Your search keyword '"Hosoyamada, M."' showing total 24 results

1. Vitamin C transporter SVCT1 serves a physiological role as a urate importer: functional analyses and in vivo investigations.

Author

Toyoda Y, Miyata H, Uchida N, Morimoto K, Shigesawa R, Kassai H, Nakao K, Tomioka NH, Matsuo H, Ichida K, Hosoyamada M, Aiba A, Suzuki H, and Takada T

Subjects

Animals, Humans, Mice, Amino Acid Sequence, Ascorbic Acid metabolism, Biological Transport, Mammals metabolism, Sodium-Coupled Vitamin C Transporters genetics, Sodium-Coupled Vitamin C Transporters metabolism, Organic Anion Transporters metabolism, Uric Acid metabolism

Abstract

Uric acid, the end product of purine metabolism in humans, is crucial because of its anti-oxidant activity and a causal relationship with hyperuricemia and gout. Several physiologically important urate transporters regulate this water-soluble metabolite in the human body; however, the existence of latent transporters has been suggested in the literature. We focused on the Escherichia coli urate transporter YgfU, a nucleobase-ascorbate transporter (NAT) family member, to address this issue. Only SLC23A proteins are members of the NAT family in humans. Based on the amino acid sequence similarity to YgfU, we hypothesized that SLC23A1, also known as sodium-dependent vitamin C transporter 1 (SVCT1), might be a urate transporter. First, we identified human SVCT1 and mouse Svct1 as sodium-dependent low-affinity/high-capacity urate transporters using mammalian cell-based transport assays. Next, using the CRISPR-Cas9 system followed by the crossing of mice, we generated Svct1 knockout mice lacking both urate transporter 1 and uricase. In the hyperuricemic mice model, serum urate levels were lower than controls, suggesting that Svct1 disruption could reduce serum urate. Given that Svct1 physiologically functions as a renal vitamin C re-absorber, it could also be involved in urate re-uptake from urine, though additional studies are required to obtain deeper insights into the underlying mechanisms. Our findings regarding the dual-substrate specificity of SVCT1 expand the understanding of urate handling systems and functional evolutionary changes in NAT family proteins., (© 2023. The Author(s).)

Published

2023

2. Identification of GLUT12/SLC2A12 as a urate transporter that regulates the blood urate level in hyperuricemia model mice.

Author

Toyoda Y, Takada T, Miyata H, Matsuo H, Kassai H, Nakao K, Nakatochi M, Kawamura Y, Shimizu S, Shinomiya N, Ichida K, Hosoyamada M, Aiba A, and Suzuki H

Subjects

Animals, Gene Expression Regulation, Glucose Transport Proteins, Facilitative genetics, Mice, Mice, Knockout, Uric Acid metabolism, Glucose Transport Proteins, Facilitative metabolism, Hyperuricemia blood, Uric Acid blood

Abstract

Recent genome-wide association studies have revealed some genetic loci associated with serum uric acid levels and susceptibility to gout/hyperuricemia which contain potential candidates of physiologically important urate transporters. One of these novel loci is located upstream of SGK1 and SLC2A12 , suggesting that variations in these genes increase the risks of hyperuricemia and gout. We herein focused on SLC2A12 encoding a transporter, GLUT12, the physiological function of which remains unclear. As GLUT12 belongs to the same protein family as a well-recognized urate transporter GLUT9, we hypothesized that GLUT12 mediates membrane transport of urate. Therefore, we conducted functional assays and analyzed Glut12 knockout hyperuricemia model mice, generated using the CRISPR-Cas9 system. Our results revealed that GLUT12 acts as a physiological urate transporter and its dysfunction elevates the blood urate concentration. This study provides insights into the deeper understanding of the urate regulatory system in the body, which is also important for pathophysiology of gout/hyperuricemia., Competing Interests: The authors declare no competing interest., (Copyright © 2020 the Author(s). Published by PNAS.)

Published

2020

3. Soluble Uric Acid Promotes Atherosclerosis via AMPK (AMP-Activated Protein Kinase)-Mediated Inflammation.

Author

Kimura Y, Yanagida T, Onda A, Tsukui D, Hosoyamada M, and Kono H

Subjects

Adult, Animals, Atherosclerosis blood, Atherosclerosis pathology, Atherosclerosis prevention & control, Benzbromarone administration & dosage, Biomarkers blood, Disease Models, Animal, Enzyme Inhibitors pharmacology, Female, HEK293 Cells, Humans, Hypoxia-Inducible Factor 1, alpha Subunit metabolism, Inflammasomes genetics, Inflammasomes metabolism, Inflammation blood, Inflammation pathology, Inflammation prevention & control, Inflammation Mediators blood, Interleukin-18 blood, Interleukin-1beta blood, Interleukin-1beta genetics, Leukocytes, Mononuclear drug effects, Male, Mice, Inbred C57BL, Mice, Knockout, ApoE, Middle Aged, NLR Family, Pyrin Domain-Containing 3 Protein genetics, NLR Family, Pyrin Domain-Containing 3 Protein metabolism, Nuclear Factor 45 Protein blood, Plaque, Atherosclerotic, Reactive Oxygen Species metabolism, Receptors, LDL deficiency, Receptors, LDL genetics, Urate Oxidase genetics, Urate Oxidase metabolism, Uricosuric Agents administration & dosage, Xanthine Oxidase antagonists & inhibitors, Xanthine Oxidase metabolism, Young Adult, AMP-Activated Protein Kinases metabolism, Atherosclerosis enzymology, Inflammation enzymology, Leukocytes, Mononuclear enzymology, Uric Acid blood

Abstract

Objective: Uric acid is supposed but not yet determined to be associated with atherosclerosis. Uric acid is released from damaged cells to form urate crystal, which is recognized by the immune system to produce IL (interleukin)-1. Danger signals and IL-1 have been shown to play an important role in atherosclerosis. We determined whether the physiological level of soluble uric acid promotes inflammation and develops atherosclerosis. Approach and Results: The secretion of IL-1β from human peripheral blood mononuclear cells mediated by NLRP3 (NACHT, LRR, and PYD domain-containing protein 3) inflammasome was promoted by physiological levels in serum uric acid. This augmentation of inflammation was mediated by the regulation of the AMPK (AMP-activated protein kinase)-mTOR (mammalian target of rapamycin) mitochondrial reactive oxygen species and HIF-1α (hypoxia-inducible factor-1α) pathway. In both of uricase transgenic and xanthine oxidase inhibitor-treated mice, decreased levels of uric acid resulted in the activation of AMPK and attenuation of the development of atherosclerotic plaques. Further, acute uric acid reduction by the administration of benzbromarone in healthy humans for 2 weeks significantly decreased plasma IL-18-an inflammasome-dependent cytokine., Conclusions: The data indicate that the development of atherosclerosis and inflammation is promoted by uric acid in vivo. Moreover, the lowering of uric acid levels attenuated inflammation via the activation of the AMPK pathway. This study provides mechanistic evidence of uric acid-lowering therapies for atherosclerosis.

