Action of biologically-relevant oxidizing species upon uric acid. Identification of uric acid oxidation products

Uric acid is an end-product of purine metabolism in Man, and has been suggested to act as an antioxidant in vivo. Products of attack upon uric acid by various oxidants were measured by high performance liquid chromatography. Hypochlorous acid rapidly oxidized uric acid, forming allantoin, oxonic/oxaluric and parabanic acids, as well as several unidentified products. HOCl could oxidize all these products further. Hydrogen peroxide did not oxidize uric acid at detectable rates, although it rapidly oxidized oxonic acid and slowly oxidized allantoin and parabanic acids. Hydroxyl radicals generated by hypoxanthine/xanthine oxidase or Fe2(+)-EDTA/H2O2 systems also oxidized uric acid to allantoin, oxonic/oxaluric acid and traces of parabanic acid. Addition of ascorbic acid to the Fe2(+)-EDTA/H2O2 system did not increase formation of oxidation products from uric acid, possibly because ascorbic acid can 'repair' the radicals resulting from initial attack of hydroxyl radicals upon uric acid. Mixtures of methaemoglobin or metmyoglobin and H2O2 also oxidized uric acid: allantoin was the major product, but some parabanic and oxonic/oxaluric acids were also produced. Caeruloplasmin did not oxidize uric acid under physiological conditions, although simple copper (Cu2+) ions could, but this was prevented by albumin or histidine. The possibility of using oxidation products of uric acid, such as allantoin, as an index of oxidant generation in vivo in humans is discussed.     

Blood uric acid levels during hyperthermic stress.

Non-diabetic and streptozotocin diabetic adult male Sprague-Dawley derived rats were divided into normothermic and hyperthermic groups. Hyperthermia was achieved in an environmental chamber. Blood uric acid and lactate levels were performed on all animals. Significant increases in blood uric acid levels were found in all animals during hyperthermia. Blood lactic acid was also increased during hyperthermia indicating tissue hypoxia. It has been shown that increases in the breakdown of purine nucleotides occurs during hypoxia. This study indicates that increases in blood uric acid levels is an expected response to hyperthermic stress and is probably due to tissue hypoxia.     

Determinants of plasma uric acid

Summary Obesity, alcohol consumption, and hematocrit provide an index of plasma uric acid, which in path analysis has a cultural heritability of 0.11 in children and 0.23 in parents, a small maternal effect, and a genetic heritability of 0.25 in both generations. Preliminary evidence for a major locus is destroyed by the omission of one exceptional child. There is no evidence against the polygenic hypothesis for hyperuricemia in the Japanese-American population studied.     

Plasmodium-induced inflammation by uric acid

Infection of erythrocytes with the Plasmodium parasite causes the pathologies associated with malaria, which result in at least one million deaths annually. The rupture of infected erythrocytes triggers an inflammatory response, which is induced by parasite-derived factors that still are not fully characterized. Induced secretion of inflammatory cytokines by these factors is considered a major cause of malaria pathogenesis. In particular, the inflammatory cytokine tumor necrosis factor (TNF) is thought to mediate most of the life-threatening pathologies of the disease. Here we describe the molecular characterization of a novel pathway that results in the secretion of TNF by host cells. We found that erythrocytes infected by Plasmodium accumulate high concentrations of hypoxanthine and xanthine. Degradation of Plasmodium-derived hypoxanthine/xanthine results in the formation of uric acid, which triggers the secretion of TNF. Since uric acid is considered a "danger signal" released by dying cells to alert the immune system, Plasmodium appears to have co-evolved to exploit this warning system. Identifying the mechanisms used by the parasite to induce the host inflammatory response is essential to develop urgently needed therapies against this disease.     

Effect of KC1 on renal uric acid excretion.

The effect of two days' KC1 administration per os (total amount 11 g, i.e. 140 mEq potassium) on renal uric acid excretion was studied in healthy subjects under conditions of water diuresis. A significant increase in the uric acid excretory fraction (CUA/CCr..100) was found, from 8.04% in the control test to 10.31% under experimental conditions. Elevated renal uric excretion led to a significant drop in the plasma uric acid level from 4.9 mg% to 4.2 mg% after the administration to KC1. The findings suggest that KC1 influences the tubular transport of uric acid, but the mechanism of its action is still obscure.     

