Literature DB >> 22945592

The genetics of hyperuricaemia and gout.

Anthony M Reginato1, David B Mount, Irene Yang, Hyon K Choi.   

Abstract

Gout is a common and very painful inflammatory arthritis caused by hyperuricaemia. This review provides an update on the genetics of hyperuricaemia and gout, including findings from genome-wide association studies. Most of the genes that associated with serum uric acid levels or gout are involved in the renal urate-transport system. For example, the urate transporter genes SLC2A9, ABCG2 and SLC22A12 modulate serum uric acid levels and gout risk. The net balance between renal urate absorption and secretion is a major determinant of serum uric acid concentration and loss-of-function mutations in SLC2A9 and SLC22A12 cause hereditary hypouricaemia due to reduced urate absorption and unopposed urate secretion. However, the variance in serum uric acid explained by genetic variants is small and their clinical utility for gout risk prediction seems limited because serum uric acid levels effectively predict gout risk. Urate-associated genes and genetically determined serum uric acid levels were largely unassociated with cardiovascular-metabolic outcomes, challenging the hypothesis of a causal role of serum uric acid in the development of cardiovascular disease. Strong pharmacogenetic associations between HLA-B*5801 alleles and severe allopurinol-hypersensitivity reactions were shown in Asian and European populations. Genetic testing for HLA-B*5801 alleles could be used to predict these potentially fatal adverse effects.

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Year:  2012        PMID: 22945592      PMCID: PMC3645862          DOI: 10.1038/nrrheum.2012.144

Source DB:  PubMed          Journal:  Nat Rev Rheumatol        ISSN: 1759-4790            Impact factor:   20.543


  115 in total

1.  Genotype-based changes in serum uric acid affect blood pressure.

Authors:  Afshin Parsa; Eric Brown; Matthew R Weir; Jeffrey C Fink; Alan R Shuldiner; Braxton D Mitchell; Patrick F McArdle
Journal:  Kidney Int       Date:  2011-12-21       Impact factor: 10.612

2.  X-linkage does not account for the absence of father-son similarity in plasma uric acid concentrations.

Authors:  D R Reed; R A Price
Journal:  Am J Med Genet       Date:  2000-05-15

3.  Association between intronic SNP in urate-anion exchanger gene, SLC22A12, and serum uric acid levels in Japanese.

Authors:  Yukio Shima; Koji Teruya; Hidehiko Ohta
Journal:  Life Sci       Date:  2006-08-01       Impact factor: 5.037

4.  Genome-wide association of serum uric acid concentration: replication of sequence variants in an island population of the Adriatic coast of Croatia.

Authors:  Rebekah Karns; Ge Zhang; Guangyun Sun; Subba Rao Indugula; Hong Cheng; Dubravka Havas-Augustin; Natalija Novokmet; Dusko Rudan; Zijad Durakovic; Sasa Missoni; Ranajit Chakraborty; Pavao Rudan; Ranjan Deka
Journal:  Ann Hum Genet       Date:  2012-01-09       Impact factor: 1.670

5.  Positive and negative associations of HLA class I alleles with allopurinol-induced SCARs in Koreans.

Authors:  Hye-Ryun Kang; Young Koo Jee; Yon-Soo Kim; Chang Hwa Lee; Jae-Woo Jung; Sae Hoon Kim; Heung-Woo Park; Yoon-Seok Chang; In-Jin Jang; Sang-Heon Cho; Kyung-Up Min; Sang-Heon Kim; Kyung Wha Lee
Journal:  Pharmacogenet Genomics       Date:  2011-05       Impact factor: 2.089

6.  The cyclic GMP-dependent protein kinase II gene associates with gout disease: identified by genome-wide analysis and case-control study.

Authors:  S-J Chang; M-H Tsai; Y-C Ko; P-C Tsai; C-J Chen; H-M Lai
Journal:  Ann Rheum Dis       Date:  2008-08-04       Impact factor: 19.103

7.  Associations between gout tophus and polymorphisms 869T/C and -509C/T in transforming growth factor beta1 gene.

Authors:  S-J Chang; C-J Chen; F-C Tsai; H-M Lai; P-C Tsai; M-H Tsai; Y-C Ko
Journal:  Rheumatology (Oxford)       Date:  2008-03-19       Impact factor: 7.580

8.  Homozygous SLC2A9 mutations cause severe renal hypouricemia.

Authors:  Dganit Dinour; Nicola K Gray; Susan Campbell; Xinhua Shu; Lindsay Sawyer; William Richardson; Gideon Rechavi; Ninette Amariglio; Liat Ganon; Ben-Ami Sela; Hilla Bahat; Michael Goldman; Joshua Weissgarten; Michael R Millar; Alan F Wright; Eliezer J Holtzman
Journal:  J Am Soc Nephrol       Date:  2009-11-19       Impact factor: 10.121

9.  Mouse GLUT9: evidences for a urate uniporter.

Authors:  Stéphanie Bibert; Solange Kharoubi Hess; Dmitri Firsov; Bernard Thorens; Käthi Geering; Jean-Daniel Horisberger; Olivier Bonny
Journal:  Am J Physiol Renal Physiol       Date:  2009-07-08

10.  Sex-specific association of the putative fructose transporter SLC2A9 variants with uric acid levels is modified by BMI.

