Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:1.17.3.2 (xanthine oxidase)
 8,383 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The protective effect of allopurinol, an inhibitor of the enzyme, xanthine oxidase, against the renal ischaemia-reperfusion of the rat was investigated. Rats were subjected to renal ischaemia by clamping of the left renal artery and vein for 45 min, and were then reperfused for 24 h; these animals were randomized to receive either saline (n = 10) or allopurinol (n = 10) at a dose of 50 mg/kg bolus intraperitoneally 5 min before reperfusion. The control group comprised seven healthy rats not exposed to ischaemia or reperfusion. The blood urea nitrogen and plasma creatinine levels were increased in the allopurinol group, but the increase was less than that in the placebo group, compared with the controls. The kidney glutathione level was significantly reduced in the placebo group but not in the allopurinol group compared with the controls. The glutathione peroxidase activity in the kidney tissues was reduced more than two-fold in the placebo group compared with the controls, but the reduction in glutathione peroxidase was considerably less in the allopurinol group. Renal tissue lactate dehydrogenase, aspartate amino-transferase, gamma-glutamyl transferase and alkaline phosphatase activities were reduced almost two-fold in the placebo group, but allopurinol treatment maintained these enzyme activities close to the control activities. These results provide evidence that allopurinol treatment may have beneficial effects on antioxidant defences against ischaemia-reperfusion injury of rat kidneys.
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PMID:Beneficial effects of allopurinol on glutathione levels and glutathione peroxidase activity in rat ischaemic acute renal failure. 867 98

Uric acid produced by xanthine oxidase (also a source of superoxide radicals) has been known to increase in hypertensive patients. In this study we evaluated the possible involvement of uric acid and xanthine oxidase in the pathogenesis of hypertension by examining their association with mean arterial pressure (MAP) and factors related to blood pressure. These factors include age, quetelet index (weight/height2), cholesterol, creatinine, calcium (Ca), magnesium (Mg), sodium (Na), potassium (K) and urea. Fifty Two (male-19, female-33) normal healthy individuals were studied. Correlation studies of demographic variables showed that age was positively correlated with MAP [r = 0.309, p = 0.026] and cholesterol [r = 0.503, p = 0.000] while quetelet index was positively correlated with age [r = 422, p = 0.000] MAP [r = 0.331, p = 0.016] and xanthine oxidase [r = 0.331, p = 0.016]. MAP was positively correlated with uric acid [r = 0.511, p = 0.000], cholesterol [r = 0.492, p = 0.000] and xanthine oxidase enzyme activity [r = 0.388, p = 0.004] and negatively correlated with plasma calcium [r = 0.603, p = 0.000]. Correlation studies of measured parameters with uric acid and xanthine oxidase showed that uric acid was positively correlated with creatinine [r = 0.627, p = 0.000], plasma magnesium [r 0.442, p = 0.001] and negatively correlated with plasma calcium [r = 0.546, p = 0.000] while xanthine oxidase was negatively correlated with plasma calcium [r = -0.404, p = 0.003] and plasma sodium [r = -0.288, p = 0.038]. Stepwise multiple regression with MAP as dependent variable showed that 65% of total variability of blood pressure can be accounted for by plasma calcium, cholesterol, creatinine, plasma K, plasma Na, uric acid and xanthine oxidase in order of increasing R2 [xanthine oxidase: T-value = 3.26, R2 = 0.653]. It can be concluded that in normotensive subjects, uric acid and xanthine oxidase have significant association with blood pressure and thus are one of the many factors which are involved in the cause or effect of hypertension.
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PMID:Uric acid, xanthine oxidase and other risk factors of hypertension in normotensive subjects. 892 44

