ABCMdb

ABCG2 p.Gly268Arg

Predicted by SNAP2:	A: D (85%), C: D (85%), D: D (91%), E: D (95%), F: D (91%), H: D (95%), I: D (91%), K: D (95%), L: D (91%), M: D (91%), N: D (91%), P: D (95%), Q: D (91%), R: D (91%), S: D (85%), T: D (91%), V: D (91%), W: D (95%), Y: D (95%),
Predicted by PROVEAN:	A: D, C: D, D: D, E: D, F: D, H: D, I: D, K: D, L: D, M: D, N: D, P: D, Q: D, R: D, S: D, T: D, V: D, W: D, Y: D,

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[hide] ABCG2/BCRP dysfunction as a major cause of gout. Nucleosides Nucleotides Nucleic Acids. 2011 Dec;30(12):1117-28. Matsuo H, Takada T, Ichida K, Nakamura T, Nakayama A, Suzuki H, Hosoya T, Shinomiya N
ABCG2/BCRP dysfunction as a major cause of gout.
Nucleosides Nucleotides Nucleic Acids. 2011 Dec;30(12):1117-28., [PMID:22132966]

Abstract [show]
Recent genome-wide association studies showed that serum uric acid (SUA) levels relate to ABCG2/BCRP gene, which locates in a gout-susceptibility locus revealed by a genome-wide linkage study. Together with the ABCG2 characteristics, we hypothesized that ABCG2 transports urate and its dysfunction causes hyperuricemia and gout. Transport assays showed ATP-dependent transport of urate via ABCG2. Kinetic analysis revealed that ABCG2 mediates high-capacity transport of urate (Km: 8.24 +/- 1.44 mM) even under high-urate conditions. Mutation analysis of ABCG2 in 90 Japanese hyperuricemia patients detected six nonsynonymous mutations, including five dysfunctional variants. Two relatively frequent dysfunctional variants, Q126X and Q141K, were then examined. Quantitative trait locus analysis of 739 Japanese individuals showed that Q141K increased SUA as the number of minor alleles of Q141K increased (p = 6.60 x 10(-5)). Haplotype frequency analysis revealed that there is no simultaneous presence of Q126X and Q141K in one haplotype. Becuase Q126X and Q141K are assigned to nonfunctional and half-functional haplotypes, respectively, their genotype combinations are divided into four functional groups. The association study with 161 male gout patients and 865 male controls showed that all of those with dysfunctional ABCG2 increased the gout risk, especially those with </=1/4 function (OR, 25.8; 95% CI, 10.3-64.6; p = 3.39 x 10(-21)). These genotypes were found in 10.1% of gout patients, but in only 0.9% of control. Our function-based clinicogenetic (FBCG) analysis showed that combinations of the two dysfunctional variants are major causes of gout, thereby providing a new approach for prevention and treatment of the gout high-risk population.

