1.2.3.4: oxalate oxidase
This is an abbreviated version!
For detailed information about oxalate oxidase, go to the full flat file.
Word Map on EC 1.2.3.4
-
1.2.3.4
-
wheat
-
barley
-
sclerotinia
-
apoplastic
-
powdery
-
mildew
-
pathogenesis-related
-
sclerotiorum
-
graminis
-
hyperoxaluria
-
blumeria
-
hordei
-
erysiphe
-
nodorum
-
bicupins
-
dentata
-
castanea
-
oxalate-degrading
-
berk
-
alkylamine
-
septoria
-
medicine
-
analysis
-
industry
-
synthesis
-
agriculture
- 1.2.3.4
- wheat
- barley
- sclerotinia
- apoplastic
-
powdery
- mildew
-
pathogenesis-related
- sclerotiorum
- graminis
- hyperoxaluria
- blumeria
-
hordei
- erysiphe
- nodorum
-
bicupins
- dentata
-
castanea
-
oxalate-degrading
-
berk
- alkylamine
- septoria
- medicine
- analysis
- industry
- synthesis
- agriculture
Reaction
Synonyms
aero-oxalo dehydrogenase, Germin, Germin GF-2.8, Germin GF-3.8, germin-like oxidase, germin-like protein, gl-OXO, glp1, GLP2, HvOxo1, oxalate oxidase, oxalate oxidase GF-2.8, oxalate: O2 oxidoreductase, oxalate:oxygen oxidoreductase, oxalic acid oxidase, OXO, OXO-G, OXO1, OXO2, OXO3, OXO4, OxOx, TaOxo1, TaOxo2
ECTree
Advanced search results
Reaction
Reaction on EC 1.2.3.4 - oxalate oxidase
Please wait a moment until all data is loaded. This message will disappear when all data is loaded.
oxalate + O2 = 2 CO2 + H2O2
The computer model supports the following reaction mechanism: The Oxo-Mn(2)-oxalate complex exists as a mixture of five-and six-coordinate species. The form with coordinatively unsaturated Mn(2) site reacts with dioxygen on the quartet potential energy surface. In this step, the proton from oxalate monoanion is transferred to dioxygen through the first-shell glutamate. The proton-transfer triggers the C-C bond cleavage, and the electron follows the proton. Simultaneously, the second electron, necessary to produce the peroxo species, is provided by manganese. This step, which is also rate-limiting, yields the first CO2 molecule and the reactive intermediate in which the formyl radical anion coordinates the high-spin Mn(3). The quartet to sextet spin transition, which involves a small apparent barrier, allows for the formyl radical -> Mn(3) electron transfer. This step leads to the product-active site complex, which upon protonation decays to H2O2, CO2, and the active site is then ready to begin the next catalytic cycle
-