UMLS:C0018099 - FACTA Search

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Query: UMLS:C0018099 (gout)
5,192 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Urate, a purine metabolite, is a cause of gout(hyperuricemia), which is an independent risk factor for cardiovascular disease. Urate is a scavenger of reactive oxygen radicals that are involved in numerous diseases. Because humans have a renal urate reabsorption system and have lost hepatic uricase by mutational silencing in evolution, urate is present in human blood at high levels. We identified the long-hypothesized urate transporter in the human kidney (URAT1, encoded by SLC22A12), a urate anion exchanger regulating blood urate levels and targeted it with uricosuric and antiuricosuric agents. Moreover, we demonstrated that patients with renal hypouricemia have mutational defects in SLC22A12.
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PMID:[Urate transporter and renal hypouricemia]. 1456 Jun 59

In humans, uric acid is the final breakdown product of unwanted purine nucleotides. Uric acid is the last stage in purine degradation, because humans lack the enzyme uricase which converts uric acid into allantoin. Uric acid has profound beneficial effects since it scavenges potential harmful radicals in our body. However, in conjunction with genetic or environmental factors, uric acid can cause significant health problems, leading to kidney stones when it builds up in the kidneys and to gout when crystals accumulate in the joints. The levels of uric acid in the blood must be tightly controlled to minimize these detrimental effects. Normally, the body eliminates enough uric acid in the kidney, and in part also through the intestines, to keep its concentration at a healthy level in the blood (approximately 300 microM). In patients with gout or kidney stone disease, however, the body either produces excessive amounts of uric acid or its ability to eliminate uric acid is disturbed in some way. In the kidney, uric acid is reabsorbed via the uric acid transporter URAT1. This transporter is the major mechanism for regulating blood uric acid levels and therefore may prove an interesting target for future drug development.
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PMID:[Physiology and biochemistry of uric acid]. 1549 12

Humans excrete uric acid as the final breakdown product of unwanted purine nucleotides. Urate scavenges potential harmful radicals in our body. However, in conjunction with genetic or environmental (especially dietary) factors, urate may cause gout, nephrolitiasis, hypertension, and vascular disease. Blood levels of urate are maintained by the balance between generation and excretion. Excretion requires specialized transporters located in renal proximal tubule cells, intestinal epithelial cells, and vascular smooth muscle cells. The recently identified human urate transporters URAT1, MRP4, OAT1, and OAT3 are thought to play central roles in homeostasis and may prove interesting targets for future drug development.
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PMID:Molecular physiology of urate transport. 1577 1

Urate is the major inert end product of purine degradation in higher primates in contrast to most other mammals because of the genetic silencing of hepatic oxidative enzyme uricase. The kidney plays a dominant role in urate elimination. The kidney excretes 70% of the daily urate production. Therefore, it is important to understand renal urate handling mechanism because the under excretion of urate has been implicated in the development of hyperuricemia that leads to gout. The urate transport systems exist in the proximal tubule but they are complicated because of their bidirectional transport and the species differences. Recently, we have identified the urate-anion exchanger URAT1 (SLC22A12) in the human kidney and found that defects in SLC22A12 lead to idiopathic renal hypouricemia. URAT1 is targeted by uricosuric and antiuricosuric agents that affect urate excretion. Molecular identification of urate transporting proteins will lead to the new drug development for hyperuricemia.
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PMID:Renal urate handling: clinical relevance of recent advances. 1591

Serum uric acid levels are maintained by urate synthesis and excretion. URAT1 (coded by SLC22CA12) was recently proposed to be the major absorptive urate transporter protein in the kidney regulating blood urate levels. Because genetic background is known to affect serum urate levels, we hypothesized that genetic variations in SLC22A12 may predispose humans to hyperuricemia and gout. We investigated rs893006 polymorphism (GG, GT and TT) in SLC22A12 in a total of 326 Japanese subjects. Differences in clinical characteristics among the genotype groups were tested by the analysis of variance (ANOVA). In male subjects, mean serum uric acid levels were significantly different among the three genotypes. Levels in the GG genotype subjects were the highest, followed by those with the GT and TT genotypes. However, no differences between the groups were seen in the distributions of creatinine, Fasting plasma glucose (FPG), HbA(1c), total cholesterol, triglyceride, HDL cholesterol levels or BMI. A single nucleotide polymorphism (SNP) in the urate transporter gene SLC22CA12 was found to be associated with elevated serum uric acid levels among Japanese subjects. This SNP may be an independent genetic marker for predicting hyperuricemia.
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PMID:Association between intronic SNP in urate-anion exchanger gene, SLC22A12, and serum uric acid levels in Japanese. 1692 Jan 56

Mechanistic and therapeutic advances in gout have been moving swiftly in the past decade. Clinically, the disease is changing in character. This review discusses several of the pertinent recent developments in understanding gout and in novel therapeutics for the disease. Subjects addressed include the role of URAT1-mediated renal proximal tubule epithelial cell urate anion reabsorption in hyperuricemia. We discuss the therapeutic limitations of allopurinol and uricosurics and the potential applications of novel xanthine oxidase inhibitors and of recombinant uricase preparations. Last, we summarize understanding of the central role of the early induced innate immune response in gouty inflammation, which has suggested the potential value of new strategies for treating gouty inflammation by targeting caspase-1 or IL-1beta.
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PMID:Gout in 2006: the perfect storm. 1712 96