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38 1119 ABCG2 : ATP binding casse e G2 SNP : single nucleo de polymorphism QTL : quan ta ve trait locus OR : odds ra o ABCG2 as a urate secre on transporter in humans Gene c analysis Func onal analysis ABCG2 muta on analysis of 90 hyperuricemic cases (all coding regions) ABCG2 muta ons (with amino acid altera ons) 6 muta ons c d Func onal analysis of urate transport via wild type ABCG2 (vesicle studies) a Iden fica on of urate transport ac vi es via ABCG2 b Func onal analysis of urate transport via mutated ABCG2 6 mutants e No effect (V12M) g Dysfunc onal genotype combina ons of ABCG2 as major causes of gout q Dysfunc onal SNP with high frequency (>30%) (Q141K) QTL analysis in 739 Japanese individuals h i j n Gout / hyperuricemia with ABCG2 homozygous, n = 2 heterozygous, n = 24 Loss of func on (Q126X, G268R, S441N, F506Sfs) Reduced func on (~50%) (Q141K) f p Genotype combina on analysis 10.1% of gout with ≤1/4 ABCG2 func on OR = 25.8, p = 3.39×10-21 o Haplotype analysis 13.5% of gout with disease haplotype OR = 5.97, p = 4.10×10-12 Associa on analysis of hyperuricemia (Q126X) OR = 3.61, p = 2.91× 10-7 l m Associa on analysis of gout (Q126X) OR = 4.25, p =3.04 × 10-8 Genotyping of nonfunc onal SNP (Q126X) hyperuricemia, n=228 k FIGURE 1 Flowchart for molecular-function-based clinicogenetic (FBCG) analysis of gout patients with ABCG2 polymorphic variants. Login to comment
53 Using the site-directed mutagenesis technique, we constructed ABCG2 mutants (V12M, Q126X, Q141K, G268R, S441N, and F506SfsX4), which were used for urate transport analysis, on the expression vector for ABCG2. Login to comment
65 The following six nonsynonymous mutations, including three SNPs, were found: V12M, Q126X, Q141K, G268R, S441N, and F506SfsX4 (Figure 2A). Login to comment
79 Among six mutants, ATP-dependent urate transport was reduced by approximately half (46.7%) in one mutant, Q141K, and was nearly eliminated in four mutants, Q126X, G268R, S441N, and F506SfsX4 (Figure 2B). Login to comment

[hide] Identification of ABCG2 dysfunction as a major fac... Nucleosides Nucleotides Nucleic Acids. 2011 Dec;30(12):1098-104. Matsuo H, Takada T, Ichida K, Nakamura T, Nakayama A, Takada Y, Okada C, Sakurai Y, Hosoya T, Kanai Y, Suzuki H, Shinomiya N
Identification of ABCG2 dysfunction as a major factor contributing to gout.
Nucleosides Nucleotides Nucleic Acids. 2011 Dec;30(12):1098-104., [PMID:22132963]

Abstract [show]
The ATP-binding cassette, subfamily G, member 2 gene ABCG2/BCRP locates in a gout-susceptibility locus (MIM 138900) on chromosome 4q. Recent genome-wide association studies also showed that the ABCG2 gene relates to serum uric acid levels and gout. Since ABCG2 is also known as a transporter of nucleotide analogs that are structurally similar to urate, and is an exporter that has common polymorphic reduced functionality variants, ABCG2 could be a urate secretion transporter and a gene causing gout. To find candidate mutations in ABCG2, we performed a mutation analysis of the ABCG2 gene in 90 Japanese patients with hyperuricemia and found six non-synonymous mutations. Among the variants, ATP-dependent urate transport was reduced or eliminated in five variants, and two out of the five variants (Q126X and Q141K) were frequently detected in patients. Haplotype frequency analysis revealed that there is no simultaneous presence of Q126X and Q141K in one haplotype. As Q126X and Q141K are a nonfunctional and half-functional haplotype, respectively, their genotype combinations are divided into four estimated functional groups. The association study with 161 male gout patients and 865 male controls showed that all of those who had dysfunctional ABCG2 had an increased risk of gout, and that a remarkable risk was observed in those with </=1/4 function (OR, 25.8; 95% CI, 10.3-64.6; p = 3.39 x 10(-21)). In 2,150 Japanese individuals, the frequency of those with dysfunctional ABCG2 was more than 50%. Our function-based clinicogenetic analysis identified the combinations of dysfunctional variants of ABCG2 as a major contributing factor in Japanese patients with gout.