Synthesis of guanidinosuccinic acid (GSA), a uremic toxin, has been suggested to relate to the urea concentration and synthetic rate. Among the urea cycle enzymes, inhibition of argininosuccinate (ASA) lyase by urea has been reported. Argininosuccinate which contains a GSA structure is a candidate of a GSA precursor. We found that another uremic toxin, methylguanidine, is formed from creatinine with reactive oxygen species. Therefore, we investigated in vitro whether GSA is formed from ASA with reactive oxygen species. GSA was measured by HPLC by a post-column-labeling method using 9,10-phenathrequinone. When 1 mmol/l ASA was reacted with the hydroxyl radical-generating system for 5 min at pH 7.4, 9 mumol/l GSA was formed. Dimethylsulfoxide, a hydroxyl radical scavenger, markedly inhibited GSA synthesis. The superoxide radical generated by xanthine and xanthine oxidase reaction also formed 1 mumol/l GSA from 1 mumol/l ASA and the GSA formation was inhibited by superoxide dismutase or catalase almost completely. Addition of FeCl2 to the xanthine/xanthine oxidase reaction further increased GSA synthesis. These results indicate that GSA is formed from ASA by reaction with the hydroxyl radical and the superoxide radical.
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PMID:Synthesis of guanidinosuccinate from argininosuccinate and reactive oxygen in vitro. 903 Aug 86

Tissue-specific changes in antioxidant defenses and lipid peroxidation damage were analyzed in spadefoot toads, Scaphiopus couchii, to determine how these responded during estivation, a state of suppressed oxygen consumption. Maximal activities of glutathione-S-transferase, glutathione reductase, glutathione peroxidase, superoxide dismutase and catalase were measured in six organs from 2-month-estivated toads and compared with activities in animals awakened for 10 days after estivation. Activities of many enzymes, particularly the glutathione-linked enzymes, were significantly lower in tissues of estivating toads than in awake toads. This indicates that enzymatic antioxidant defenses are probably modulated in response to the rate of reactive oxygen species generation in tissues, which is proportional to oxygen consumption. Antioxidant enzyme activities were largely insensitive to high urea, which accumulates during estivation, but were inhibited by elevated KCl. Levels of reduced glutathione were also significantly lower in three organs during estivation and all organs, except skeletal muscle, exhibited a higher oxidized/reduced glutathione ratio, indicating a more oxidized state during estivation. Products of lipid peroxidation (conjugated dienes, lipid hydroperoxides) were higher in tissues of estivated than control toads, suggesting accumulated oxidative damage to lipids during dormancy. One enzymatic source of free radical generation, xanthine oxidase, appeared to have little impact because its activity was detectable only in liver and was significantly lower in estivated toads. The data indicate that both enzymatic and metabolite antioxidant defenses in toads are adaptable systems that are modulated in estivating versus awake states.
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PMID:Antioxidant defenses and lipid peroxidation damage in estivating toads, Scaphiopus couchii. 954 48

Shichimotsu-koka-to (SKT) has been prescribed to treat patients with essential and renal hypertension. We investigated the effects of SKT on renal lesions in stroke-prone spontaneously hypertensive rats (SHRSPs). SHRSPs were given an extract of SKT by mixing it with drinking water, from 8 through 29 weeks of age, so that the average intake of SKT extract was about 1.5 g/kg/d. At 29 weeks of age, the kidneys of SHRSPs exhibited proliferative arteritis characterized by the proliferation of smooth muscle cells in the interlobular arteries, dilation and degeneration of renal tubules, infiltration of inflammatory cells and hemorrhage, with partial swelling or necrotizing of glomeruli. In particular, arteritis and periarteritis were noted. The treatment of SHRSPs with SKT ameliorated this morphological damage in the kidney and significantly decreased urea nitrogen in the serum. Treatment with SKT also strongly decreased the xanthine oxidase (XOD) activity and significantly increased the superoxide dismutase (SOD) activity in the kidney of SHRSPs; consequently, these values became close to those in normotensive Wistar Kyoto rats (WKYs). These results indicate that treatment with SKT ameliorated the histopathological damage and change in activity of enzymes related to free radicals in the kidney of SHRSPs, which may be important mechanisms for SKT for protecting SHRSPs from renal dysfunction.
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PMID:Preventive effects of Shichimotsu-koka-to on renal lesions in stroke-prone spontaneously hypertensive rats. 978 38

