
-
?
2 Mn(II) + 2 H+ + H2O2
-
Acinetobacter baumannii 2 Mn(III) + 2 H2O
-
?
2 Mn(II) + 2 H+ + H2O2
-
Trametes villosa 2 Mn(III) + 2 H2O
-
?
2 Mn(II) + 2 H+ + H2O2
-
Phanerodontia chrysosporium 2 Mn(III) + 2 H2O
-
?
2 Mn(II) + 2 H+ + H2O2
-
Cerrena unicolor 2 Mn(III) + 2 H2O
-
?
2 Mn(II) + 2 H+ + H2O2
-
Agrocybe praecox 2 Mn(III) + 2 H2O
-
?
2 Mn(II) + 2 H+ + H2O2
-
Phlebia radiata 2 Mn(III) + 2 H2O
-
?
2 Mn(II) + 2 H+ + H2O2
-
Trametes sp. 48424 2 Mn(III) + 2 H2O
-
?
2 Mn(II) + 2 H+ + H2O2
-
Irpex lacteus CD2 2 Mn(III) + 2 H2O
-
?
2 Mn(II) + 2 H+ + H2O2
-
Irpex lacteus F17 2 Mn(III) + 2 H2O
-
?
2 Mn(II) + 2 H+ + H2O2
-
Irpex lacteus CCBAS238 2 Mn(III) + 2 H2O
-
?
2 Mn(II) + 2 H+ + H2O2
-
Schizophyllum commune IBL-06 2 Mn(III) + 2 H2O
-
?
2 Mn(II) + 2 H+ + H2O2
-
Ganoderma lucidum IBL-05 2 Mn(III) + 2 H2O
-
?
2 Mn(II) + 2 H+ + H2O2
-
Cerrena unicolor BBP6 2 Mn(III) + 2 H2O
-
?
gallic acid + H2O2
-
Ganoderma lucidum ?
-
?
gallic acid + H2O2
-
Phanerodontia chrysosporium ?
-
?
gallic acid + H2O2
-
Irpex lacteus ?
-
?
gallic acid + H2O2
-
Cerrena unicolor ?
-
?
gallic acid + H2O2
-
Irpex lacteus F17 ?
-
?
gallic acid + H2O2
-
Ganoderma lucidum IBL-05 ?
-
?
gallic acid + H2O2
-
Cerrena unicolor BBP6 ?
-
?
phenol red + H2O2
-
Alcaligenes faecalis ?
-
?
phenol red + H2O2
-
Bacillus cereus ?
-
?
phenol red + H2O2
-
Gelatoporia subvermispora ?
-
?
veratric acid + H2O2
-
Trametes sp. 48424 ? + 2 H2O
-
?
veratryl alcohol + H2O2
-
Irpex lacteus ? + 2 H2O
-
?
veratryl alcohol + H2O2
-
Irpex lacteus CD2 ? + 2 H2O
-
?

Subunits

Subunits Comment Organism
? x * 42000, SDS-PAGE Agrocybe praecox
? x * 43000, SDS-PAGE Alcaligenes faecalis
? x * 43000, SDS-PAGE Bacillus cereus
? x * 43000, SDS-PAGE Ganoderma lucidum
? x * 45000, SDS-PAGE Cerrena unicolor
? x * 37000, SDS-PAGE Irpex lacteus
? x * 49000, SDS-PAGE Trametes sp. 48424
? x * 68000, SDS-PAGE Phlebia radiata
? x * 52800, SDS-PAGE Phanerodontia chrysosporium
? x * 37720, SDS-PAGE Ganoderma lucidum