Histochemical studies of uric acid in some insects. 3. Excretion of uric acid by the malpighian tubules in Calliphora vicina and Rhodnius prolixus

In adult Calliphora uric acid is excreted throughout the Malpighian tubules. Histochemical preparations for the light microscope show uric acid passing through the cells and forming crystalline spheres in immediate contact with the microvilli. Uric acid appears to be synthesized and discharged into the haemolymph by the fat body cells. In Rhodnius there is no visible uric acid in the cells or lumen of the upper segment of the tubule (two-thirds of the total length of the tubule) apart from occasional deposits in the basal lamina. All uric acid excretion depends on the lower segment. Electron micrographs after argentaffin staining show high concentration of uric acid in the cytoplasm below the basal lamina (which also contains uric acid deposits). Uric acid is visible throughout the cell, particularly aroand the mitochondria; it is absent from the infolded plasma membrane and from all vacuoles. At the lumen there is a concentrated deposit of uric acid immediately beyond the plasma membrane. The uric acid particles unite with particles of unstained matrix material to form crystalline spheres. The fat body shows active synthesis of uric acid which is discharged by the cells into the intercellular channels and so to the basal lamina through which it passes into the haemolymph. As judged by histochemical preparations the haemolymph contains a high concentration of uric acid, very variable in different sites. Likewise large variations in uric acid secretion occur in different parts of the fat body.     

Reaction of uric acid with peroxynitrite and implications for the mechanism of neuroprotection by uric acid

Peroxynitrite, a biological oxidant formed from the reaction of nitric oxide with the superoxide radical, is associated with many pathologies, including neurodegenerative diseases, such as multiple sclerosis (MS). Gout (hyperuricemic) and MS are almost mutually exclusive, and uric acid has therapeutic effects in mice with experimental allergic encephalomyelitis, an animal disease that models MS. This evidence suggests that uric acid may scavenge peroxynitrite and/or peroxynitrite-derived reactive species. Therefore, we studied the kinetics of the reactions of peroxynitrite with uric acid from pH 6.9 to 8.0. The data indicate that peroxynitrous acid (HOONO) reacts with the uric acid monoanion with k = 155 M(-1) s(-1) (T = 37 degrees C, pH 7.4) giving a pseudo-first-order rate constant in blood plasma k(U(rate))(/plasma) = 0.05 s(-1) (T = 37 degrees C, pH 7.4; assuming [uric acid](plasma) = 0.3 mM). Among the biological molecules in human plasma whose rates of reaction with peroxynitrite have been reported, CO(2) is one of the fastest with a pseudo-first-order rate constant k(CO(2))(/plasma) = 46 s(-1) (T = 37 degrees C, pH 7.4; assuming [CO(2)](plasma) = 1 mM). Thus peroxynitrite reacts with CO(2) in human blood plasma nearly 920 times faster than with uric acid. Therefore, uric acid does not directly scavenge peroxynitrite because uric acid can not compete for peroxynitrite with CO(2). The therapeutic effects of uric acid may be related to the scavenging of the radicals CO(*-)(3) and NO(*)(2) that are formed from the reaction of peroxynitrite with CO(2). We suggest that trapping secondary radicals that result from the fast reaction of peroxynitrite with CO(2) may represent a new and viable approach for ameliorating the adverse effects associated with peroxynitrite in many diseases.     

血尿酸与代谢性风险

越来越多研究表明,高血尿酸与代谢综合征密切相关。传统观点认为尿酸水平仅是代谢综合征的一个生物标志而不能预测代谢综合征,这种观点可能被修改。降低血尿酸可能是预防糖尿病及多种慢性疾病的一种新的治疗方法。     

Free radical metabolite of uric acid

Uric acid has previously been shown to act as a water-soluble antioxidant. Although the antioxidant activity of uric acid has been attributed to its ability to scavenge free radicals, the one-electron uric acid oxidation product of such a scavenging reaction has not been detected. It order to determine whether a free radical metabolite of uric acid could be formed via one-electron redox processes, we oxidized uric acid with potassium permanganate, horseradish peroxidase/hydrogen peroxide, and hematin/hydrogen peroxide systems. With the use of the rapid-mixing, continuous-flow electron spin resonance technique, we were able to detect the urate anion free radical in all three radical-generating systems. Based on N15-isotopic-labeling experiments, we show that the unpaired electron of this radical is located primarily on the five-membered ring of the purine structure. We were also able to demonstrate that this radical could be scavenged by ascorbic acid.