Human Sodium Phosphate Transporter 4 (hNPT4/SLC17A3) as a Common Renal Secretory Pathway for Drugs and Urate

Promsuk Jutabha,Akira Yamada,Hitoshi Endou,George Seki,Tomohisa Katada,Naohiko Anzai,Michael F Wempe,Yoshinori Moriyama,Wako Urano,Shuji Kaneko,Shunya Uchida,Kenichiro Kitamura,Toshiro Fujita,Hideomi Yamada,Hisashi Yamanaka,Kimio Tomita,Toshiyuki Fukutomi,Atsuo Taniguchi,Hiroyuki Sakurai,Yan Kou ,Tōru Kimura ,Hirokazu Shimada

doi:10.1074/jbc.m110.121301

Abstract

The evolutionary loss of hepatic urate oxidase (uricase) has resulted in humans with elevated serum uric acid (urate). Uricase loss may have been beneficial to early primate survival. However, an elevated serum urate has predisposed man to hyperuricemia, a metabolic disturbance leading to gout, hypertension, and various cardiovascular diseases. Human serum urate levels are largely determined by urate reabsorption and secretion in the kidney. Renal urate reabsorption is controlled via two proximal tubular urate transporters: apical URAT1 (SLC22A12) and basolateral URATv1/GLUT9 (SLC2A9). In contrast, the molecular mechanism(s) for renal urate secretion remain unknown. In this report, we demonstrate that an orphan transporter hNPT4 (human sodium phosphate transporter 4; SLC17A3) was a multispecific organic anion efflux transporter expressed in the kidneys and liver. hNPT4 was localized at the apical side of renal tubules and functioned as a voltage-driven urate transporter. Furthermore, loop diuretics, such as furosemide and bumetanide, substantially interacted with hNPT4. Thus, this protein is likely to act as a common secretion route for both drugs and may play an important role in diuretics-induced hyperuricemia. The in vivo role of hNPT4 was suggested by two hyperuricemia patients with missense mutations in SLC17A3. These mutated versions of hNPT4 exhibited reduced urate efflux when they were expressed in Xenopus oocytes. Our findings will complete a model of urate secretion in the renal tubular cell, where intracellular urate taken up via OAT1 and/or OAT3 from the blood exits from the cell into the lumen via hNPT4.

Highlights

Urate is the end product of purine metabolism in humans and certain primates as a result of uricase genetic loss [1]
Our findings will complete a model of urate secretion in the renal tubular cell, where intracellular urate taken up via OAT1 and/or OAT3 from the blood exits from the cell into the lumen via hNPT4
It was demonstrated that luminal urate is taken up by a urate-anion exchanger (URAT1; SLC22A12)3 [6] into the renal proximal tubular cell and that intracellular urate exits the cell into the interstitium/blood space via a voltage-driven urate efflux transporter (URATv1/GLUT9; SLC2A9) [7,8,9]

Summary

Introduction

Urate is the end product of purine metabolism in humans and certain primates as a result of uricase genetic loss (urate oxidase degrades urate to allantoin) [1]. It has been proposed that OAT1 and/or OAT3, located on the basolateral side of renal proximal tubular cell, act as uptake transporters for urate from the interstitium/blood space into the cell [10], but the molecular identity for an apical urate transporter, which excretes intracellular urate to the luminal (urine) space, is elusive. In their genome-wide association study (GWAS), Dehghan et al [11] indicated that SLC17A3 was one of three gene loci associated with uric acid concentration and gout. We show that hNPT4 is the previously unknown urate efflux transporter on the apical side of human renal proximal tubule and is likely to act as an exit path for organic anionic drugs as well as urate in vivo

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