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Literature summary for 1.1.3.13 extracted from

  • Ito, T.; Fujimura, S.; Uchino, M.; Tanaka, N.; Matsufuji, Y.; Miyaji, T.; Takano, K.; Nakagawa, T.; Tomizuka, N.
    Distribution, diversity and regulation of alcohol oxidase isozymes, and phylogenetic relationships of methylotrophic yeasts (2007), Yeast, 24, 523-532.
    View publication on PubMed

Application

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/ Products (Substrates)

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

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 and Products (Substrate)

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

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