Literature DB >> 29215084

Variants of ALPK1 with ABCG2, SLC2A9, and SLC22A12 increased the positive predictive value for gout.

Hung-Pin Tu1,2, Albert Min-Shan Ko3, Su-Shin Lee4, Chi-Pin Lee5, Tzer-Min Kuo5, Chung-Ming Huang6,7, Ying-Chin Ko8.   

Abstract

We investigated the interactions of ALPK1 variants and the loci of ABCG2, SLC2A9, and SLC22A12 on gout risk. We conducted two case-control studies. Participants were recruited from hospitals (n = 410; 104 gout cases and 306 controls) and communities (n = 678; 373 gout cases and 305 controls) in Taiwan. The genotypes of ALPK1 (rs11726117 M861T, rs231247 R1084R, and rs231253 3' UTR), ABCG2 (rs2231142 Q141K and rs2231137 V12M), SLC2A9 (rs3733591 R265H and rs1014290), and SLC22A12 (rs3825016 H86H, rs11231825 H142H, and rs475688) were genotyped. Under a recessive model, the joint effects of ALPK1 variants and the SNPs rs2231142 of ABCG2, rs1014290 of SLC2A9, or rs475688 and rs3825016 of SLC22A12 were associated with gout. The rs11726117 [CC] of ALPK1 and rs2231142 [TT] of ABCG2 with the sequential addition of the rs1014290 [AA] of SLC2A9 and rs3825016 [CC] of SLC22A12 were associated with gout risk (odds ratio (OR): 13.01, 15.11, and 55.00 and positive predictive value (PPV): 56%, 69%, and 99% in the Han group, respectively; OR: 3.76, 5.78, and 12.30 and PPV: 74%, 80%, and 81% in the aboriginal group, respectively). Combined exposure to the four high-risk genotypes of ALPK1 and the uric-acid-related loci of ABCG2, SLC2A9, and SLC22A12 was associated with an increased gout risk and a high PPV for gout.

Entities:  

Mesh:

Substances:

Year:  2017        PMID: 29215084     DOI: 10.1038/s10038-017-0368-9

Source DB:  PubMed          Journal:  J Hum Genet        ISSN: 1434-5161            Impact factor:   3.172


  33 in total

1.  Understanding deficient elimination of uric acid.

Authors:  Martin Aringer; Juergen Graessler
Journal:  Lancet       Date:  2008-10-01       Impact factor: 79.321

Review 2.  Molecular physiology of urate transport.

Authors:  Matthias A Hediger; Richard J Johnson; Hiroki Miyazaki; Hitoshi Endou
Journal:  Physiology (Bethesda)       Date:  2005-04

Review 3.  The molecular physiology of uric acid homeostasis.

Authors:  Asim K Mandal; David B Mount
Journal:  Annu Rev Physiol       Date:  2014-11-12       Impact factor: 19.318

4.  URAT1 inhibition by ALPK1 is associated with uric acid homeostasis.

Authors:  Tzer-Min Kuo; Chung-Ming Huang; Hung-Pin Tu; Albert Min-Shan Ko; Shu-Jung Wang; Chi-Pin Lee; Ying-Chin Ko
Journal:  Rheumatology (Oxford)       Date:  2017-04-01       Impact factor: 7.580

5.  Efficacy and tolerability of pegloticase for the treatment of chronic gout in patients refractory to conventional treatment: two randomized controlled trials.

Authors:  John S Sundy; Herbert S B Baraf; Robert A Yood; N Lawrence Edwards; Sergio R Gutierrez-Urena; Edward L Treadwell; Janitzia Vázquez-Mellado; William B White; Peter E Lipsky; Zeb Horowitz; William Huang; Allan N Maroli; Royce W Waltrip; Steven A Hamburger; Michael A Becker
Journal:  JAMA       Date:  2011-08-17       Impact factor: 56.272

6.  Identification of chromosome 3q28 and ALPK1 as susceptibility loci for chronic kidney disease in Japanese individuals by a genome-wide association study.

Authors:  Yoshiji Yamada; Tamotsu Nishida; Sahoko Ichihara; Kimihiko Kato; Tetsuo Fujimaki; Mitsutoshi Oguri; Hideki Horibe; Tetsuro Yoshida; Sachiro Watanabe; Kei Satoh; Yukitoshi Aoyagi; Michio Fukuda; Motoji Sawabe
Journal:  J Med Genet       Date:  2013-03-28       Impact factor: 6.318

Review 7.  The genetics of hyperuricaemia and gout.