Published

2020

4. ABCG2 expression and uric acid metabolism of the intestine in hyperuricemia model rat.

Author

Morimoto C, Tamura Y, Asakawa S, Kuribayashi-Okuma E, Nemoto Y, Li J, Murase T, Nakamura T, Hosoyamada M, Uchida S, and Shibata S

Subjects

ATP Binding Cassette Transporter, Subfamily G, Member 2 metabolism, Animals, Hyperuricemia chemically induced, Intestines, Male, Oxonic Acid, Rats, Rats, Sprague-Dawley, Xanthine Dehydrogenase metabolism, ATP Binding Cassette Transporter, Subfamily G, Member 2 genetics, Hyperuricemia metabolism, Uric Acid metabolism

Abstract

To elucidate roles of the intestine in uric acid (UA) metabolism, we examined ABCG2 expression, tissue UA content and xanthine oxidoreductase (XOR) activity in different intestinal segments. Male SD rats were assigned to control group or oxonic acid-induced hyperuricemia (HUA) group. In control rats, ABCG2 was present both in villi and crypts in each segment. Tissue UA content and XOR activity were relatively high in duodenum and jejunum. However, in HUA rats, tissue UA content was significantly elevated in the ileum, whereas it remained unaltered in other segments. Moreover, ABCG2 expression in the HUA group was upregulated both in the villi and crypts of the ileum. These data indicate that the ileum may play an important role in the extra-renal UA excretion.

Published

2020

5. Insulin stimulates uric acid reabsorption via regulating urate transporter 1 and ATP-binding cassette subfamily G member 2.

Author

Toyoki D, Shibata S, Kuribayashi-Okuma E, Xu N, Ishizawa K, Hosoyamada M, and Uchida S

Subjects

Animals, Blood Glucose drug effects, Blood Glucose metabolism, Cell Line, Diabetes Mellitus, Experimental chemically induced, Diabetes Mellitus, Experimental metabolism, Diabetes Mellitus, Experimental physiopathology, Diabetes Mellitus, Type 1 chemically induced, Diabetes Mellitus, Type 1 metabolism, Diabetes Mellitus, Type 1 physiopathology, Glucosides pharmacology, Kidney Tubules metabolism, Kidney Tubules physiopathology, Male, Rats, Sprague-Dawley, Renal Elimination drug effects, Sodium-Glucose Transporter 2 metabolism, Sodium-Glucose Transporter 2 Inhibitors, Streptozocin, Thiophenes pharmacology, Time Factors, Uric Acid urine, ATP Binding Cassette Transporter, Subfamily G, Member 2 metabolism, Anion Transport Proteins metabolism, Diabetes Mellitus, Experimental drug therapy, Diabetes Mellitus, Type 1 drug therapy, Hypoglycemic Agents pharmacology, Insulin pharmacology, Kidney Tubules drug effects, Renal Reabsorption drug effects, Uric Acid metabolism

Abstract

Accumulating data indicate that renal uric acid (UA) handling is altered in diabetes and by hypoglycemic agents. In addition, hyperinsulinemia is associated with hyperuricemia and hypouricosuria. However, the underlying mechanisms remain unclear. In this study, we aimed to investigate how diabetes and hypoglycemic agents alter the levels of renal urate transporters. In insulin-depleted diabetic rats with streptozotocin treatment, both UA excretion and fractional excretion of UA were increased, suggesting that tubular handling of UA is altered in this model. In the membrane fraction of the kidney, the expression of urate transporter 1 (URAT1) was significantly decreased, whereas that of ATP-binding cassette subfamily G member 2 (ABCG2) was increased, consistent with the increased renal UA clearance. Administration of insulin to the diabetic rats decreased UA excretion and alleviated UA transporter-level changes, while sodium glucose cotransporter 2 inhibitor (SGLT2i) ipragliflozin did not change renal UA handling in this model. To confirm the contribution of insulin in the regulation of urate transporters, normal rats received insulin and separately, ipragliflozin. Insulin significantly increased URAT1 and decreased ABCG2 levels, resulting in increased UA reabsorption. In contrast, the SGLT2i did not alter URAT1 or ABCG2 levels, although blood glucose levels were similarly reduced. Furthermore, we found that insulin significantly increased endogenous URAT1 levels in the membrane fraction of NRK-52E cells, the kidney epithelial cell line, demonstrating the direct effects of insulin on renal UA transport mechanisms. These results suggest a previously unrecognized mechanism for the anti-uricosuric effects of insulin and provide novel insights into the renal UA handling in the diabetic state., (Copyright © 2017 the American Physiological Society.)

Published

2017

6. Urinary excretion of uric acid, allantoin, and 8-OH-Deoxyguanosine in uricase-knockout mice.

Author

Inazawa K, Yamaguchi S, Hosoyamada M, Fukuuchi T, Tomioka NH, Yamaoka N, and Kaneko K

Subjects

8-Hydroxy-2'-Deoxyguanosine, Animals, Deoxyguanosine urine, Female, Male, Mice, 129 Strain, Mice, Inbred C57BL, Mice, Knockout, Urate Oxidase metabolism, Allantoin urine, Deoxyguanosine analogs & derivatives, Urate Oxidase genetics, Uric Acid urine

Abstract

Although uricase-knockout (Uox KO) mice are reported to develop uric acid (UA) nephropathy, those that mature without severe nephropathy could be useful for research into purine metabolism in humans. In this study, we measured the urinary excretion of creatinine, UA, allantoin, and 8-hydroxy-2'-deoxyguanosine (8-OHdG) collected from Uox KO mice housed in metabolic cages. UA and allantoin were determined using liquid chromatography-mass spectrometry and creatinine and 8-OHdG were measured with a commercial kit. Uox KO mice excreted significantly higher levels of UA than wild-type mice (C57BL/6), while the excretion of allantoin was significantly lower. Urinary allantoin was detected in Uox KO mice despite a lack of uricase, which is the same as in humans. In contrast to the elevated levels of UA, the daily excretion of 8-OHdG, an oxidative stress marker, was lower in Uox KO mice. UA is thought to act as an anti-oxidizing agent in humans; thus, these results show that Uox KO mice are potential animal models for research into human purine metabolism.

