Application | Comment | Organism |
---|---|---|
analysis | AOD gene and isozyme structure may be used as a basis for reclassification of the methylotrophic yeasts | [Candida] boidinii |
analysis | AOD gene and isozyme structure may be used as a basis for reclassification of the methylotrophic yeasts | Ogataea minuta |
analysis | AOD gene and isozyme structure may be used as a basis for reclassification of the methylotrophic yeasts | Ogataea angusta |
analysis | AOD gene and isozyme structure may be used as a basis for reclassification of the methylotrophic yeasts | Ogataea wickerhamii |
analysis | AOD gene and isozyme structure may be used as a basis for reclassification of the methylotrophic yeasts | Ogataea henricii |
analysis | AOD gene and isozyme structure may be used as a basis for reclassification of the methylotrophic yeasts | Ogataea philodendri |
analysis | AOD gene and isozyme structure may be used as a basis for reclassification of the methylotrophic yeasts | Ogataea pignaliae |
analysis | AOD gene and isozyme structure may be used as a basis for reclassification of the methylotrophic yeasts | [Candida] sonorensis |
analysis | AOD gene and isozyme structure may be used as a basis for reclassification of the methylotrophic yeasts | Ogataea glucozyma |
analysis | AOD gene and isozyme structure may be used as a basis for reclassification of the methylotrophic yeasts | Ogataea methanolica |
analysis | AOD gene and isozyme structure may be used as a basis for reclassification of the methylotrophic yeasts | Ogataea trehalophila |
analysis | AOD gene and isozyme structure may be used as a basis for reclassification of the methylotrophic yeasts | Pichia sp. |
analysis | AOD gene and isozyme structure may be used as a basis for reclassification of the methylotrophic yeasts | Ogataea methylovora |
analysis | AOD gene and isozyme structure may be used as a basis for reclassification of the methylotrophic yeasts | [Candida] methanosorbosa |
analysis | AOD gene and isozyme structure may be used as a basis for reclassification of the methylotrophic yeasts | [Candida] succiphila |
analysis | AOD gene and isozyme structure may be used as a basis for reclassification of the methylotrophic yeasts | Kuraishia capsulata |
analysis | AOD gene and isozyme structure may be used as a basis for reclassification of the methylotrophic yeasts | Ogataea naganishii |
analysis | AOD gene and isozyme structure may be used as a basis for reclassification of the methylotrophic yeasts | Komagataella pastoris |
Natural Substrates | Organism | Comment (Nat. Sub.) | Natural Products | Comment (Nat. Pro.) | Rev. | Reac. |
---|---|---|---|---|---|---|
additional information | [Candida] boidinii | AOD isozymes and second AOD genes distribute widely in several methylotrophic yeasts in the natural environment, and second AOD genes may have evolved as methylotrophic genes that can adapt to the environmental conditions of higher methanol concentrations | ? | - |
? | |
additional information | Ogataea minuta | AOD isozymes and second AOD genes distribute widely in several methylotrophic yeasts in the natural environment, and second AOD genes may have evolved as methylotrophic genes that can adapt to the environmental conditions of higher methanol concentrations | ? | - |
? | |
additional information | Ogataea angusta | AOD isozymes and second AOD genes distribute widely in several methylotrophic yeasts in the natural environment, and second AOD genes may have evolved as methylotrophic genes that can adapt to the environmental conditions of higher methanol concentrations | ? | - |
? | |
additional information | Ogataea wickerhamii | AOD isozymes and second AOD genes distribute widely in several methylotrophic yeasts in the natural environment, and second AOD genes may have evolved as methylotrophic genes that can adapt to the environmental conditions of higher methanol concentrations | ? | - |
? | |
additional information | Ogataea henricii | AOD isozymes and second AOD genes distribute widely in several methylotrophic yeasts in the natural environment, and second AOD genes may have evolved as methylotrophic genes that can adapt to the environmental conditions of higher methanol concentrations | ? | - |
? | |
additional information | Ogataea philodendri | AOD isozymes and second AOD genes distribute widely in several methylotrophic yeasts in the natural environment, and second AOD genes may have evolved as methylotrophic genes that can adapt to the environmental conditions of higher methanol concentrations | ? | - |
? | |
additional information | Ogataea pignaliae | AOD isozymes and second AOD genes distribute widely in several methylotrophic yeasts in the natural environment, and second AOD genes may have evolved as methylotrophic genes that can adapt to the environmental conditions of higher methanol concentrations | ? | - |
? | |
additional information | [Candida] sonorensis | AOD isozymes and second AOD genes distribute widely in several methylotrophic yeasts in the natural environment, and second AOD genes may have evolved as methylotrophic genes that can adapt to the environmental conditions of higher methanol concentrations | ? | - |
? | |
additional information | Ogataea glucozyma | AOD isozymes and second AOD genes distribute widely in several methylotrophic yeasts in the natural environment, and second AOD genes may have evolved as methylotrophic genes that can adapt to the environmental conditions of higher methanol concentrations | ? | - |
