rs10910845 - PDZK1 - CD160

Magnitude 2.2 · 5 studies on file

Reported associations

  • A genome-wide association analysis reveals new pathogenic pathways in gout. - Nature genetics (2024) · Major TJ, Takei R, Matsuo H, Leask MP, Sumpter NA, Topless RK, Shirai Y, Wang W, Cadzow MJ, Phipps-Green AJ, Li Z, Ji A, Merriman ME, Morice E, Kelley EE, Wei WH, McCormick SPA, Bixley MJ, Reynolds RJ, Saag KG, Fadason T, Golovina E, O'Sullivan JM, Stamp LK, Dalbeth N, Abhishek A, Doherty M, Roddy E, Jacobsson LTH, Kapetanovic MC, Melander O, Andrés M, Pérez-Ruiz F, Torres RJ, Radstake T, Jansen TL, Janssen M, Joosten LAB, Liu R, Gaal OI, Crişan TO, Rednic S, Kurreeman F, Huizinga TWJ, Toes R, Lioté F, Richette P, Bardin T, Ea HK, Pascart T, McCarthy GM, Helbert L, Stibůrková B, Tausche AK, Uhlig T, Vitart V, Boutin TS, Hayward C, Riches PL, Ralston SH, Campbell A, MacDonald TM, Nakayama A, Takada T, Nakatochi M, Shimizu S, Kawamura Y, Toyoda Y, Nakaoka H, Yamamoto K, Matsuo K, Shinomiya N, Ichida K, Lee C, Bradbury LA, Brown MA, Robinson PC, Buchanan RRC, Hill CL, Lester S, Smith MD, Rischmueller M, Choi HK, Stahl EA, Miner JN, Solomon DH, Cui J, Giacomini KM, Brackman DJ, Jorgenson EM, Liu H, Susztak K, Shringarpure S, So A, Okada Y, Li C, Shi Y, Merriman TR · PubMed 39406924

    Gout is a chronic disease that is caused by an innate immune response to deposited monosodium urate crystals in the setting of hyperuricemia. Here, we provide insights into the molecular mechanism of the poorly understood inflammatory component of gout from a genome-wide association study (GWAS) of 2.6 million people, including 120,295 people with prevalent gout. We detected 377 loci and 410 genetically independent signals (149 previously unreported loci in urate and gout). An additional 65 loci with signals in urate (from a GWAS of 630,117 individuals) but not gout were identified. A prioritization scheme identified candidate genes in the inflammatory process of gout, including genes involved in epigenetic remodeling, cell osmolarity and regulation of NOD-like receptor protein 3 (NLRP3) i

  • Association of Gout Polygenic Risk Score With Age at Disease Onset and Tophaceous Disease in European and Polynesian Men With Gout. - Arthritis & rheumatology (Hoboken, N.J.) (2023) · Sumpter NA, Takei R, Cadzow M, Topless RKG, Phipps-Green AJ, Murphy R, de Zoysa J, Watson H, Qasim M, Lupi AS, Abhishek A, Andrés M, Crișan TO, Doherty M, Jacobsson L, Janssen M, Jansen TL, Joosten LAB, Kapetanovic M, Lioté F, Matsuo H, McCarthy GM, Perez-Ruiz F, Riches P, Richette P, Roddy E, Stiburkova B, So A, Tausche AK, Torres RJ, Uhlig T, Major TJ, Stamp LK, Dalbeth N, Choi HK, Vazquez AI, Leask MP, Reynolds RJ, Merriman TR · PubMed 36281732

    To determine whether a gout polygenic risk score (PRS) is associated with age at gout onset and tophaceous disease in European, East Polynesian, and West Polynesian men and women with gout. A 19-variant gout PRS was produced in 7 European gout cohorts (N = 4,016), 2 East Polynesian gout cohorts (N = 682), and 1 West Polynesian gout cohort (N = 490). Sex-stratified regression models were used to estimate the relationship between the PRS and age at gout onset and tophaceous disease. The PRS was associated with earlier age at gout onset in men (β = -3.61 in years per unit PRS [95% confidence interval (95% CI) -4.32, -2.90] in European men; β = -6.35 [95% CI -8.91, -3.80] in East Polynesian men; β = -3.51 [95% CI -5.46, -1.57] in West Polynesian men) but not in women (β = 0.0

