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 | 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 | 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 | 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 | 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 | 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 | 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 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 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 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 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 | 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 | 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 |