? | |
additional information | Ogataea methanolica | AOD isozymes and second AOD genes distribute widely in several methylotrophic yeasts in the natural environment, and second AOD genes may have evolved as methylotrophic genes that can adapt to the environmental conditions of higher methanol concentrations | ? | - |
? | |
additional information | Ogataea trehalophila | AOD isozymes and second AOD genes distribute widely in several methylotrophic yeasts in the natural environment, and second AOD genes may have evolved as methylotrophic genes that can adapt to the environmental conditions of higher methanol concentrations | ? | - |
? | |
additional information | Pichia sp. | AOD isozymes and second AOD genes distribute widely in several methylotrophic yeasts in the natural environment, and second AOD genes may have evolved as methylotrophic genes that can adapt to the environmental conditions of higher methanol concentrations | ? | - |
? | |
additional information | Ogataea methylovora | AOD isozymes and second AOD genes distribute widely in several methylotrophic yeasts in the natural environment, and second AOD genes may have evolved as methylotrophic genes that can adapt to the environmental conditions of higher methanol concentrations | ? | - |
? | |
additional information | [Candida] methanosorbosa | AOD isozymes and second AOD genes distribute widely in several methylotrophic yeasts in the natural environment, and second AOD genes may have evolved as methylotrophic genes that can adapt to the environmental conditions of higher methanol concentrations | ? | - |
? | |
additional information | [Candida] succiphila | AOD isozymes and second AOD genes distribute widely in several methylotrophic yeasts in the natural environment, and second AOD genes may have evolved as methylotrophic genes that can adapt to the environmental conditions of higher methanol concentrations | ? | - |
? | |
additional information | Kuraishia capsulata | AOD isozymes and second AOD genes distribute widely in several methylotrophic yeasts in the natural environment, and second AOD genes may have evolved as methylotrophic genes that can adapt to the environmental conditions of higher methanol concentrations | ? | - |
? | |
additional information | Ogataea naganishii | AOD isozymes and second AOD genes distribute widely in several methylotrophic yeasts in the natural environment, and second AOD genes may have evolved as methylotrophic genes that can adapt to the environmental conditions of higher methanol concentrations | ? | - |
? | |
additional information | Komagataella pastoris | AOD isozymes and second AOD genes distribute widely in several methylotrophic yeasts in the natural environment, and second AOD genes may have evolved as methylotrophic genes that can adapt to the environmental conditions of higher methanol concentrations | ? | - |
? |
Organism | UniProt | Comment | Textmining |
---|---|---|---|
Komagataella pastoris | F2QY27 | fragment | - |
Komagataella pastoris | F2R038 | fragment | - |
Kuraishia capsulata | A5LGE7 | fragment | - |
Ogataea angusta | P04841 | - |
- |
Ogataea glucozyma | A5LGE9 | fragment | - |
Ogataea henricii | A5LGF0 | fragment | - |
Ogataea methanolica | Q9UVU1 | - |
- |
Ogataea methanolica | Q9UVU2 | - |
- |
Ogataea methylovora | A5LGE3 | fragment | - |
Ogataea minuta | A5LGE4 | - |
- |
Ogataea minuta | A5LGF1 | fragment; var. minuta | - |
Ogataea naganishii | A5LGF2 | fragment | - |
Ogataea philodendri | A5LGF3 | fragment | - |
Ogataea pignaliae | A5LGE1 | fragment | - |
Ogataea pignaliae | A5LGE2 | fragment | - |
Ogataea trehalophila | A5LGF4 | fragment | - |
Ogataea wickerhamii | A5LGE8 | fragment | - |
Pichia sp. | Q5S059 | - |
- |
Pichia sp. | Q5S060 | - |
- |
[Candida] boidinii | Q00922 | - |
- |
[Candida] boidinii | Q5S057 | fragment | - |
[Candida] boidinii | Q5S058 | - |
- |
[Candida] methanosorbosa | A5LGE5 | fragment | - |
[Candida] sonorensis | A5LGD9 | fragment | - |
[Candida] sonorensis | A5LGE0 | fragment | - |
[Candida] succiphila | A5LGE6 | fragment | - |
Substrates | Comment Substrates | Organism | Products | Comment (Products) | Rev. | Reac. |
---|---|---|---|---|---|---|
additional information | AOD isozymes and second AOD genes distribute widely in several methylotrophic yeasts in the natural environment, and second AOD genes may have evolved as methylotrophic genes that can adapt to the environmental conditions of higher methanol concentrations | [Candida] boidinii | ? | - |
? | |
additional information | AOD isozymes and second AOD genes distribute widely in several methylotrophic yeasts in the natural environment, and second AOD genes may have evolved as methylotrophic genes that can adapt to the environmental conditions of higher methanol concentrations | Ogataea minuta | ? | - |
? | |
additional information | AOD isozymes and second AOD genes distribute widely in several methylotrophic yeasts in the natural environment, and second AOD genes may have evolved as methylotrophic genes that can adapt to the environmental conditions of higher methanol concentrations | Ogataea angusta | ? | - |
? | |