Synonyms

Synonyms Comment Organism
manganese peroxidase 2 UniProt Phlebia radiata
Mn2+:H2O2 oxidoreductase
-
Alcaligenes faecalis
Mn2+:H2O2 oxidoreductase
-
Bacillus subtilis
Mn2+:H2O2 oxidoreductase
-
Bacillus cereus
Mn2+:H2O2 oxidoreductase
-
Schizophyllum commune
Mn2+:H2O2 oxidoreductase
-
Irpex lacteus
Mn2+:H2O2 oxidoreductase
-
Ganoderma lucidum
Mn2+:H2O2 oxidoreductase
-
Gelatoporia subvermispora
Mn2+:H2O2 oxidoreductase
-
Acinetobacter baumannii
Mn2+:H2O2 oxidoreductase
-
Trametes villosa
Mn2+:H2O2 oxidoreductase
-
Phanerodontia chrysosporium
Mn2+:H2O2 oxidoreductase
-
Cerrena unicolor
Mn2+:H2O2 oxidoreductase
-
Agrocybe praecox
Mn2+:H2O2 oxidoreductase
-
Phlebia radiata
Mn2+:H2O2 oxidoreductase
-
Trametes sp. 48424
MnP
-
Alcaligenes faecalis
MnP
-
Bacillus subtilis
MnP
-
Bacillus cereus
MnP
-
Schizophyllum commune
MnP
-
Irpex lacteus
MnP
-
Ganoderma lucidum
MnP
-
Gelatoporia subvermispora
MnP
-
Acinetobacter baumannii
MnP
-
Trametes villosa
MnP
-
Phanerodontia chrysosporium
MnP
-
Cerrena unicolor
MnP
-
Agrocybe praecox
MnP
-
Phlebia radiata
MnP
-
Trametes sp. 48424
mnp1
-
Irpex lacteus
mnp1
-
Phanerodontia chrysosporium
mnp1
-
Agrocybe praecox
MnP2
-
Phlebia radiata
MnP2 UniProt Phlebia radiata

Temperature Optimum [°C]

Temperature Optimum [°C] Temperature Optimum Maximum [°C] Comment Organism
22
-
-
Trametes villosa
28
-
-
Irpex lacteus
28 38
-
Phanerodontia chrysosporium
30
-
-
Bacillus subtilis
30
-
-
Ganoderma lucidum
30
-
-
Gelatoporia subvermispora
35
-
-
Schizophyllum commune
40
-
-
Irpex lacteus
50 60
-
Irpex lacteus
60
-
-
Cerrena unicolor
70
-
-
Trametes sp. 48424

Temperature Stability [°C]

Temperature Stability Minimum [°C] Temperature Stability Maximum [°C] Comment Organism
20 60 stable at Ganoderma lucidum
40 70 stable at Irpex lacteus
65
-
stable at Irpex lacteus

pH Optimum

pH Optimum Minimum pH Optimum Maximum Comment Organism
3.5
-
-
Irpex lacteus
4 7
-
Irpex lacteus
4.5
-
-
Schizophyllum commune
4.5
-
-
Ganoderma lucidum
4.5
-
-
Phanerodontia chrysosporium
4.5
-
-
Cerrena unicolor
4.5
-
-
Irpex lacteus
4.5
-
-
Agrocybe praecox
5
-
-
Trametes sp. 48424

pH Stability

pH Stability pH Stability Maximum Comment Organism
4.8
-
stable at Cerrena unicolor
5.5
-
stable at Irpex lacteus
6
-
stable at Irpex lacteus
7
-
stable at Trametes villosa
7
-
stable at Agrocybe praecox

Cofactor

Cofactor Comment Organism Structure
heme
-
Alcaligenes faecalis
heme
-
Bacillus subtilis
heme
-
Bacillus cereus
heme
-
Schizophyllum commune
heme
-
Irpex lacteus
heme
-
Ganoderma lucidum
heme
-
Gelatoporia subvermispora
heme
-
Acinetobacter baumannii
heme
-
Trametes villosa
heme
-
Phanerodontia chrysosporium
heme
-
Cerrena unicolor
heme
-
Agrocybe praecox
heme
-
Phlebia radiata
heme
-
Trametes sp. 48424