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36 Using the site-directed mutagenesis technique, we constructed mutants of ABCG2 (V12M, Q126X, Q141K, G268R, S441N, and F506SfsX4), which were used for urate transport analysis, on the expression vector for ABCG2. Login to comment
45 The following six non-synonymous mutations, V12M, Q126X, Q141K, G268R, S441N, and F506SfsX4, were found (Figure 1A), and the first three mutations were SNPs. Login to comment
52 The ATP-dependent transport of urate was reduced by approximately half (46.7%) in Q141K and was nearly eliminated in Q126X, G268R, S441N, and F506SfsX4 mutants (Figure 1B). Login to comment

[hide] ABCG2 is a high-capacity urate transporter and its... Nucleosides Nucleotides Nucleic Acids. 2011 Dec;30(12):1091-7. Nakayama A, Matsuo H, Takada T, Ichida K, Nakamura T, Ikebuchi Y, Ito K, Hosoya T, Kanai Y, Suzuki H, Shinomiya N
ABCG2 is a high-capacity urate transporter and its genetic impairment increases serum uric acid levels in humans.
Nucleosides Nucleotides Nucleic Acids. 2011 Dec;30(12):1091-7., [PMID:22132962]

Abstract [show]
The ATP-binding cassette, subfamily G, member 2 (ABCG2/BCRP) gene encodes a well-known transporter, which exports various substrates including nucleotide analogs such as 3'-azido-3'-deoxythymidine (AZT). ABCG2 is also located in a gout-susceptibility locus (MIM 138900) on chromosome 4q, and has recently been identified by genome-wide association studies to relate to serum uric acid (SUA) and gout. Becuase urate is structurally similar to nucleotide analogs, we hypothesized that ABCG2 might be a urate exporter. To demonstrate our hypothesis, transport assays were performed with membrane vesicles prepared from ABCG2-overexpressing cells. Transport of estrone-3-sulfate (ES), a typical substrate of ABCG2, is inhibited by urate as well as AZT and ES. ATP-dependent transport of urate was then detected in ABCG2-expressing vesicles but not in control vesicles. Kinetic analysis revealed that ABCG2 is a high-capacity urate transporter that maintained its function even under high-urate concentration. The calculated parameters of ABCG2-mediated transport of urate were a Km of 8.24 +/- 1.44 mM and a Vmax of 6.96 +/- 0.89 nmol/min per mg of protein. Moreover, the quantitative trait locus (QTL) analysis performed in 739 Japanese individuals revealed that a dysfunctional variant of ABCG2 increased SUA as the number of minor alleles of the variant increased (p = 6.60 x 10(-5)). Because ABCG2 is expressed on the apical membrane in several tissues, including kidney, intestine, and liver, these findings indicate that ABCG2, a high-capacity urate exporter, has a physiological role of urate homeostasis in the human body through both renal and extrarenal urate excretion.

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47 We found the following six nonsynonymous mutations: V12M, Q126X, Q141K, G268R, S441N, and F506SfsX4, and the first three mutations are SNPs. Login to comment

[hide] ABCG transporters and disease. FEBS J. 2011 Sep;278(18):3215-25. doi: 10.1111/j.1742-4658.2011.08171.x. Epub 2011 Jun 13. Woodward OM, Kottgen A, Kottgen M
ABCG transporters and disease.
FEBS J. 2011 Sep;278(18):3215-25. doi: 10.1111/j.1742-4658.2011.08171.x. Epub 2011 Jun 13., [PMID:21554546]

Abstract [show]
ATP-binding cassette (ABC) transporters form a large family of transmembrane proteins that facilitate the transport of specific substrates across membranes in an ATP-dependent manner. Transported substrates include lipids, lipopolysaccharides, amino acids, peptides, proteins, inorganic ions, sugars and xenobiotics. Despite this broad array of substrates, the physiological substrate of many ABC transporters has remained elusive. ABC transporters are divided into seven subfamilies, A-G, based on sequence similarity and domain organization. Here we review the role of members of the ABCG subfamily in human disease and how the identification of disease genes helped to determine physiological substrates for specific ABC transporters. We focus on the recent discovery of mutations in ABCG2 causing hyperuricemia and gout, which has led to the identification of urate as a physiological substrate for ABCG2.