Published

2016

7. Uric acid metabolism of kidney and intestine in a rat model of chronic kidney disease.

Author

Nagura M, Tamura Y, Kumagai T, Hosoyamada M, and Uchida S

Subjects

Animals, Colon metabolism, Creatinine blood, Duodenum metabolism, Gene Expression, Ileum metabolism, Male, Organic Anion Transporters genetics, Organic Anion Transporters metabolism, RNA, Messenger genetics, RNA, Messenger metabolism, Rats, Wistar, Kidney metabolism, Renal Insufficiency, Chronic blood, Uric Acid blood

Abstract

Uric acid (UA) is a potential risk factor of the progression of chronic kidney disease (CKD). Recently, we reported that intestinal UA excretion might be enhanced via upregulation of the ATP-binding cassette transporter G2 (Abcg2) in a 5/6 nephrectomy (Nx) rat model. In the present study, we examined the mRNA and protein expressions of UA transporters, URAT1, GLUT9/URATv1, ABCG2 and NPT4 in the kidney and ileum in the same rat model. Additionally, we investigated the Abcg2 mRNA expression of ileum in hyperuricemic rat model by orally administering oxonic acid. Male Wistar rats were randomly assigned to three groups consisting of Nx group, oxonic acid-treated (Ox) group and sham-operated control group, and sacrificed at 8 weeks. Creatinine and UA were measured and the mRNA expressions of UA transporters in the kidney and intestine were evaluated by a real time PCR. UA transporters in the kidney sections were also examined by immunohistochemistry. Serum creatinine elevated in the Nx group whereas serum UA increased in the Ox group. Both the mRNA expression and the immunohistochemistry of the UA transporters were decreased in the Nx group, suggesting a marginal role in UA elevation in decreased kidney function. In contrast, the mRNA expression of Abcg2 in the ileum significantly increased in the Ox group. These results suggest that the upregulation of Abcg2 mRNA in the ileum triggered by an elevation of serum UA may play a compensatory role in increasing intestinal UA excretion.

Published

2016

8. The Mechanism of False in Vitro Elevation of Uric Acid Level in Mouse Blood.

Author

Watanabe T, Tomioka NH, Watanabe S, Suzuki Y, Tsuchiya M, and Hosoyamada M

Subjects

Animals, Hypoxanthine blood, Male, Mice, Inbred C57BL, Mice, Knockout, Xanthine blood, Hypoxanthine Phosphoribosyltransferase genetics, Urate Oxidase genetics, Uric Acid blood

Abstract

Thirty minutes incubation at room temperature elevates the uric acid (UA) level of mouse blood in a test tube, and has previously been reported as "false in vitro elevation of the uric acid level." However the UA level of human blood does not elevate using the same incubation. We clarified the mechanism of the false in vitro UA elevation using mice with highly active hypoxanthine phosphoribosyl transferase (Hprt) of B6-ChrXC(MSM), a consomic mouse strain with the chromosome portion of Mus musculus morocinus in the Hprt gene site, or mice with a targeted deletion of the urate oxidase gene (Uox) (Uox-knockout (KO)). The plasma levels of UA, hypoxanthine, and xanthine, determined by HPLC, were compared with those of C57BL/6J laboratory mice used as controls. The uric acid level of Uox-KO mice was approximately 10 times higher than that of control, did not elevated after incubation in the test tube. With allopurinol, the hypoxanthine levels of B6-ChrXC(MSM) and Uox-KO were significantly lower than that of controls. Without allopurinol, the UA and xanthine levels of B6-ChrXC(MSM) were significantly lower than those of C57BL/6J controls. Even with allopurinol, the UA and xanthine levels were still significantly lower than that of controls. In conclusion, "false in vitro elevation of uric acid level" seems to be caused by low levels of erythrocyte HPRT activity and the low plasma uric acid level of laboratory mice.

Published

2016

9. Targeting Uric Acid and the Inhibition of Progression to End-Stage Renal Disease--A Propensity Score Analysis.

Author

Uchida S, Chang WX, Ota T, Tamura Y, Shiraishi T, Kumagai T, Shibata S, Fujigaki Y, Hosoyamada M, Kaneko K, Shen ZY, and Fujimori S

Subjects

Adult, Aged, Aged, 80 and over, Disease Progression, Female, Follow-Up Studies, Humans, Male, Middle Aged, Models, Statistical, Prognosis, Proportional Hazards Models, Retrospective Studies, Risk Factors, Young Adult, Biomarkers blood, Kidney Failure, Chronic blood, Kidney Failure, Chronic pathology, Propensity Score, Uric Acid blood

Abstract

Background: The role of uric acid (UA) in the progression of chronic kidney disease (CKD) remains controversial due to the unavoidable cause and result relationship. This study was aimed to clarify the independent impact of UA on the subsequent risk of end-stage renal disease (ESRD) by a propensity score analysis., Methods: A retrospective CKD cohort was used (n = 803). Baseline 23 covariates were subjected to a multivariate binary logistic regression with the targeted time-averaged UA of 6.0, 6.5 or 7.0 mg/dL. The participants trimmed 2.5 percentile from the extreme ends of the cohort underwent propensity score analyses consisting of matching, stratification on quintile and covariate adjustment. Covariate balances after 1:1 matching without replacement were tested for by paired analysis and standardized differences. A stratified Cox regression and a Cox regression adjusted for logit of propensity scores were examined., Results: After propensity score matching, the higher UA showed elevated hazard ratios (HRs) by Kaplan-Meier analysis (≥ 6.0 mg/dL, HR 4.53, 95%CI 1.79-11.43; ≥ 6.5 mg/dL, HR 3.39, 95%CI 1.55-7.42; ≥ 7.0 mg/dL, HR 2.19, 95%CI 1.28-3.75). The number needed to treat was 8 to 9 over 5 years. A stratified Cox regression likewise showed significant crude HRs (≥ 6.0 mg/dL, HR 3.63, 95%CI 1.25-10.58; ≥ 6.5 mg/dL, HR 3.46, 95%CI 1.56-7.68; ≥ 7.0 mg/dL, HR 2.05, 95%CI 1.21-3.48). Adjusted HR lost its significance at 6.0 mg/dL. The adjustment for the logit of the propensity scores showed the similar results but with worse model fittings than the stratification method. Upon further adjustment for other covariates the significance was attained at 6.5 mg/dL., Conclusions: Three different methods of the propensity score analysis showed consistent results that the higher UA accelerates the progression to the subsequent ESRD. A stratified Cox regression outperforms other methods in generalizability and adjusting for residual bias. Serum UA should be targeted less than 6.5 mg/dL.