additional information | AOD isozymes and second AOD genes distribute widely in several methylotrophic yeasts in the natural environment, and second AOD genes may have evolved as methylotrophic genes that can adapt to the environmental conditions of higher methanol concentrations | Ogataea wickerhamii | ? | - |
? | |
additional information | AOD isozymes and second AOD genes distribute widely in several methylotrophic yeasts in the natural environment, and second AOD genes may have evolved as methylotrophic genes that can adapt to the environmental conditions of higher methanol concentrations | Ogataea henricii | ? | - |
? | |
additional information | AOD isozymes and second AOD genes distribute widely in several methylotrophic yeasts in the natural environment, and second AOD genes may have evolved as methylotrophic genes that can adapt to the environmental conditions of higher methanol concentrations | Ogataea philodendri | ? | - |
? | |
additional information | AOD isozymes and second AOD genes distribute widely in several methylotrophic yeasts in the natural environment, and second AOD genes may have evolved as methylotrophic genes that can adapt to the environmental conditions of higher methanol concentrations | Ogataea pignaliae | ? | - |
? | |
additional information | AOD isozymes and second AOD genes distribute widely in several methylotrophic yeasts in the natural environment, and second AOD genes may have evolved as methylotrophic genes that can adapt to the environmental conditions of higher methanol concentrations | [Candida] sonorensis | ? | - |
? | |
additional information | AOD isozymes and second AOD genes distribute widely in several methylotrophic yeasts in the natural environment, and second AOD genes may have evolved as methylotrophic genes that can adapt to the environmental conditions of higher methanol concentrations | Ogataea glucozyma | ? | - |
? | |
additional information | AOD isozymes and second AOD genes distribute widely in several methylotrophic yeasts in the natural environment, and second AOD genes may have evolved as methylotrophic genes that can adapt to the environmental conditions of higher methanol concentrations | Ogataea methanolica | ? | - |
? | |
additional information | AOD isozymes and second AOD genes distribute widely in several methylotrophic yeasts in the natural environment, and second AOD genes may have evolved as methylotrophic genes that can adapt to the environmental conditions of higher methanol concentrations | Ogataea trehalophila | ? | - |
? | |
additional information | AOD isozymes and second AOD genes distribute widely in several methylotrophic yeasts in the natural environment, and second AOD genes may have evolved as methylotrophic genes that can adapt to the environmental conditions of higher methanol concentrations | Pichia sp. | ? | - |
? | |
additional information | AOD isozymes and second AOD genes distribute widely in several methylotrophic yeasts in the natural environment, and second AOD genes may have evolved as methylotrophic genes that can adapt to the environmental conditions of higher methanol concentrations | Ogataea methylovora | ? | - |
? | |
additional information | AOD isozymes and second AOD genes distribute widely in several methylotrophic yeasts in the natural environment, and second AOD genes may have evolved as methylotrophic genes that can adapt to the environmental conditions of higher methanol concentrations | [Candida] methanosorbosa | ? | - |
? | |
additional information | AOD isozymes and second AOD genes distribute widely in several methylotrophic yeasts in the natural environment, and second AOD genes may have evolved as methylotrophic genes that can adapt to the environmental conditions of higher methanol concentrations | [Candida] succiphila | ? | - |
? | |
additional information | AOD isozymes and second AOD genes distribute widely in several methylotrophic yeasts in the natural environment, and second AOD genes may have evolved as methylotrophic genes that can adapt to the environmental conditions of higher methanol concentrations | Kuraishia capsulata | ? | - |
? | |
additional information | AOD isozymes and second AOD genes distribute widely in several methylotrophic yeasts in the natural environment, and second AOD genes may have evolved as methylotrophic genes that can adapt to the environmental conditions of higher methanol concentrations | Ogataea naganishii | ? | - |
? | |
additional information | AOD isozymes and second AOD genes distribute widely in several methylotrophic yeasts in the natural environment, and second AOD genes may have evolved as methylotrophic genes that can adapt to the environmental conditions of higher methanol concentrations | Komagataella pastoris | ? | - |
? |
Synonyms | Comment | Organism |
---|---|---|
alcohol oxidase 1 | - |
Ogataea methanolica |
alcohol oxidase 2 | - |
Ogataea methanolica |
alcohol oxidase A | - |
Pichia sp. |
alcohol oxidase B | - |
Pichia sp. |
AOd | - |
[Candida] boidinii |
AOd | - |
Ogataea minuta |
AOd | - |
Ogataea angusta |
AOd | - |
Ogataea wickerhamii |
AOd | - |
Ogataea henricii |
AOd | - |
Ogataea philodendri |
AOd | - |
Ogataea pignaliae |
AOd | - |
[Candida] sonorensis |
AOd | - |
Ogataea glucozyma |
AOd | - |
Ogataea methanolica |
AOd | - |
Ogataea trehalophila |
AOd | - |
Pichia sp. |
AOd | - |
Ogataea methylovora |
AOd | - |
Ogataea naganishii |
AOX1 | - |
Komagataella pastoris |
AOX2 | - |
Komagataella pastoris |