  • A cross-population atlas of genetic associations for 220 human phenotypes. - Nature genetics (2021) · Sakaue S, Kanai M, Tanigawa Y, Karjalainen J, Kurki M, Koshiba S, Narita A, Konuma T, Yamamoto K, Akiyama M, Ishigaki K, Suzuki A, Suzuki K, Obara W, Yamaji K, Takahashi K, Asai S, Takahashi Y, Suzuki T, Shinozaki N, Yamaguchi H, Minami S, Murayama S, Yoshimori K, Nagayama S, Obata D, Higashiyama M, Masumoto A, Koretsune Y, Ito K, Terao C, Yamauchi T, Komuro I, Kadowaki T, Tamiya G, Yamamoto M, Nakamura Y, Kubo M, Murakami Y, Yamamoto K, Kamatani Y, Palotie A, Rivas MA, Daly MJ, Matsuda K, Okada Y · PubMed 34594039

    Current genome-wide association studies do not yet capture sufficient diversity in populations and scope of phenotypes. To expand an atlas of genetic associations in non-European populations, we conducted 220 deep-phenotype genome-wide association studies (diseases, biomarkers and medication usage) in BioBank Japan (n = 179,000), by incorporating past medical history and text-mining of electronic medical records. Meta-analyses with the UK Biobank and FinnGen (n = 628,000) identified ~5,000 new loci, which improved the resolution of the genomic map of human traits. This atlas elucidated the landscape of pleiotropy as represented by the major histocompatibility complex locus, where we conducted HLA fine-mapping. Finally, we performed statistical decomposition of matrices of phenome-wid

  • Target genes, variants, tissues and transcriptional pathways influencing human serum urate levels - Unknown journal (n.d.) · Unknown authors · PubMed 31578528

    ABSTRACT: Elevated serum urate levels cause gout and correlate with cardio-metabolic diseases via poorly understood mechanisms. We performed a trans-ethnic genome-wide association study of serum urate among 457,690 individuals, identifying 183 loci (147 novel) that improve prediction of gout in an independent cohort of 334,880 individuals. Serum urate showed significant genetic correlations with many cardio-metabolic traits, with genetic causality analyses supporting a substantial role for pleiotropy. Enrichment analysis, fine-mapping of urate-associated loci, and co-localization with gene expression in 47 tissues implicated kidney and liver as main target organs and prioritized potentially causal genes and variants, including the transcriptional master regulators in liver and kidney, HNF1

  • Large-scale cross-ancestry genome-wide meta-analysis of serum urate - Unknown journal (n.d.) · Unknown authors · PubMed 38658550

    ABSTRACT: Hyperuricemia is an essential causal risk factor for gout and is associated with cardiometabolic diseases. Given the limited contribution of East Asian ancestry to genome-wide association studies of serum urate, the genetic architecture of serum urate requires exploration. A large-scale cross-ancestry genome-wide association meta-analysis of 1,029,323 individuals and ancestry-specific meta-analysis identifies a total of 351 loci, including 17 previously unreported loci. The genetic architecture of serum urate control is similar between European and East Asian populations. A transcriptome-wide association study, enrichment analysis, and colocalization analysis in relevant tissues identify candidate serum urate-associated genes, including CTBP1, SKIV2L, and WWP2. A phenome-wide ass


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Lifestyle context

Concrete actions anchored to the cited research. We do not prescribe, we describe.

Diet

  • limit high-purine foods and alcohol Moderate

    Purine metabolism and alcohol both increase serum urate. rs10910845-A carriers have reduced urate excretion capacity.

    Minimize red meat, organ meats, shellfish, high-fructose beverages; limit alcohol to <1-2 drinks daily

Discuss with your doctor

  • genetic risk and preventive urate-lowering therapy High

    Strong genetic predisposition to elevated urate and gout warrants early personalized medical management and prophylaxis planning.

    Discuss findings with physician; consider prophylactic therapy (allopurinol or febuxostat) if gout episodes occur

Lifestyle

  • maintain healthy weight and adequate hydration Moderate

    Obesity increases urate production; dehydration impairs renal excretion. Weight loss and hydration reduce urate and gout risk.

    Target BMI <25 kg/m2 if overweight; drink 2-3 liters water daily

Screening

  • gout symptoms and incidence High

    rs10910845-A increases gout incidence 1.16-fold via elevated serum urate. Early detection enables timely preventive therapy.

    Monitor for acute joint pain episodes (especially feet/ankles); seek clinical evaluation for recurrent symptoms

  • serum urate levels High

    rs10910845-A is associated with elevated serum urate via altered PDZK1 expression affecting renal urate transport, a key gout risk factor.

    Annual or biannual serum urate measurement; target <6 mg/dL if recurrent episodes or persistent elevation