Published

2015

10. False in vitro and in vivo elevations of uric acid levels in mouse blood.

Author

Watanabe T, Tomioka NH, Watanabe S, Tsuchiya M, and Hosoyamada M

Subjects

Allopurinol pharmacology, Animals, Blood Specimen Collection, False Positive Reactions, Male, Mice, Mice, Inbred ICR, Phentolamine pharmacology, Time Factors, Blood Chemical Analysis methods, Uric Acid blood

Abstract

Uric acid (UA) levels in mouse blood have been reported to range widely from 0.1 μM to 760 μM. The aim of this study was to demonstrate false in vitro and in vivo elevations of UA levels in mouse blood. Male ICR mice were anesthetized with pentobarbital (breathing mice) or sacrificed with overdose ether (non-breathing mice). Collected blood was dispensed into MiniCollect® tubes and incubated in vitro for 0 or 30 min at room temperature. After separation of plasma or serum, the levels of UA and hypoxanthine were determined using HPLC. From the non-incubated plasma of breathing mice, the true value of UA level in vivo was 13.5±1.4 μM. However, UA levels in mouse blood increased by a factor of 3.9 following incubation in vitro. This "false in vitro elevation" of UA levels in mouse blood after blood sampling was inhibited by allopurinol, a xanthine oxidase inhibitor. Xanthine oxidase was converted to UA in mouse serum from hypoxanthine which was released from blood cells during incubation. Plasma UA levels from non-breathing mice were 19 times higher than those from breathing mice. This "false in vivo elevation" of UA levels before blood sampling was inhibited by pre-treatment with phentolamine, an α-antagonist. Over-anesthesia with ether might induce α-vasoconstriction and ischemia and thus degrade intracellular ATP to UA. For the accurate measurement of UA levels in mouse blood, the false in vitro and in vivo elevations of UA level must be avoided by immediate separation of plasma after blood sampling from anesthetized breathing mice.

Published

2014

11. Decreased extra-renal urate excretion is a common cause of hyperuricemia.

Author

Ichida K, Matsuo H, Takada T, Nakayama A, Murakami K, Shimizu T, Yamanashi Y, Kasuga H, Nakashima H, Nakamura T, Takada Y, Kawamura Y, Inoue H, Okada C, Utsumi Y, Ikebuchi Y, Ito K, Nakamura M, Shinohara Y, Hosoyamada M, Sakurai Y, Shinomiya N, Hosoya T, and Suzuki H

Subjects

ATP Binding Cassette Transporter, Subfamily G, Member 2, ATP-Binding Cassette Transporters genetics, ATP-Binding Cassette Transporters metabolism, Adult, Aged, Animals, Biological Transport, Down-Regulation, Humans, Hyperuricemia genetics, Hyperuricemia physiopathology, Kidney physiopathology, Male, Mice, Mice, Knockout, Middle Aged, Neoplasm Proteins genetics, Neoplasm Proteins metabolism, Hyperuricemia metabolism, Kidney metabolism, Uric Acid metabolism

Abstract

ABCG2, also known as BCRP, is a high-capacity urate exporter, the dysfunction of which raises gout/hyperuricemia risk. Generally, hyperuricemia has been classified into urate 'overproduction type' and/or 'underexcretion type' based solely on renal urate excretion, without considering an extra-renal pathway. Here we show that decreased extra-renal urate excretion caused by ABCG2 dysfunction is a common mechanism of hyperuricemia. Clinical parameters, including urinary urate excretion, are examined in 644 male outpatients with hyperuricemia. Paradoxically, ABCG2 export dysfunction significantly increases urinary urate excretion and risk ratio of urate overproduction. Abcg2-knockout mice show increased serum uric acid levels and renal urate excretion, and decreased intestinal urate excretion. Together with high ABCG2 expression in extra-renal tissues, our data suggest that the 'overproduction type' in the current concept of hyperuricemia be renamed 'renal overload type', which consists of two subtypes-'extra-renal urate underexcretion' and genuine 'urate overproduction'-providing a new concept valuable for the treatment of hyperuricemia and gout.

Published

2012

12. The effect of female hormones upon urate transport systems in the mouse kidney.

Author

Takiue Y, Hosoyamada M, Kimura M, and Saito H

Subjects

ATP Binding Cassette Transporter, Subfamily G, Member 2, ATP-Binding Cassette Transporters genetics, Animals, Cation Transport Proteins genetics, Female, Glucose Transport Proteins, Facilitative genetics, Mice, Mice, Inbred ICR, Monocarboxylic Acid Transporters, Organic Anion Transporters genetics, Ovariectomy, RNA, Messenger genetics, RNA, Messenger metabolism, Estradiol pharmacology, Kidney drug effects, Kidney metabolism, Progesterone pharmacology, Uric Acid metabolism

Abstract

Increased levels of serum urate in postmenopausal women are thought to be caused by a change in renal urate elimination associated with the loss of female hormones. In this study, we investigated the regulation of renal urate transporter expression by female hormones using ovariectomized mice with or without hormone replacement. Estradiol suppressed the protein levels of urate reabsorptive transporters urate transporter 1 and glucose transporter 9 (Urat1 and Glut9), and that of urate efflux transporter ATP-binding cassette sub-family G member 2 (Abcg2). Progesterone suppressed protein levels of sodium-coupled monocarboxylate transporter 1 (Smct1). However, neither estradiol nor progesterone influenced the respective levels of mRNA.

Published

2011

13. The effect of testosterone upon the urate reabsorptive transport system in mouse kidney.

Author

Hosoyamada M, Takiue Y, Shibasaki T, and Saito H

Subjects

Animals, Biological Transport drug effects, Case-Control Studies, Glucose Transport Proteins, Facilitative genetics, Glucose Transport Proteins, Facilitative metabolism, Hyperuricemia metabolism, Hyperuricemia physiopathology, Kidney physiology, Male, Mice, Mice, Inbred ICR, Monocarboxylic Acid Transporters genetics, Monocarboxylic Acid Transporters metabolism, Orchiectomy, Organic Anion Transporters genetics, Organic Anion Transporters metabolism, RNA, Messenger genetics, RNA, Messenger metabolism, Symporters genetics, Symporters metabolism, Uric Acid blood, Uric Acid urine, Kidney drug effects, Kidney metabolism, Testosterone pharmacology, Uric Acid metabolism

Abstract

It is hypothesized that hyperuricemia in males is caused by androgen-induced urate reabsorptive transport system in the kidney. The expression of urate transporter 1 (Urat1), sodium-coupled monocarboxylate transporter 1 (Smct1) and glucose transporter 9 (Glut9) were investigated in orchiectomized mice with or without testosterone replacement. Testosterone enhanced mRNA and protein levels of Smct1 while those of Glut9 were attenuated. Although the mRNA level of Urat1 was enhanced by testosterone, the corresponding levels of Urat1 protein remained unaffected. Thus, the induction of Smct1 by testosterone is a candidate mechanism underlying hyperuricemia in males.