Oxidation by rat liver microsomes of 13 compounds involving a C=N(OH) function (including N-hydroxyguanidines, amidoximes, ketoximes, and aldoximes) was found to occur with the release of nitrogen oxides such as NO, NO2-, and NO3-. The greatest activities were observed with liver microsomes from dexamethasone-treated rats (up to 8 nmol of NO2- nmol of P450(-)1 min-1). A detailed study of the microsomal oxidation of some of these compounds was performed. Oxidation of N-(4-chlorophenyl)-N'-hydroxy-guanidine led to the formation of the corresponding urea and cyanamide in addition to NO, NO2-, and NO3-. Formation of all these products was dependent on NADPH, O2, and cytochromes P450. Oxidation of two arylamidoximes was found to occur with formation of the corresponding amides and nitriles in addition to nitrogen oxides. Oxidation of 4-(chlorophenyl)methyl ketone oxime gave the corresponding ketone and nitroalkane as well as NO, NO2-, and NO3-. These reactions were also dependent on cytochromes P450 and required NADPH and O2. Mechanistic experiments showed that microsomal oxidations of amidoximes to the corresponding nitriles and of ketoximes to the corresponding nitroalkanes are not inhibited by superoxide dismutase (SOD) and are performed by a cytochrome P450 active species, presumably the high-valent P450-iron-oxo complex. On the contrary, microsomal oxidation of N-hydroxyguanidines to the corresponding cyanamides was greatly inhibited by SOD and appeared to be mainly due to O2*- derived from the oxidase function of cytochromes P450. Similarly, microsomal oxidations of N-hydroxyguanidines and amidoximes to the corresponding ureas and amides were also found to be mainly performed by O2*-, as shown by the great inhibitory effect of SOD (70-100%) and the ability of the xanthine-xanthine oxidase system to give similar oxidation products. However, it is noteworthy that other species, such as the P450 Fe(II)-O2 complex, are also involved, to a minor extent, in the SOD-insensitive microsomal oxidative cleavages of compounds containing a C=N(OH) bond. Our results suggest a general mechanism for such oxidative cleavages of C=N(OH) bonds with formation of nitrogen oxides by cytochromes P450 and NO-synthases, with the involvement of O2*- and its Fe(III) complex [(FeIII-O2-) or (FeII-O2)] as main active species.
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PMID:Microsomal cytochrome P450 dependent oxidation of N-hydroxyguanidines, amidoximes, and ketoximes: mechanism of the oxidative cleavage of their C=N(OH) bond with formation of nitrogen oxides. 986 Aug 31

Biodegradation of poly(urethane)s (PU)s using single enzymes in vitro was assessed by measuring radiolabel release from model poly(ester-urea-urethane) (PESU) and poly(ether-urea-urethane) (PETU) materials synthesized with 14C-labelled monomers. Cholesterol esterase (CE), an enzyme found in monocyte-derived macrophages (MDM), has been reported to cause a significant level of radiolabel release from both of these PUs. Previous work has shown that CE activity could be inhibited by the serine protease/esterase inhibitor, phenylmethylsulfonyl fluoride. Since many serine proteases are present in circulating blood and can be released by cells other than MDM, this study investigated the ability of serine proteases relative to that of CE to cause the degradation of PUs. In addition, the possible role of several oxidative enzymes in the breakdown of PUs was investigated. Proteinase K, chymotrypsin and thrombin, when incubated with PESU, coated on glass slips, caused significant radiolabel release, with proteinase K giving the highest values. However, the highest radiolabel release which proteinase K could elicit was ten times less than CE. Thrombin and then chymotrypsin were progressively worse in their biodegradative activity. Only CE, and not the serine proteases, could elicit a detectable radiolabel release from PETU. Although the release of reactive oxygen species and molecular oxygen occur around an implanted biomaterial, several oxidative systems (peroxidase, xanthine oxidase, catalase), known to produce one or more of these molecular species, were unable to induce radiolabel release from these PUs. The process of biodegradation as assessed by radiolabel release appears to be a specific hydrolytic process, while the role of oxidative enzymes remains less clear.
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PMID:The biodegradation of poly(urethane)s by the esterolytic activity of serine proteases and oxidative enzyme systems. 1042 27

Methods to microencapsulate enzyme, cells, and genetically engineered cells have been described in this article. More specific examples of enzyme encapsulation include the microencapsulation of xanthine oxidase for Lesch-Nyhan disease; phenylalanine ammonia lyase for pheny, ketonuria and microencapsulation of multienzyme systems with cofactor recycling for multistep enzyme conversions. Methods for cell encapsulation include the details for encapsulating hepatocytes for liver failure and for gene therapy. This also includes the details of a novel two-step method for encapsulation of high concentrations of smaller cells. Another new approach is the detailed method of the encapsulation of genetically engineered Escherichia coli DH5 cells for lowering urea, ammonia, and other metabolites in kidney or, liver failure and other diseases.
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PMID:Procedures for microencapsulation of enzymes, cells and genetically engineered microorganisms. 1143 13

