Including modulation of cell adhesion and differentiation [21,22]. The role of UAT-1 in the physiologic renal tubular transport or intestinal transport (specifically secretion) of urate remains to be established [13]. A number of other organic acid transporters and additional candidate exchangers may also participate in urate handling, particularly at the basolateral membrane of proximal tubule epithelial cells [23-25]. Further insight into the mechanisms that affect renal uric acid excretion has been provided by studies of familial juvenile hyperuricemic nephropathy (FJHN), an autosomal dominantly inherited disorder that is characterized by early onset ofXanthine oxidase in the generation of uric acid and as a drug target for urate-lowering agentsDegradation of purine nucleotides and nucleosides to purine bases yields the key urate precursors hypoxanthine and guanine (Fig. 2). Ordinarily, most of the hypoxanthine and guanine produced is reutilized in a salvage reaction with 5Page 3 of(page number not for citation purposes)Arthritis Research TherapyVol 8 SupplTerkeltaub et al.FigureFigurePX-478 web reactions catalyzed by xanthine oxidase (also known as xanthine oxidoreductase). The enzyme exists in dehydrogenase and oxidase forms, accepting NAD+ in the former conformation and O2 in the latter. Reversible interconversion of the forms involves disulfide bond formation and disruption.FigureXanthine oxidase in the context of purine metabolism. Schematic representation of human purine metabolic pathways, culminating in PubMed ID:https://www.ncbi.nlm.nih.gov/pubmed/29072704 the production of uric acid. Purine nucleotides are synthesized by alternative pathways, each requiring the key regulatory intermediate 5-phosphoribosyl 1-pyrophosphate (PRPP), which is synthesized from ATP and ribose-5-P in a reaction catalyzed by PRPP synthetase. The pathway of purine synthesis de novo involves a sequence of 10 reactions by means of which a purine ring is synthesized on a ribosephosphate backbone donated by PRPP. The first reaction in the pathway is the rate-limiting step and is catalyzed by the enzyme amidophopshoribosyltransferase (AmidoPRT). The subsequent 9 reactions in the de novo pathway are represented by the dashed arrow. The alternative pathways of purine nucleotide synthesis are single step processes by which preformed purine bases (adenine, Ade; hypoxanthine (Hyp); guanine, Gua) are salvaged in reactions catalyzed by the phosphoribosyltransferase (PRT) enzymes adeninePRT (APRT) and hypoxanthine-guanine (HPRT), respectively. Regulation of nucleotide synthesis is effected mainly at the AmidoPRT step, by means of antagonistic allosteric regulation of the activity of AmidoPRT by inhibitory (? purine nucleotide products and PRPP activation. Purine nucleotide products also inhibit PRPP synthetase activity. Purine nucleotides and nucleosides are readily interconverted by means of an extensive and complex series of enzyme-catalyzed reactions that provide the cellular requirements for balanced availability of adenine and guanine nucleotides and nucleosides. Phosphorolysis of the nucleosides inosine and guanosine result in production of Hyp and Gua, which are either salvaged (in the HPRT reaction) or are ultimately and irreversibly oxidized through the base xanthine (Xan) to the end product, uric acid, in reactions catalyzed by xanthine oxidase.Comparison of structures of allopurinol, oxypurinol, and febuxostat. Clinically utilized xanthine oxidase inhibitors. Allopurinol and its oxidation product oxypurinol are hyd.