General Information

General Information Comment Organism
physiological function manganese peroxidase is a key contributor in the microbial ligninolytic system. It mainly oxidizes Mn2+ ions that remain present in wood and soils, into more reactive Mn3+ form, stabilized by fungal chelators like oxalic acids. Mn3+ acts as a diffusible redox intermediate, a low molecular weight compound, which breaks phenolic lignin and produces free radicals that have a tendency to disintegrate involuntarily Alcaligenes faecalis
physiological function manganese peroxidase is a key contributor in the microbial ligninolytic system. It mainly oxidizes Mn2+ ions that remain present in wood and soils, into more reactive Mn3+ form, stabilized by fungal chelators like oxalic acids. Mn3+ acts as a diffusible redox intermediate, a low molecular weight compound, which breaks phenolic lignin and produces free radicals that have a tendency to disintegrate involuntarily Bacillus subtilis
physiological function manganese peroxidase is a key contributor in the microbial ligninolytic system. It mainly oxidizes Mn2+ ions that remain present in wood and soils, into more reactive Mn3+ form, stabilized by fungal chelators like oxalic acids. Mn3+ acts as a diffusible redox intermediate, a low molecular weight compound, which breaks phenolic lignin and produces free radicals that have a tendency to disintegrate involuntarily Bacillus cereus
physiological function manganese peroxidase is a key contributor in the microbial ligninolytic system. It mainly oxidizes Mn2+ ions that remain present in wood and soils, into more reactive Mn3+ form, stabilized by fungal chelators like oxalic acids. Mn3+ acts as a diffusible redox intermediate, a low molecular weight compound, which breaks phenolic lignin and produces free radicals that have a tendency to disintegrate involuntarily Schizophyllum commune
physiological function manganese peroxidase is a key contributor in the microbial ligninolytic system. It mainly oxidizes Mn2+ ions that remain present in wood and soils, into more reactive Mn3+ form, stabilized by fungal chelators like oxalic acids. Mn3+ acts as a diffusible redox intermediate, a low molecular weight compound, which breaks phenolic lignin and produces free radicals that have a tendency to disintegrate involuntarily Irpex lacteus
physiological function manganese peroxidase is a key contributor in the microbial ligninolytic system. It mainly oxidizes Mn2+ ions that remain present in wood and soils, into more reactive Mn3+ form, stabilized by fungal chelators like oxalic acids. Mn3+ acts as a diffusible redox intermediate, a low molecular weight compound, which breaks phenolic lignin and produces free radicals that have a tendency to disintegrate involuntarily Ganoderma lucidum
physiological function manganese peroxidase is a key contributor in the microbial ligninolytic system. It mainly oxidizes Mn2+ ions that remain present in wood and soils, into more reactive Mn3+ form, stabilized by fungal chelators like oxalic acids. Mn3+ acts as a diffusible redox intermediate, a low molecular weight compound, which breaks phenolic lignin and produces free radicals that have a tendency to disintegrate involuntarily Gelatoporia subvermispora
physiological function manganese peroxidase is a key contributor in the microbial ligninolytic system. It mainly oxidizes Mn2+ ions that remain present in wood and soils, into more reactive Mn3+ form, stabilized by fungal chelators like oxalic acids. Mn3+ acts as a diffusible redox intermediate, a low molecular weight compound, which breaks phenolic lignin and produces free radicals that have a tendency to disintegrate involuntarily Acinetobacter baumannii
physiological function manganese peroxidase is a key contributor in the microbial ligninolytic system. It mainly oxidizes Mn2+ ions that remain present in wood and soils, into more reactive Mn3+ form, stabilized by fungal chelators like oxalic acids. Mn3+ acts as a diffusible redox intermediate, a low molecular weight compound, which breaks phenolic lignin and produces free radicals that have a tendency to disintegrate involuntarily Trametes villosa
physiological function manganese peroxidase is a key contributor in the microbial ligninolytic system. It mainly oxidizes Mn2+ ions that remain present in wood and soils, into more reactive Mn3+ form, stabilized by fungal chelators like oxalic acids. Mn3+ acts as a diffusible redox intermediate, a low molecular weight compound, which breaks phenolic lignin and produces free radicals that have a tendency to disintegrate involuntarily Phanerodontia chrysosporium
physiological function manganese peroxidase is a key contributor in the microbial ligninolytic system. It mainly oxidizes Mn2+ ions that remain present in wood and soils, into more reactive Mn3+ form, stabilized by fungal chelators like oxalic acids. Mn3+ acts as a diffusible redox intermediate, a low molecular weight compound, which breaks phenolic lignin and produces free radicals that have a tendency to disintegrate involuntarily Cerrena unicolor
physiological function manganese peroxidase is a key contributor in the microbial ligninolytic system. It mainly oxidizes Mn2+ ions that remain present in wood and soils, into more reactive Mn3+ form, stabilized by fungal chelators like oxalic acids. Mn3+ acts as a diffusible redox intermediate, a low molecular weight compound, which breaks phenolic lignin and produces free radicals that have a tendency to disintegrate involuntarily Agrocybe praecox
physiological function manganese peroxidase is a key contributor in the microbial ligninolytic system. It mainly oxidizes Mn2+ ions that remain present in wood and soils, into more reactive Mn3+ form, stabilized by fungal chelators like oxalic acids. Mn3+ acts as a diffusible redox intermediate, a low molecular weight compound, which breaks phenolic lignin and produces free radicals that have a tendency to disintegrate involuntarily Phlebia radiata
physiological function manganese peroxidase is a key contributor in the microbial ligninolytic system. It mainly oxidizes Mn2+ ions that remain present in wood and soils, into more reactive Mn3+ form, stabilized by fungal chelators like oxalic acids. Mn3+ acts as a diffusible redox intermediate, a low molecular weight compound, which breaks phenolic lignin and produces free radicals that have a tendency to disintegrate involuntarily Trametes sp. 48424