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59 R L L A A M AT T T R V S G G G F I T Q R R V K K S G E A D RR V V K K L L G E E E I IN NN D H Q Q R V V V V V L L S G F E N M TT QD D S K R V K L L G F P C Y R K S G F P P C N N A V L L S G G G I N A D R K P P S GG G R V VK K KK L L L LL L S S S GG G PPE E IIII N NN M A A A T D D Y N E A I P E S I D L L F T LS G EI MT D I I P FC L R IH A N T T T T T G L D S S K K K L L L S G G G F F F F Q P P I M M A A A A D H G G LS S S V L L L L L R R RQ Q I I Y Y YS S HE E A T V V V V L Q I S F I I II A A L G G Y K F R S S E E I I L G Y YY Y V V K H S P C M M D R T I II L L L F F YV S S P F N T I A Q Q L L L G F Y Y H S S PR W C N M I I A A A L L G F V V K H W T L I F F C C C D D D A A A QQ Q Q Q G G G G G G G G G G FF FF F F FF Y Y Y Y Y V V V V V VVV K KKK KK K K E E E E P P P P R W W TT TT T TT T T NNNN N N N N N M MM M L L L L L L L L LL LL I I I I I I AA A A A A A S S S S S S S S SS L L L L LL L L LL V V F G GCC T Q Q Q Q Y Y Y KK K K K H H EE E E E E EEE E P P P P R R RW N N N II I I I I I I A AAA A A A S SS S S S S L L LL L L L V V V V F F F F F F F G GG G C TT T T T T K K K K KKKK N NN LL D DDD DS S 395 469 565 644 414 450 495 505 584 625 Signature Walker A WalkerBQ EP MI A V V VF FG GTN N NS S S S P F HE V FG CTT K NN LLD SS AAA I V12M N-terminus C-terminus M MM MM T A A A A L F F Y V V S S S F 524476 Y Q126X G268R S441N F506fs Q141K 44 288 PP AA DD Fig. 2. Login to comment

[hide] Common defects of ABCG2, a high-capacity urate exp... Sci Transl Med. 2009 Nov 4;1(5):5ra11. Matsuo H, Takada T, Ichida K, Nakamura T, Nakayama A, Ikebuchi Y, Ito K, Kusanagi Y, Chiba T, Tadokoro S, Takada Y, Oikawa Y, Inoue H, Suzuki K, Okada R, Nishiyama J, Domoto H, Watanabe S, Fujita M, Morimoto Y, Naito M, Nishio K, Hishida A, Wakai K, Asai Y, Niwa K, Kamakura K, Nonoyama S, Sakurai Y, Hosoya T, Kanai Y, Suzuki H, Hamajima N, Shinomiya N
Common defects of ABCG2, a high-capacity urate exporter, cause gout: a function-based genetic analysis in a Japanese population.
Sci Transl Med. 2009 Nov 4;1(5):5ra11., [PMID:20368174]

Abstract [show]
Gout based on hyperuricemia is a common disease with a genetic predisposition, which causes acute arthritis. The ABCG2/BCRP gene, located in a gout-susceptibility locus on chromosome 4q, has been identified by recent genome-wide association studies of serum uric acid concentrations and gout. Urate transport assays demonstrated that ABCG2 is a high-capacity urate secretion transporter. Sequencing of the ABCG2 gene in 90 hyperuricemia patients revealed several nonfunctional ABCG2 mutations, including Q126X. Quantitative trait locus analysis of 739 individuals showed that a common dysfunctional variant of ABCG2, Q141K, increases serum uric acid. Q126X is assigned to the different disease haplotype from Q141K and increases gout risk, conferring an odds ratio of 5.97. Furthermore, 10% of gout patients (16 out of 159 cases) had genotype combinations resulting in more than 75% reduction of ABCG2 function (odds ratio, 25.8). Our findings indicate that nonfunctional variants of ABCG2 essentially block gut and renal urate excretion and cause gout.