Published

2010

14. Age and origin of the G774A mutation in SLC22A12 causing renal hypouricemia in Japanese.

Author

Ichida K, Hosoyamada M, Kamatani N, Kamitsuji S, Hisatome I, Shibasaki T, and Hosoya T

Subjects

Age Factors, Asian People genetics, Female, Haplotypes, Homozygote, Humans, Japan, Kidney Diseases ethnology, Kidney Diseases metabolism, Linkage Disequilibrium, Male, Polymorphism, Single Nucleotide, Kidney Diseases genetics, Organic Anion Transporters genetics, Organic Cation Transport Proteins genetics, Point Mutation, Uric Acid metabolism

Abstract

Renal hypouricemia is an inherited disorder characterized by impaired tubular uric acid transport. Impairment of the function of URAT1, the main transporter for the reabsorption of uric acid at the apical membrane of the renal tubules, causes renal hypouricemia. The G774A mutation in the SLC22A12 gene encoding URAT1 predominates in Japanese renal hypouricemia. From data on linkage disequilibrium between the G774 locus and the 13 markers flanking it (12 single nucleotide polymorphisms and 1 dinucleotide insertion/deletion locus), we here estimate the age of this mutation at approximately 6820 years [95% confidence interval (CI) 1860-11,760 years; median = 2460 years]. This indicates that the origin of the G774A mutation dates back from between the time when the Jomon people predominated in Japan and the time when the Yayoi people started to migrate to Japan from the Korean peninsula. These data are consistent with a recent finding that this G774A mutation was also predominant in Koreans with hypouricemia and indicate that the mutation originated on the Asian continent. Thus, this mutation found in Japanese patients was originally brought by immigrant(s) from the continent and thereafter expanded in the Japanese population either by founder effects or by genetic drift (or both).

Published

2008

15. [Molecular mechanism in biological transport in the kidney: Urate transporter URAT1].

Author

Hosoyamada M, Shibasaki T, and Ichida K

Subjects

Animals, Benzbromarone pharmacology, Benzbromarone therapeutic use, Carrier Proteins antagonists & inhibitors, Carrier Proteins chemistry, Carrier Proteins genetics, Humans, Hyperuricemia drug therapy, Organic Anion Transporters antagonists & inhibitors, Organic Anion Transporters chemistry, Organic Anion Transporters genetics, Organic Cation Transport Proteins, Probenecid pharmacology, Probenecid therapeutic use, RNA, Messenger, Transcription, Genetic, Uric Acid blood, Uricosuric Agents pharmacology, Uricosuric Agents therapeutic use, Carrier Proteins physiology, Kidney Tubules metabolism, Organic Anion Transporters physiology, Uric Acid metabolism

Published

2006

16. Uric acid causes vascular smooth muscle cell proliferation by entering cells via a functional urate transporter.

Author

Kang DH, Han L, Ouyang X, Kahn AM, Kanellis J, Li P, Feng L, Nakagawa T, Watanabe S, Hosoyamada M, Endou H, Lipkowitz M, Abramson R, Mu W, and Johnson RJ

Subjects

Animals, Cell Proliferation drug effects, Cells, Cultured, Chemokine CCL2 antagonists & inhibitors, Chemokine CCL2 biosynthesis, Myocytes, Smooth Muscle metabolism, Organic Anion Transporters antagonists & inhibitors, Probenecid pharmacology, Rats, Reverse Transcriptase Polymerase Chain Reaction, Muscle, Smooth, Vascular cytology, Muscle, Smooth, Vascular metabolism, Myocytes, Smooth Muscle cytology, Organic Anion Transporters metabolism, Uric Acid pharmacokinetics, Uric Acid pharmacology

Abstract

Background: Soluble uric acid stimulates vascular smooth muscle cell (VSMC) proliferation by activating mitogen-activated protein kinases, and stimulating COX-2 and PDGF synthesis. The mechanism by which uric acid enters the VSMC is not known. We hypothesized that uric acid enters via transporters similar to that observed in the kidney., Methods: We studied the uptake of uric acid into rat VSMC under polarized and depolarized conditions and in the presence of organic anion transport (OAT) inhibitors (probenecid and benzbromarone) or p-aminohippurate (PAH). We also examined the ability of probenecid to inhibit uric acid-induced VSMC proliferation and monocyte chemoattractant protein-1 (MCP-1) synthesis., Results: (14)C-Urate uptake was shown in VSMC and was enhanced under depolarized conditions. (14)C-Uric acid uptake was inhibited by probenecid and benzbromarone, as well as by unlabelled urate and PAH. Probenecid blocked VSMC proliferation and MCP-1 expression in response to uric acid. VSMC did not express rOAT1-3, rOAT-5 or URAT-1 mRNA by PCR, but did express the voltage-sensitive transporter (UAT) by both PCR and RNase protection assay., Conclusions: Urate enters VSMC by both voltage-sensitive and OAT pathways, and the uptake, cell proliferation and MCP-1 expression can be blocked by OAT inhibitors. The specific transporter(s) responsible for the urate uptake remains to be determined., (Copyright (c) 2005 S. Karger AG, Basel.)

Published

2005

17. Mutations in human urate transporter 1 gene in presecretory reabsorption defect type of familial renal hypouricemia.

Author

Wakida N, Tuyen DG, Adachi M, Miyoshi T, Nonoguchi H, Oka T, Ueda O, Tazawa M, Kurihara S, Yoneta Y, Shimada H, Oda T, Kikuchi Y, Matsuo H, Hosoyamada M, Endou H, Otagiri M, Tomita K, and Kitamura K

Subjects

Adolescent, Adult, Aged, Child, Female, Genotype, Humans, Male, Microsatellite Repeats, Middle Aged, Organic Cation Transport Proteins, Carrier Proteins genetics, Mutation, Organic Anion Transporters genetics, Renal Tubular Transport, Inborn Errors genetics, Uric Acid metabolism