Authors:  Anthony M Reginato; David B Mount; Irene Yang; Hyon K Choi
Journal:  Nat Rev Rheumatol       Date:  2012-09-04       Impact factor: 20.543

8.  ABCG2 dysfunction causes hyperuricemia due to both renal urate underexcretion and renal urate overload.

Authors:  Hirotaka Matsuo; Akiyoshi Nakayama; Masayuki Sakiyama; Toshinori Chiba; Seiko Shimizu; Yusuke Kawamura; Hiroshi Nakashima; Takahiro Nakamura; Yuzo Takada; Yuji Oikawa; Tappei Takada; Hirofumi Nakaoka; Junko Abe; Hiroki Inoue; Kenji Wakai; Sayo Kawai; Yin Guang; Hiroko Nakagawa; Toshimitsu Ito; Kazuki Niwa; Ken Yamamoto; Yutaka Sakurai; Hiroshi Suzuki; Tatsuo Hosoya; Kimiyoshi Ichida; Toru Shimizu; Nariyoshi Shinomiya
Journal:  Sci Rep       Date:  2014-01-20       Impact factor: 4.379

Review 9.  An update on the genetic architecture of hyperuricemia and gout.

Authors:  Tony R Merriman
Journal:  Arthritis Res Ther       Date:  2015-04-10       Impact factor: 5.156

10.  ALPK1 phosphorylates myosin IIA modulating TNF-α trafficking in gout flares.

Authors:  Chi-Pin Lee; Shang-Lun Chiang; Albert Min-Shan Ko; Yu-Fan Liu; Che Ma; Chi-Yu Lu; Chung-Ming Huang; Jan-Gowth Chang; Tzer-Min Kuo; Chia-Lin Chen; Eing-Mei Tsai; Ying-Chin Ko
Journal:  Sci Rep       Date:  2016-05-12       Impact factor: 4.379
View more
  6 in total

1.  Examining an Association of Single Nucleotide Polymorphisms with Hyperuricemia in Chinese Flight Attendants.

Authors:  Jianpin Ye; Zhiwei Zeng; Yuxian Chen; Zhenkun Wu; Qingwei Yang; Tao Sun
Journal:  Pharmgenomics Pers Med       Date:  2022-06-08

2.  Differential gene expression of ABCG2, SLC22A12, IL-1β, and ALPK1 in peripheral blood leukocytes of primary gout patients with hyperuricemia and their comorbidities: a case-control study.

Authors:  Paniagua-Díaz Natsuko; Sanchez-Chapul Laura; Clavijo-Cornejo Denise; Ventura-Ríos Lucio; Aguilar-Salinas Carlos; Sanchez-Muñoz Fausto; López-Macay Ambar
Journal:  Eur J Med Res       Date:  2022-05-03       Impact factor: 4.981

Review 3.  Trends in the Contribution of Genetic Susceptibility Loci to Hyperuricemia and Gout and Associated Novel Mechanisms.

Authors:  Jianan Zhao; Shicheng Guo; Steven J Schrodi; Dongyi He
Journal:  Front Cell Dev Biol       Date:  2022-06-23

Review 4.  Genetics of hyperuricemia and gout: Insights from recent genome-wide association studies and Mendelian randomization studies.

Authors:  Yu-Lin Ko
Journal:  Tzu Chi Med J       Date:  2021-11-24

5.  Long noncoding RNA HAR1A regulates oral cancer progression through the alpha-kinase 1, bromodomain 7, and myosin IIA axis.

Authors:  Chi-Pin Lee; Albert Min-Shan Ko; Srinivasan Nithiyanantham; Chu-Hu Lai; Ying-Chin Ko
Journal:  J Mol Med (Berl)       Date:  2021-06-07       Impact factor: 4.599

6.  The association between genetic polymorphisms in ABCG2 and SLC2A9 and urate: an updated systematic review and meta-analysis.

Authors:  Thitiya Lukkunaprasit; Sasivimol Rattanasiri; Saowalak Turongkaravee; Naravut Suvannang; Atiporn Ingsathit; John Attia; Ammarin Thakkinstian
Journal:  BMC Med Genet       Date:  2020-10-21       Impact factor: 2.103
  6 in total

北京卡尤迪生物科技股份有限公司 © 2022-2023.