| Description | Galactose oxidase oxidizes galactose and some galactose derivatives in both free and polymeric forms. Oxidation occurs at the C6 position. The enzyme has a molecular weight of 68 ± 3 kDa, and the optimum pH is 7.0.Useful in the determination of lactose.Application Galactose Oxidase from Galactose oxidase oxidizes galactose and some galactose derivatives in both free and polymeric forms. Oxidation occurs at the C6 position. The enzyme has a molecular weight of 68 ± 3 kDa, and the optimum pH is 7.0.Useful in the determination of lactose.Application Galactose Oxidase from Dactylium dendroides has been used as a component for galactose oxidase treatment of arabinogalactan. It has also been used to co-immobilise with peroxidase for the preparation of a biosensor for galactose detection. Galactose oxidase may be used as an analytical tool for the specific determination of D-galactose in blood plasma, plant extracts, and phospholipids. It could be used for the characterization of terminal D-galactoside units in several polymers. It may also be useful in the determination of lactose.1、Specificity :GAO has a wide substrate specificity, but remarkable stereospecificity, only oxidizing D-isomers of substrates (McPherson et al. 1992). GAO will oxidize galactose and some galactose derivatives in both free and polymeric form. Oxidation occurs at the C6 position. 2、Composition:GAO contains one Cu(II) atom yet catalyzes a two-electron transfer reaction (McPherson et al. 1992). The copper is bound by two tyrosines, and two histidines (Tyr272, Tyr495, His496, and His581). In a novel post-translational covalent modification, Tyr272 is linked by a thioether bond to cysteine (Cys228), suggesting the involvement of a tyrosine radical in the catalytic mechanism. Stabilization of the radical occurs because Tyr272 of the thioether bond is liganded to the copper, creating a stacking interaction with Trp290 (Whittaker et al. 1989, Ito et al. 1991, and Whittaker et al. 2005). The structure of the enzyme has revealed extensive beta-sheet secondary structure, consistent with the high stability of the enzyme (Kosman et al. 1974). Most extracellular proteins of eukaryotes are modified by glycosylation during passage through the ER and golgi, leading to greater glycosylation of extracellular than intracellular forms of a protein. Unusually, the intracellular form of GAO is more highly glycosylated (9% carbohydrate) and exhibits greater stability than the extracellular form (2% carbohydrate) (Medonca and Zancan 1988). Additionally, most proteins are modified by O- and/or N-glycosylation while GAO is only modified only by O-glycosylation (Kornfield and Kornfield 1985, and McPherson et al. 1992)3、Molecular Characteristics:The gaoA gene contains a long open reading frame from +324 to +2507, including the mature protein-coding sequence (+521 to +2507). It also contains a long untranslated upstream region and a putative pro-sequence with a monobasic cleavage site (McPherson et al. 1992).4、Characteristics of Galactose Oxidase:Protein Accession Number:P0CS93;Isoelectric point:7.75 (Theoretical)CATH Classification:Three domains:Class: Mainly BetaArchitecture: Sandwich, 7 PropellorTopology: Jelly Rolls, Methylamind Dehydrogenase; Chain H, Immunoglobulin-likeMolecular Weight68.5 kDa (calculated from translated DNA sequence and SDS-polyacrylamide gel electrophoresis, McPherson et al. 1992)68.0 ± 3.0 kDa (determined from physical measurements, Cooper et al. 1959) Optimal pH:7.0 (Cooper et al. 1959) Extinction Coefficient:122,480 cm-1M-1 (Theoretical)E1%, 280 = 17.87 (Theoretical)InhibitorsCyanideDiethyldithiocarbamateAzideHydroxylamineEDTAApplicationsQuantitative determination of galactose in blood and other biological fluids (Frings and Pardue 1964, Hankin 1966, and Roth et al. 1965)Locating galactose histochemically (Roberts and Gupta 1965)Detecting and distinguishing glycoproteins (Itaya et al. 1975)5、Galactose Oxidase Assay:MethodThe reaction velocity is measured in a peroxidase/o-tolidine coupled system as an increase in A425 resulting from the oxidation of galactose. One unit results in a change in A425 of 1.0 per minute at 25°C and pH 6.0 under the defined conditions.Reagents0.1 M Potassium phosphate buffer, pH 6.00.5% o-tolidine. Note: o-tolidine has been reported to be carcinogenic. Handle with care.Peroxidase. Dissolve Worthington peroxidase (Code: HPOD) at a concentration of approximately 60 u/ml in reagent grade water.10% galactose. Allow to come to equilibrium of mutarotation by allowing to stand overnight.EnzymeDissolve at a concentration of 1 mg/ml in reagent grade water. Dilute further for assay to a concentration of 0.2 - 0.5 units/ml.ProcedureAdjust spectrophotometer to 425 nm and 25°C.Prepare tolidine-buffer mixture by adding 0.1 ml tolidine to 12 ml 0.1 M potassium phosphate buffer pH 6.0.Pipette into each cuvette as follows:Tolidine-buffer solution 1.7 ml10% Galactose 1.5 mlPeroxidase 0.1 mlIncubate in spectrophotometer at 25°C for 3 - 4 mintues to achieve temperature equilibration and establish blank rate, if any. Add 0.1 ml of appropriately diluted enzyme and record increase in A425/min. from initial linear portion of the curve... Read More | Purity≥95% SDS-PAGE.FunctionStimulates growth of the cells in an autocrine manner. Mediates hormonal action on the growth of cancer cells | Purity>95% SDS-PAGE. Protein Content and Purity (typically = 95%) determined by reducing and Non-reducing SDS-PAGE, UV spectroscopy at 280 nm.Additional sequence informationThis product is for the mature full length protein. The signal peptide is not included.FunctionCytokine with a wide variety Purity>95% SDS-PAGE. Protein Content and Purity (typically = 95%) determined by reducing and Non-reducing SDS-PAGE, UV spectroscopy at 280 nm.Additional sequence informationThis product is for the mature full length protein. The signal peptide is not included.FunctionCytokine with a wide variety of biological functions. It is a potent inducer of the acute phase response. Plays an essential role in the final differentiation of B-cells into Ig-secreting cells Involved in lymphocyte and monocyte differentiation. It induces myeloma and plasmacytoma growth and induces nerve cells differentiation Acts on B-cells, T-cells, hepatocytes, hematopoeitic progenitor cells and cells of the CNS. Also acts as a myokine. It is discharged into the bloodstream after muscle contraction and acts to increase the breakdown of fats and to improve insulin resistance.Post-translational:N- and O-glycosylated... Read More | Purity> 95% by SDS-PAGE and HPLC analyses.FunctionSerine protease inhibitor that inhibits plasminogen activators and plasmin but not thrombin. May be involved in the formation or reorganization of synaptic connections as well as for synaptic plasticity in the adult nervous system. May protect Purity> 95% by SDS-PAGE and HPLC analyses.FunctionSerine protease inhibitor that inhibits plasminogen activators and plasmin but not thrombin. May be involved in the formation or reorganization of synaptic connections as well as for synaptic plasticity in the adult nervous system. May protect neurons from cell damage by tissue-type plasminogen activator... Read More | Inquire |