Abstract

To date, 11 loss of function mutations in the human urate transporter 1 (hURAT1) gene have been identified in subjects with idiopathic renal hypouricemia. In the present studies we investigated the clinical features and the mutations in the hURAT1 gene in seven families with presecretory reabsorption defect-type renal hypouricemia and in one family with the postsecretory reabsorption defect type. Twelve affected subjects and 26 family members were investigated. Mutations were analyzed by PCR and the direct sequencing method. Urate-transporting activities of wild-type and mutant hURAT1 were determined by [14C]urate uptake in Xenopus oocytes. Mutational analysis revealed three previously reported mutations (G774A, A1145T, and 1639-1643 del-GTCCT) and a novel mutation (T1253G) in families with the presecretory reabsorption defect type. Neither mutations in the coding region of hURAT1 gene nor significant segregation patterns of the hURAT1 locus were detected in the postsecretory reabsorption defect type. All hURAT1 mutants had significantly reduced urate-transporting activities compared with wild type (P < 0.05; n = 12), suggesting that T1253G is a loss of function mutation, and hURAT1 is responsible for the presecretory reabsorption defect-type familial renal hypouricemia. Future studies are needed to identify a responsible gene for the postsecretory reabsorption defect-type familial renal hypouricemia.

Published

2005

18. A high prevalence of renal hypouricemia caused by inactive SLC22A12 in Japanese.

Author

Iwai N, Mino Y, Hosoyamada M, Tago N, Kokubo Y, and Endou H

Subjects

Adult, Aged, Base Sequence, Carrier Proteins metabolism, Cohort Studies, Female, Haplotypes, Humans, Hyperuricemia blood, Hyperuricemia epidemiology, Hyperuricemia genetics, Japan epidemiology, Kidney Diseases blood, Male, Middle Aged, Molecular Sequence Data, Mutation, Missense, Organic Anion Transporters metabolism, Organic Cation Transport Proteins, Phenotype, Polymorphism, Genetic, Prevalence, Carrier Proteins genetics, Kidney Diseases epidemiology, Kidney Diseases genetics, Organic Anion Transporters genetics, Uric Acid blood

Abstract

Background: Recently, SLC22A12 has been identified as a urate-anion exchanger in the human kidney., Methods: We screened for polymorphisms of SLC22A12 and conducted an association study between genetic polymorphisms and urate levels in an epidemiologic cohort representing the general population in Japan. Functional significance of mutations was assessed by oocyte expression analysis., Results: We found five missense, one nonsense, and one deletion mutations [R90H, A226V, R228E, W258Stop, Q312L, D313A (deletion of 313D-333P), and R477H] in 24 subjects with hypouricemia recruited from an epidemiologic cohort (Suita Study) representing the general population in Japan (N= 1875). A statistical analysis indicated that the 90H (N= 14), 477H (N= 5), and 258Stop (hetero + homo N= 82 + 3) alleles were associated with hypouricemia. The alleles 228E and 313A (deletion of 313D-333P) were found just once in the total population. In vitro oocyte expression analysis indicated that 313A (deletion of 313D-333P) had no urate transport activity, indicating that this is a newly identified mutation for idiopathic renal hypouricemia. Intriguingly, the allele frequency of 258Stop was unexpectedly high (2.37%). However, this inactivating mutation does not seem to be harmful in the general population. The effects of common polymorphisms of SLC22A12 were also investigated. Based on linkage disequilibrium, 16 common polymorphisms were categorized into six distinct groups, and six representative genotypes were determined. None of these six common polymorphisms affected the serum uric acid level. A haplotype analysis also suggested that these common genotypes/haplotypes were not important in determining the serum uric acid levels in the general population., Conclusion: SLC22A12 is a major gene for hypouricemia but not hyperuricemia in Japanese.

Published

2004

19. Function and localization of urate transporter 1 in mouse kidney.

Author

Hosoyamada M, Ichida K, Enomoto A, Hosoya T, and Endou H

Subjects

Amino Acid Sequence, Animals, Female, Male, Mice, Molecular Sequence Data, Organic Cation Transport Proteins, Carrier Proteins physiology, Kidney metabolism, Membrane Proteins physiology, Organic Anion Transporters physiology, Uric Acid metabolism

Abstract

Mouse renal-specific transporter (RST) cDNA, the amino acid sequence of which has 74% identity with that of human urate transporter 1 (hURAT1), is potentially the mouse homologue of hURAT1, the gene responsible for hereditary renal hypouricemia. The aim of this study is to determine the location and characteristics of RST molecule in mouse kidney and investigate urate transport by RST using the Xenopus oocyte expression system. RST transported (14)C-urate in a Michaelis-Menten manner. The K(m) and the V(max) values of RST-dependent urate transport were 1213 +/- 222 micro M and 268.8 +/- 38.0 pmol/oocyte per hr, respectively (n = 3). RST-dependent urate transport was cis-inhibited significantly by 1 mM probenecid (68.7 +/- 9.4%), 50 micro M benzbromarone (67.9 +/- 6.4%), and 10 mM lactate (50.9 +/- 9.5%). However, 1 mM p-aminohippurate (PAH), 1 mM xanthine, and 1 mM oxonate did not inhibit RST-dependent urate transport. Substitution of Cl anion with gluconate in the external solution enhanced RST-dependent urate transport. Pre-injected pyrazinoic acid (PZA) or L-lactate trans-stimulated RST-dependent urate transport. Using immunohistochemistry for mouse kidney, the brush border or intracellular membrane of proximal tubules was stained by an affinity-purified antibody that recognized mouse URAT1 (mURAT1) expressed on Xenopus oocyte. Using Western blotting, anti-mURAT1 antibody detected 70-kD and 62-kD protein bands. The 70-kD protein was N-glycosylated and was identified as a Triton X-100 insoluble brush border membrane protein. RST mRNA and protein levels were higher in male kidneys than female. RST transported urate similar to hURAT1 and, therefore, appears to be mURAT1-the mouse homologue of hURAT1.

Published

2004

20. Clinical and molecular analysis of patients with renal hypouricemia in Japan-influence of URAT1 gene on urinary urate excretion.