Historical development of gout and hyperuricemia investigations was reviewed. Gout has been a recognized disease since the fifth century B.C. In 1683, Sydenham described the detailed clinical features of the disease based on his own condition. Leeuwenhoek (1679) first described crystals in a gouty tophus, which were identified as uric acid by Wollaston (1797). Since uric acid clearance of hyperuricemia was markedly lower than that in normal controls, early investigators considered that the main cause of hyperuricemia was urate underexcretion. However, in the 1940s, studies on uric acid metabolism using isotope tracer techniques demonstrated that a part of hyperuricemia resulted from urate overproduction, which was detected in approximately one-third of all gouty patients. In the 1970s, micropuncture, microinjection and microperfusion methods as well as stop-flow methods demonstrated that uric acid transports in nephron were suspected to consist of four steps, that were glomerular filtration, reabsorption, secretion and postsecretory reabsorption. The majority of filtrated uric acid was almost completely reabsorbed, followed by secretion and postsecretory reabsorption at a proximal site in the tubulus. Each proportion of transports to the glomerular filtration(100%) was estimated approximately 99%, 50% and 40%, respectively. Subsequently, about 10% of the filtrate was excreted in the urine. The authors (1999) suggested that the secretion rate of hyperuricemic patients was significantly lower than that of normal controls but postsecretory reabsorption was not. Therefore, the decrease in the secretion rate was suspected to be the main cause of underexcretion. Dunkan (1960) reported a family demonstrating hyperuricemia associated with severe renal damage that progressed rapidely. Currently, this disease is called familial juvenile hyperuricemic nephropathy (FJHN), and was recently found to be the result of a variation in uromodulin. Enomoto (2002) found a number of urate transporters in the cell surface of the tubulus, among which URAT1 was the most effective in reabsorbing urate from the tubulus lumen to the cells. The urate was released to the blood vessel side by the other transporter OAT. Therefore, URAT1 was suspected to be a cause of underexcretion. As the mechanism underlying overproduction of uric acid, de novo purine nucleotide synthesis has been shown to be increased. In some cases, the increase in de novo synthesis is the result of gene mutation in purine nucleotide synthesis enzymes, such as PRPP synthetase (Sperling, 1973) as well as hypoxanthine guanine phosphoribosylpyrophosphate synthetase (Seegmiller, 1967). However, the mechanism in majority of the overproduction has not yet been clarified and is currently under investigation.
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PMID:[Historical review of gout and hyperuricemia investigations]. 1840 6

Urate lowering treatment is indicated in patients with recurrent acute attacks, tophi, gouty arthropathy, radiographic changes of gout, multiple joint involvement, or associated uric acid nephrolithiasis. Uricosuric agents like benzbromarone and probenecid are very useful to treat hyperuricemia as well as allopurinol (xanthine oxidase inhibitor). Uricosuric agents act the urate lowering effect through blocking the URAT1, an urate transporter, in brush border of renal proximal tubular cells. In order to avoid the nephrotoxicity and urolithiasis due to increasing of urinary urate excretion by using uricosuric agents, the proper urinary tract management (enough urine volume and correction of aciduria) should be performed.
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PMID:[Uricosuric agent]. 1840 25

An inhibitor of xanthine dehydrogenase (XDH), allopurinol, and uricosuric agents, probenecid and benzbromarone, have been used for more than 20 years in the treatment of hyperuricemia and gout. However, they are inconvenient in some situations. With regard to allopurinol, the dosage reduction is recommended in patients with renal insufficiency for preventing from rare adverse effect, bone marrow depression. Benzbromarone also has quite rare adverse effect, fulminant hepatitis. Recently several new therapies have been developed such as new XDH inhibitors urate transporter (URAT) 1 inhibitor, and a modified recombinant uricase. The dosage reduction of the new XDH inhibitors, febuxostat and FYX-051, is not necessary in patients with renal insufficiency because renal excretion is not main excretory pathway. JTT-552 is a first medicine targeting on URAT1. Polyethylene glycol (PEG) conjugation with recombinant uricase sufficiently reduces the immunogenicity to permit repeated dosing and the clinical trials are ongoing for patients with treatment-failure gout and hyperuricemia.
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PMID:[New antihyperuricemic medicine: febuxostat, Puricase, etc]. 1840 28

Hyperuricemia is a significant factor in a variety of diseases, including gout and cardiovascular diseases. Although renal excretion largely determines plasma urate concentration, the molecular mechanism of renal urate handling remains elusive. Previously, we identified a major urate reabsorptive transporter, URAT1 (SLC22A12), on the apical side of the renal proximal tubular cells. However, it is not known how urate taken up by URAT1 exits from the tubular cell to the systemic circulation. Here, we report that a sugar transport facilitator family member protein GLUT9 (SLC2A9) functions as an efflux transporter of urate from the tubular cell. GLUT9-expressed Xenopus oocytes mediated saturable urate transport (K(m): 365+/-42 microm). The transport was Na(+)-independent and enhanced at high concentrations of extracellular potassium favoring negative to positive potential direction. Substrate specificity and pyrazinoate sensitivity of GLUT9 was distinct from those of URAT1. The in vivo role of GLUT9 is supported by the fact that a renal hypouricemia patient without any mutations in SLC22A12 was found to have a missense mutation in SLC2A9, which reduced urate transport activity in vitro. Based on these data, we propose a novel model of transcellular urate transport in the kidney; urate [corrected] is taken up via apically located URAT1 and exits the cell via basolaterally located GLUT9, which we suggest be renamed URATv1 (voltage-driven urate transporter 1).
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PMID:Plasma urate level is directly regulated by a voltage-driven urate efflux transporter URATv1 (SLC2A9) in humans. 1870 66

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