Xanthine oxidase, function

Therapeutic Function Xanthine oxidase inhibitor gout therapy Chemical Name 1 H-pyra2olo[3,4-d] pyrimidin4-ol Common Name —... 

Romao MJ, Huber R (1998) Structure and Function of the Xanthine-Oxidase Family of Molybdenum Enzymes. 90 69-96 Rosenzweig A, see Penneman RA (1973) 13 1-52... 

It is possible that dietary flavonoids participate in the regulation of cellular function independent of their antioxidant properties. Other non-antioxidant direct effects reported include inhibition of prooxidant enzymes (xanthine oxidase, NAD(P)H oxidase, lipoxygenases), induction of antioxidant enzymes (superoxide dismutase, gluthathione peroxidase, glutathione S-transferase), and inhibition of redox-sensitive transcription factors. 

Lee, C.-H. Skibo, E. B. Active site directed reductive alkylation of xanthine oxidase by imidazo[4,5-g]quinazoline-4,9-diones functionalized with a leaving group. Biochemistry 1987, 26, 7355-7362. 

The role of the iron-sulphur system of xanthine oxidase in the catalytic reaction is somewhat problematical. Nevertheless, it is clear, both from rapid freezing EPR (53) and from stopped-flow measurements monitored optically at 450 nm (58, 63) (where both iron and flavin are measured), that iron is reduced and oxidized at catalytically significant rates. Perhaps the best interpretation is that it functions as a store for reducing equivalents within the enzyme when this is acting as an oxidase, though it may well represent the main site of electron egress in dehydrogenase reactions (52). 

In earlier work (66) where the presence of two inactive species was recognised but their origins less fully understood, these species were termed xanthine oxidase-i i (now inactivated xanthine oxidase) and xanthine oxidase-12 (now de-molybdo xanthine oxidase). The former species is referred to by Massey and co-workers as xanthine oxidase with non-functional active sites (33). 

Fig. 5. Multiple phases in the reduction of xanthine oxidase by xanthine at pH 8.2. Intensities of the Rapid (circles) and Slow (triangles) molybdenum EPR signals expressed as electron/mole enzyme (i-e. per 2 atom Mo) are plotted as a function of time. Note the changes in the time scale. Rapid freezing was used for reaction times (at 22°) up to 1 sec. and manual mixing for longer times (at 25°) enzyme concentrations (immediately after mixing) were 0.09 mM and 0.13 mM respectively. The enzyme had Activity/A45o 125 corresponding to 63% of active enzyme and 20 mole xanthine/mole enzyme was used. (Data from ref. 67.)...

So little is known about molybdenum enzymes other than milk xanthine oxidase that there is little to be said by way of general conclusions. In all cases where there is direct evidence (except possibly for xanthine dehydrogenase from Micrococcus lactilyticus) it seems that molybdenum in the enzymes does have a redox function in catalysis. For the xanthine oxidases and dehydrogenases and for aldehyde oxidase, the metal is concerned in interaction of the enzymes with reducing substrates. However, for nitrate reductase it is apparently in interaction with the oxidizing substrate that the metal is involved. In nitrogenase the role of molybdenum is still quite uncertain. 

In addition to these more-or-less well characterized proteins, iron is known to be bound to certain flavoproteins such as succinic dehydrogenase (20), aldehyde oxidase (27), xanthine oxidase (22) and dihydrooro-tate dehydrogenase (23). Iron is present and functional in non-heme segments of the electron transport chain but again no real structural information is at hand (24). 

Allopurinol is the antihyperuricemic drug of choice in patients with a history of urinary stones or impaired renal function, in patients who have lymphoproliferative or myeloproliferative disorders and need pretreatment with a xanthine oxidase inhibitor before initiation of cytotoxic therapy to protect against acute uric acid nephropathy, and in patients with gout who are overproducers of uric acid. 

Professor Sabyasachi Sarkar (bom in 17 May 1947) is an Indian Chemist. He has explored chemistry passionately as a prospector to observe closely the clandestine activities of nature. He has worked and continued working in the diverse branches of chemistry closely related to natural set up and as such his research embraces functional models related to hyperthermophilic to mesophilic metalloproteins enriching bioinorganic chemistry. A Rephca of a Fishy Enzyme and the reduced xanthine oxidase also have been made. Inhibition patterns in the Michaelis complex of low molecular weight hepatic sulfite oxidase model complex have been exhibited. He demonstrated that carbon dioxide molecule does bind... 

In patients with severely impaired renal function or decreased urate clearance, the plasma half-life of oxipurinol is greatly prolonged. A dose of 100 mg/day or 300 mg twice a week, or less, may be sufficient to maintain adequate xanthine oxidase inhibition to reduce serum urate levels. 

A large number of studies devoted to metal-sulfur centers are motivated by the occurrence of such arrangements at the active site of various metalloenzymes [1-13]. Mononuclear complexes with Mo=0 func-tion(s) and possessing sulfur ligands in their coordination sphere have been extensively investigated since they can be seen as models of the active site of enzymes such as nitrate- and DM SO reductases or sulfite- and xanthine oxidases [1-4]. On the other hand, a large variety of mono-, di-, and polynuclear Mo—S centers have been synthesized in order to produce functional models of the Mo-nitrogenase since the exact nature (mono-, di- or polynuclear) of the metal center, where N2 interacts within the iron-molybdenum cofactor (FeMo—co) of the enzyme is still unknown [4-8]. 

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