Author

Ichida K, Hosoyamada M, Hisatome I, Enomoto A, Hikita M, Endou H, and Hosoya T

Subjects

Female, Genotype, Humans, Japan, Male, Mutation, Organic Cation Transport Proteins, Phenotype, Protein Structure, Secondary, Carrier Proteins genetics, Kidney Diseases genetics, Kidney Diseases urine, Organic Anion Transporters genetics, Uric Acid urine

Abstract

Renal hypouricemia is an inherited and heterogeneous disorder characterized by increased urate clearance (CUA). The authors recently established that urate was reabsorbed via URAT1 on the tubular apical membrane and that mutations in SLC22A12 encoding URAT1 cause renal hypouricemia. This study was undertaken to elucidate and correlate clinical and genetic features of renal hypouricemia. The SLC22A12 gene was sequenced in 32 unrelated idiopathic renal hypouricemia patients, and the relationships of serum urate levels, and CUA/creatinine clearance (Ccr) to SLC22A12 genotype were examined. Uricosuric (probenecid and benzbromarone) and anti-uricosuric drug (pyrazinamide) loading tests were also performed in some patients. Three patients had exercise-induced acute renal failure (9.4%), and four patients had urolithiasis (12.5%). The authors identified eight new mutations and two previously reported mutations that result in loss of function. Thirty patients had SLC22A12 mutations; 24 homozygotes and compound heterozygotes, and 6 heterozygotes. Mutation G774A dominated SLC22A12 mutations (74.1% in 54 alleles). Serum urate levels were significantly lower and CUA/Ccr was significantly higher in heterozygotes compared with healthy subjects; these changes were even more significant in homozygotes and compound heterozygotes. These CUA/Ccr relations demonstrated a gene dosage effect that corresponds with the difference in serum urate levels. In contrast to healthy subjects, the CUA/Ccr of patients with homozygous and compound heterozygous SLC22A12 mutations was unaffected by pyrazinamide, benzbromarone, and probenecid. The findings indicate that SLC22A12 was responsible for most renal hypouricemia and that URAT1 is the primary reabsorptive urate transporter, targeted by pyrazinamide, benzbromarone, and probenecid in vivo.

Published

2004

21. Two male siblings with hereditary renal hypouricemia and exercise-induced ARF.

Author

Tanaka M, Itoh K, Matsushita K, Matsushita K, Wakita N, Adachi M, Nonoguchi H, Kitamura K, Hosoyamada M, Endou H, and Tomita K

Subjects

Acute Kidney Injury genetics, Adult, Back Pain etiology, Carrier Proteins genetics, Codon, Nonsense, Creatinine blood, Exons genetics, Humans, Kidney Function Tests, Male, Metabolism, Inborn Errors blood, Metabolism, Inborn Errors genetics, Middle Aged, Organic Anion Transporters genetics, Organic Cation Transport Proteins, Pedigree, Probenecid, Pyrazinamide, Running, Uric Acid urine, Urinary Calculi etiology, Acute Kidney Injury etiology, Exercise, Metabolism, Inborn Errors complications, Organic Anion Transporters deficiency, Uric Acid blood

Abstract

Familial renal hypouricemia with exercise-induced acute renal failure (ARF) is rare. A 45-year-old man presented with abdominal pain, vomiting, and oliguria after severe exercise. The diagnosis was ARF based on high serum creatinine (SCr) level (5.1 mg/dL [451 micromol/L]). Renal function recovered completely within 2 weeks of conservative treatment (creatinine clearance [Ccr], 100.4 mL/min [1.67 mL/s]). After remission, laboratory results showed serum urate (SUA) of 0.8 mg/dL (48 micromol/L), and fractional excretion of uric acid (FE(UA)) of 46%. The final diagnosis was ARF associated with idiopathic renal hypouricemia. Other diseases that could increase the excretion of urate were excluded. Because only mild responses were observed both in pyradinamide and benzbromarone loading tests, he was considered to be a presecretory reabsorption disorder type. The younger brother (42 years old) also had episodes of low and middle back pain after severe exercise and experienced similar attacks at least 5 times since the age of 29. SCr level was elevated in every attack. Hypouricemia (SUA, 1.0 mg/dL [59 micromol/L]) and high urinary urate excretion (FE(UA), 65.7%) also were detected. Renal function recovered almost completely without any specific treatment. Radiologic examination of the 2 cases showed bilateral urolithiasis probably caused by the high urinary urate excretion. Sequence analysis of a urate anion exchanger known to regulate blood urate level (URAT1 gene) in both brothers showed homozygous mutation in exon 4 (W258Stop), resulting in a premature truncated URAT1 protein. Both their parents and their children showed heterozygous mutation of the URAT1 gene. This is the first report of the 2 male siblings of familial renal hypouricemia complicated with exercise-induced ARF, with definite demonstration of genetic abnormality in the responsible gene (URAT1).

Published

2003

22. Urate transport via human PAH transporter hOAT1 and its gene structure.

Author

Ichida K, Hosoyamada M, Kimura H, Takeda M, Utsunomiya Y, Hosoya T, and Endou H

Subjects

Anti-Inflammatory Agents, Non-Steroidal pharmacology, Benzbromarone pharmacology, Biological Transport drug effects, Biological Transport physiology, Blotting, Western, Carbon Radioisotopes, Cell Line, Cloning, Molecular, Exons, Female, Gene Library, Gout metabolism, Humans, Kidney metabolism, Kidney Diseases metabolism, Organic Anion Transport Protein 1 chemistry, Probenecid pharmacology, Protein Structure, Tertiary, Pyrazinamide pharmacology, Sodium Salicylate pharmacology, Uricosuric Agents pharmacology, p-Aminohippuric Acid pharmacokinetics, Gout genetics, Kidney Diseases genetics, Organic Anion Transport Protein 1 genetics, Organic Anion Transport Protein 1 metabolism, Pyrazinamide analogs & derivatives, Uric Acid metabolism

Abstract

Background: We recently cloned the human organic anion transporter 1 (hOAT1) as a p-aminohippurate (PAH) transporter. Whether urate is transported by the PAH transporter in humans remains unclear. Familial juvenile gouty nephropathy (FJGN) is thought to develop as a result of an abnormality in the urate transporter., Methods: To determine if hOAT1 transported urate, the cellular uptakes of PAH and urate were determined, as were the inhibition profiles of inorganic anions, and uricosuric and antiuricosuric agents using a mouse S2 cell line expressing hOAT1. The hOAT1 gene was cloned from a genomic library using full-length hOAT1-1 cDNA as a probe. The coding regions of the hOAT1 genes of two sisters with FJGN were sequenced. Also, immunohistochemical fluorescence analysis of hOAT1 in the kidney of the younger sister with FJGN was performed., Results: The Km and Vmax values of urate transport via hOAT1 were 943 +/- 84 micromol/L and 1286 +/- 162 pmol/mg protein/min, respectively. The order of the IC50 of urate transport via hOAT1 was benzbromarone < probenecid < salicylate or pyrazine carboxylic acid. The 10.9 kb hOAT1 gene was found to be interrupted by nine introns. Mutations in the coding region of the hOAT1 gene from the two sisters with FJGN were undetectable. Immunohistochemical fluorescent staining showed that hOAT1 in the kidney of the younger sister was similar to that of control individuals., Conclusions: Our data show that hOAT1 transports urate, and the inhibition profiles of uricosuric and antiuricosuric agents are defined. hOAT1 is not responsible for FJGN in the two sisters examined in this study.