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46 The following six nonsynonymous mutations were found: V12M, Q126X, Q141K, G268R, S441N, and F506SfsX4 (Table 1). Login to comment
52 ATP-dependent transport of urate was reduced by approximately half (46.7%) in Q141K and was nearly eliminated in Q126X, G268R, S441N, and F506SfsX4 mutants (Fig. 2B). Login to comment
77 The call rate, or the ability of the SNP to be reliably decoded, for V12M, Q126X, and LS N N SV FLC S P T AN FK G LM ETS S E V F I P Q G N T N G FV P A A AS LD V S N I C Y R V K K RKPVEKEILSNINGIKPGLNAILGPG GGKSSL LDVLA ARKDP S G T L S G D V L I G A P PR A N F K N S G Y Q D D V V M G T L T V R NE LV VC H Q F S A A A RL L T T TNEKNER HINRVIQELGLDKVADSKVGTQFIRGVG GERR KTSIGME L I T D P S I L F L D E P T T G L D S S T A N A V LL L L K R M S K Q G R I I F S T S I H Q P R Y M S I F K LFDSLTLLASGRLMFHGPAQEALGYFESAGYHCEAN YN T V A L N R E E D F K A T E II E P S K Q D K L I E L A EK I Y V N S S F Y K ETKAELHQLSGGEKKKKITVFKEISYTTSFCHQRWVK SRS AFFLDII N G D S A PD P L F K N LL G N P Q A S A I V G I I T L V A FI I Q V V L G Y AVEFLKNDST G I Q N R A G V L F F L T T Q C F S L V S S N G L S L M L I T P M S F I FV D L R P I C Y W L W Y I Y T Q S R F L NQ S L F P G A H E F Y S Y S E F R G Y I K V K S V Y I H L E V A S S V L M A A M F V A F M S Y M T M F K A T I M L H F I A V K G W I L V C A N L W V A T L M T C F VI F M M I F S G L L VNLTTIASAIAAGQS L S V V LKGL L F N Q L F P S L D Y G Q K V L C Y EEGTCTAYNCPNNGTAN G P G L K L L L K K SYF L Y D L G L M A P K Extracellular Intracellular 50 150 200 300 100 350 395 415 469 450 470 500 525 550 565 585 600 625 608 650 250 655 603 475 644 F506SfsX4 (F506fs) V12M Q126X Q141K S441N G268R V Q F S G Q # C signature Walker B motif Walker A motif C D E 4.0 4.5 5.0 5.5 6.0 C/C C/A A/A Male + female P= 2.02 x 10 -6 5.0 5.5 6.0 6.5 7.0 C/C C/A A/A Male P= 0.0144 Serumuric acid(mg/dl) 4.0 4.5 5.0 5.5 6.0 C/C C/A A/A Female P= 0.0137 (pmol/mgprotein) 0 20 40 60 80 100 120 140 160 180 200 + AMP + ATP B Serumuric acid(mg/dl) Serumuric acid(mg/dl) A [C]Uratetransport 14 G F M C-terminal N-terminal Fig. 2. Login to comment
89 Amino acid change SNP ID dbSNP (NCBI) Exon Type of mutation Number of hyperuricemia patients Allele frequency (%) (in hyperuricemia) Allele frequency* (%) (in Japanese population) Wild-type Heterozygote Homozygote Q141K rs2231142 5 Missense 29 47 14 41.67 31.9 V12M rs2231137 2 Missense 64 23 3 16.11 19.2 Q126X 4 Nonsense 80 10 0 5.56 2.8 G268R 7 Missense 89 1 0 0.56 N.D. S441N 11 Missense 89 1 0 0.56 0.3 F506SfsX4 13 Frameshift 89 1 0 0.56 0.3 * Data from Maekawa et al. (34). Login to comment
181 Using the site-directed mutagenesis technique, we constructed mutants of ABCG2 (V12M, Q126X, Q141K, G268R, S441N, and F506SfsX4), which were used for urate transport analysis, on the expression vector for ABCG2. Login to comment