In an earlier communication, we have shown that Tephrosia purpurea ameliorates benzoyl peroxide-induced oxidative stress in murine skin (Saleem et al. 1999). The present study was designed to investigate a chemopreventive efficacy of T purpurea against N-diethylnitrosamine-initiated and potassium bromate-mediated oxidative stress and toxicity in rat kidney. A single intraperitoneal dose of N-diethylnitrosamine (200 mg/kg body weight) one hr prior to the dose of KBrO3 (125 mg/kg body weight) increases microsomal lipid peroxidation and the activity of xanthine oxidase and decreases the activities of renal antioxidant enzymes viz., catalase, glutathione peroxidase, glutathione reductase and glucose-6-phosphate dehydrogenase, phase II metabolizing enzymes such as glutathione-S-transferase and quinone reductase and causes depletion in the level of renal glutathione content. A sharp increase in blood urea nitrogen and serum creatinine has also been observed. Prophylactic treatment of rats with T. purpurea at doses of 5 mg/kg body weight and 10 mg/kg body weight prevented N-diethylnitrosamine-initiated and KBrO3 promoted renal oxidative stress and toxicity. The susceptibility of renal microsomal membrane for iron ascorbate-induced lipid peroxidation and xanthine oxidase activities were significantly reduced (P<0.01). The depleted levels of glutathione, the inhibited activities of antioxidant enzymes, phase II metabolizing enzymes and the enhanced levels of serum creatinine and blood urea nitrogen were recovered to a significant level (P<0.01). All the antioxidant enzymes were recovered dose-dependently. Our data indicate that T purpurea besides a skin antioxidant can be a potent chemopreventive agent against renal oxidative stress and carcinogenesis induced by N-diethylnitrosamine and KBrO3.
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PMID:Tephrosia purpurea ameliorates N-diethylnitrosamine and potassium bromate-mediated renal oxidative stress and toxicity in Wistar rats. 1145 68

The major insecticide imidacloprid (IMI) is known to be metabolized by human cytochrome P450 3A4 with NADPH by imidazolidine hydroxylation and dehydrogenation to give 5-hydroxy-imidacloprid and the olefin, respectively, and by nitroimine reduction and cleavage to yield the nitrosoimine, guanidine, and urea derivatives. More extensive metabolism by human or rabbit liver microsomes with NADPH or rabbit liver cytosol without added cofactor reduces the IMI N-nitro group to an N-amino substituent, i.e., the corresponding hydrazone. A major metabolite on incubation of IMI in the human microsome-NADPH system is tentatively assigned by LC/MS as a 1,2,4-triazol-3-one derived from the hydrazone; the same product is obtained on reaction of the hydrazone with ethyl chloroformate. The hydrazone and proposed triazolone are considered here together (referred to as the hydrazone) for quantitation. Only a portion of the microsomal reduction and cleavage of the nitroimine substituent is attributable to a CYP450 enzyme. The cytosolic enzyme conversion to the hydrazone is inhibited by added cofactors (NAD > NADH > NADP > NADPH) and enhanced by an argon instead of an air atmosphere. The responsible cytosolic enzyme(s) does not appear to be DT-diaphorase (which is inhibited by several neonicotinoids), aldose reductase, aldehyde reductase, or xanthine oxidase. However, the cytosolic metabolism of IMI is inhibited by several aldo-keto-reductase inhibitors (i.e., alrestatin, EBPC, Ponalrestat, phenobarbital, and quercetin). Other neonicotinoids with nitroimine, nitrosoimine, and nitromethylene substituents are probably also metabolized by "neonicotinoid nitro reductase(s)" since they serve as competitive substrates for [(3)H]IMI metabolism.
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PMID:Neonicotinoid insecticides: reduction and cleavage of imidacloprid nitroimine substituent by liver microsomal and cytosolic enzymes. 1223 Apr 9


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