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Product Details:
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| Name: | Xanthine Oxidase | CAS: | 9002-17-9 |
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| Form: | Powder | Technique(s): | Cell Culture | Mammalian: Suitable |
| Highlight: | Xanthine Oxidase CAS 9002-17-9,CAS 9002-17-9 Xanthine Oxidase |
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CAS 9002-17-9 Xanthine Oxidase
| Xanthine Oxidase Basic information |
| Product Name: | Xanthine Oxidase |
| Synonyms: | e.c.1.2.3.2;hypoxanthineandxanthineoxidase;schardingerenzyme;xanthine-oxidas;xanthineoxidaseandhypoxanthine;xanthineoxidoreductase;EC 1.1.3.22;XOD |
| CAS: | 9002-17-9 |
| MF: | N/A |
| MW: | 0 |
| EINECS: | 232-657-6 |
| Product Categories: | enzyme |
| Mol File: | Mol File |
| Xanthine Oxidase Chemical Properties |
| storage temp. | 2-8°C |
| form | powder |
| color | brown |
| Description | An enzyme that is closely related to aldehyde oxidase (EC 1.2.3.1). Both are metalloflavoproteins of about 300,000 daltons. They consist of two subunits of equal size and contain molybdenum, FAD, and iron (as Fe/S) in a ratio of 1:1:4 per subunit. These enzymes are widely distributed and catalyze a reaction in which the substrate is hydroxylated by an oxygen atom derived from water and electrons from the substrate are transferred to a variety of acceptors. These two enzymes have a broad overlapping substrate specificity including many purines, pyrimidines, and pteridines. However, xanthine, the best known substrate for xanthine oxidase, is not a substrate for aldehyde oxidase whereas the reverse is true for quaternary pyridinium compounds, such as N0 -methylnicotinamide. The role of oxygen as an electron acceptor with its production of hydrogen peroxide and the intermediate superoxide anion (both potential toxicants) may not be important in vivo since there is evidence that these enzymes are NAD-dependent dehydrogenases in vivo and become oxidases as a result of modification during purification. However, they are probably important in two types of detoxication. The first of these is the hydroxylation of exogenous aldehydes, purines, pyrimidines and other heterocyclic compounds, and the second involves the utilization of exogenous compounds as electron acceptors. Examples of the latter include the conversion of organic nitro compounds to hydroxyamino derivatives and the reduction of N-oxides to the free base. |
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