Authors:  Anita Brandstätter; Stefan Kiechl; Barbara Kollerits; Steven C Hunt; Iris M Heid; Stefan Coassin; Johann Willeit; Ted D Adams; Thomas Illig; Paul N Hopkins; Florian Kronenberg
Journal:  Diabetes Care       Date:  2008-05-16       Impact factor: 19.112
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  77 in total

1.  Lack of gene-diuretic interactions on the risk of incident gout: the Nurses' Health Study and Health Professionals Follow-up Study.

Authors:  Ying Bao; Gary Curhan; Tony Merriman; Robert Plenge; Peter Kraft; Hyon K Choi
Journal:  Ann Rheum Dis       Date:  2015-02-09       Impact factor: 19.103

2.  Uric acid enhances longevity and endurance and protects the brain against ischemia.

Authors:  Roy G Cutler; Simonetta Camandola; Neil H Feldman; Jeong Seon Yoon; James B Haran; Sandro Arguelles; Mark P Mattson
Journal:  Neurobiol Aging       Date:  2018-12-12       Impact factor: 4.673

3.  Expert consensus for the diagnosis and treatment of patient with hyperuricemia and high cardiovascular risk: 2021 update.

Authors:  Claudio Borghi; Justyna Domienik-Karłowicz; Andrzej Tykarski; Krystyna Widecka; Krzysztof J Filipiak; Miłosz J Jaguszewski; Krzysztof Narkiewicz; Giuseppe Mancia
Journal:  Cardiol J       Date:  2021-01-13       Impact factor: 2.737

4.  Genetics: Metabolic pathways newly implicated in gout epidemiology.

Authors:  Emma Leah
Journal:  Nat Rev Rheumatol       Date:  2013-01-15       Impact factor: 20.543

5.  The frequency of single nucleotide polymorphisms and their association with uric acid concentration based on data from genome-wide association studies in the Korean population.

Authors:  Chang-Nam Son; So-Young Bang; Soo-Kyung Cho; Yoon-Kyoung Sung; Tae-Hwan Kim; Sang-Cheol Bae; Jae-Bum Jun
Journal:  Rheumatol Int       Date:  2014-01-10       Impact factor: 2.631

6.  Uric acid and cardiac performance.

Authors:  Enzo Manzato
Journal:  Intern Emerg Med       Date:  2014-05-28       Impact factor: 3.397

7.  Genetic risk scores, sex and dietary factors interact to alter serum uric acid trajectory among African-American urban adults.

Authors:  May A Beydoun; Jose-Atilio Canas; Marie T Fanelli-Kuczmarski; Salman M Tajuddin; Michele K Evans; Alan B Zonderman
Journal:  Br J Nutr       Date:  2017-03-27       Impact factor: 3.718

8.  Additive composite ABCG2, SLC2A9 and SLC22A12 scores of high-risk alleles with alcohol use modulate gout risk.

Authors:  Hung-Pin Tu; Chia-Min Chung; Albert Min-Shan Ko; Su-Shin Lee; Han-Ming Lai; Chien-Hung Lee; Chung-Ming Huang; Chiu-Shong Liu; Ying-Chin Ko
Journal:  J Hum Genet       Date:  2016-05-26       Impact factor: 3.172

Review 9.  Molecular basis of oxidative stress in gouty arthropathy.

Authors:  Yessica Zamudio-Cuevas; Cristina Hernández-Díaz; Carlos Pineda; Anthony M Reginato; Jorge Francisco Cerna-Cortés; Lucio Ventura-Ríos; Alberto López-Reyes
Journal:  Clin Rheumatol       Date:  2015-04-09       Impact factor: 2.980

10.  The association between genotypes of urate transporter-1, Serum uric acid, and mortality in the community-based population: the Yamagata (Takahata) Study.

Authors:  Soichiro Kon; Tsuneo Konta; Kazunobu Ichikawa; Masafumi Watanabe; Hidenori Sato; Kenichi Ishizawa; Yoshiyuki Ueno; Hidetoshi Yamashita; Takamasa Kayama
Journal:  Clin Exp Nephrol       Date:  2019-09-03       Impact factor: 2.801
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