Published

2003

23. Molecular identification of a renal urate anion exchanger that regulates blood urate levels.

Author

Enomoto A, Kimura H, Chairoungdua A, Shigeta Y, Jutabha P, Cha SH, Hosoyamada M, Takeda M, Sekine T, Igarashi T, Matsuo H, Kikuchi Y, Oda T, Ichida K, Hosoya T, Shimokata K, Niwa T, Kanai Y, and Endou H

Subjects

Amino Acid Sequence, Animals, Anions metabolism, Biological Transport, Carrier Proteins chemistry, Cloning, Molecular, Humans, Immunohistochemistry, Kidney metabolism, Kidney Tubules, Proximal chemistry, Kidney Tubules, Proximal metabolism, Molecular Sequence Data, Mutation, Oocytes metabolism, Organic Cation Transport Proteins, RNA, Messenger genetics, RNA, Messenger metabolism, Substrate Specificity, Uric Acid metabolism, Xenopus, Anions blood, Carrier Proteins genetics, Carrier Proteins metabolism, Kidney chemistry, Organic Anion Transporters, Uric Acid blood

Abstract

Urate, a naturally occurring product of purine metabolism, is a scavenger of biological oxidants implicated in numerous disease processes, as demonstrated by its capacity of neuroprotection. It is present at higher levels in human blood (200 500 microM) than in other mammals, because humans have an effective renal urate reabsorption system, despite their evolutionary loss of hepatic uricase by mutational silencing. The molecular basis for urate handling in the human kidney remains unclear because of difficulties in understanding diverse urate transport systems and species differences. Here we identify the long-hypothesized urate transporter in the human kidney (URAT1, encoded by SLC22A12), a urate anion exchanger regulating blood urate levels and targeted by uricosuric and antiuricosuric agents (which affect excretion of uric acid). Moreover, we provide evidence that patients with idiopathic renal hypouricaemia (lack of blood uric acid) have defects in SLC22A12. Identification of URAT1 should provide insights into the nature of urate homeostasis, as well as lead to the development of better agents against hyperuricaemia, a disadvantage concomitant with human evolution.

Published

2002

24. GWAS of clinically defined gout and subtypes identifies multiple susceptibility loci that include urate transporter genes

Author

Nakayama, A., Nakaoka, H., Yamamoto, K., Sakiyama, M., Shaukat, A., Toyoda, Y., Okada, Y., Kamatani, Y., Nakamura, T., Takada, T., Inoue, K., Yasujima, T., Yuasa, H., Shirahama, Y., Nakashima, H., Shimizu, S., Higashino, T., Kawamura, Y., Ogata, H., Kawaguchi, M., Ohkawa, Y., Danjoh, I., Tokumasu, A., Ooyama, K., Ito, T., Kondo, T., Wakai, K., Stiburkova, B., Pavelka, K., Stamp, L.K., Dalbeth, N., Sakurai, Y., Suzuki, H, Hosoyamada, M., Fujimori, S., Yokoo, T., Hosoya, T., Inoue, I., Takahashi, A., Kubo, M., Ooyama, H., Shimizu, T., Ichida, K., Shinomiya, N., Merriman, T.R., Matsuo, H., Andres, M, Joosten, L.A., Janssen, M.C.H., Jansen, T.L., Liote, F., Radstake, T.R., Riches, P.L., So, A., and Tauches, A.K.

Subjects

0301 basic medicine, Male, Native Hawaiian or Other Pacific Islander, Gout, lnfectious Diseases and Global Health Radboud Institute for Molecular Life Sciences [Radboudumc 4], Organic Anion Transporters, Genome-wide association study, Cell Cycle Proteins, Urate transport, Histones, chemistry.chemical_compound, 0302 clinical medicine, Japan, Immunology and Allergy, Medicine, Cation Transport Proteins, Genetics, biology, Metabolic Disorders Radboud Institute for Molecular Life Sciences [Radboudumc 6], Middle Aged, DNA-Binding Proteins, SLC22A12, Sodium-Phosphate Cotransporter Proteins, Type I, musculoskeletal diseases, Adult, congenital, hereditary, and neonatal diseases and abnormalities, Genotype, Organic Cation Transport Proteins, Immunology, Single-nucleotide polymorphism, Polymorphism, Single Nucleotide, General Biochemistry, Genetics and Molecular Biology, White People, 03 medical and health sciences, Rheumatology, Asian People, Gene Polymorphism, Humans, Genetic Predisposition to Disease, Aged, 030203 arthritis & rheumatology, business.industry, Arthritis, Case-control study, nutritional and metabolic diseases, Proteins, Clinical and Epidemiological Research, medicine.disease, 030104 developmental biology, chemistry, Genetic Loci, Case-Control Studies, biology.protein, Uric acid, Gene polymorphism, business, Genome-Wide Association Study

Abstract

ObjectiveA genome-wide association study (GWAS) of gout and its subtypes was performed to identify novel gout loci, including those that are subtype-specific.MethodsPutative causal association signals from a GWAS of 945 clinically defined gout cases and 1213 controls from Japanese males were replicated with 1396 cases and 1268 controls using a custom chip of 1961 single nucleotide polymorphisms (SNPs). We also first conducted GWASs of gout subtypes. Replication with Caucasian and New Zealand Polynesian samples was done to further validate the loci identified in this study.ResultsIn addition to the five loci we reported previously, further susceptibility loci were identified at a genome-wide significance level (p−8): urate transporter genes (SLC22A12andSLC17A1) andHIST1H2BF-HIST1H4Efor all gout cases, andNIPAL1andFAM35Afor the renal underexcretion gout subtype. WhileNIPAL1encodes a magnesium transporter, functional analysis did not detect urate transport via NIPAL1, suggesting an indirect association with urate handling. Localisation analysis in the human kidney revealed expression of NIPAL1 and FAM35A mainly in the distal tubules, which suggests the involvement of the distal nephron in urate handling in humans. Clinically ascertained male patients with gout and controls of Caucasian and Polynesian ancestries were also genotyped, andFAM35Awas associated with gout in all cases. A meta-analysis of the three populations revealedFAM35Ato be associated with gout at a genome-wide level of significance (pmeta=3.58×10−8).ConclusionsOur findings including novel gout risk loci provide further understanding of the molecular pathogenesis of gout and lead to a novel concept for the therapeutic target of gout/hyperuricaemia.

Published

2016