Association between KCNQ1 gene expression levels and gout
ZENG Jie1, HE Juan2, XU Yuanjun1, WANG Chun1
1. The Affiliated Guangdong Second Provincial General Hospital of Jinan University, Guangzhou, Guangdong 510310, China; 2. Tianhe District Center for Disease Control and Prevention, Guangzhou, Guangdong 510655, China
Abstract:Objective To investigate the association between expression levels of potassium voltage-gated channel subfamily Q member 1 (KCNQ1) gene and gout, so as to provide the basis for diagnosis, prevention and treatment of gout. Methods A total of 179 patients diagnosed with gout at the outpatient department of Guangdong Second Provincial General Hospital were enrolled in the case group, while 179 healthy individuals matched by age (within 5 years) were selected as the control group. Demographic information, lifestyle, dietary intake and biochemical blood indicators were collected through questionnaires and laboratory tests. The relative expression levels of KCNQ1 gene mRNA were quantified using real-time fluorescence quantitative PCR. A receiver operating characteristic (ROC) curve was constructed to evaluate the diagnostic performance of KCNQ1 gene mRNA levels in distinguishing gout. The association between the relative expression level of KCNQ1 gene mRNA and gout, the interaction effects of the relative expression levels of KCNQ1 gene mRNA with dietary intake and biochemical blood indicators on gout were analyzed using a multivariate conditional logistic regression model. Results There were 112 males (62.57%) and 67 females (37.43%) in the case group, with a mean age of (41.32±10.12) years. There were 98 males (54.75%) and 81 females (45.25%) in the control group, with a mean age of (40.24±7.62) years. The mRNA expression levels of the KCNQ1 gene were higher in the case group compared to the control group (P<0.05). The area under the ROC curve was 0.897 (95%CI: 0.865-0.928). Multivariate conditional logistic regression analysis revealed that KCNQ1 gene mRNA expression levels were positively associated with gout risk (OR=1.430, 95%CI: 1.171-1.747). Significant interactions were observed between KCNQ1 mRNA expression and seafood intake (OR=2.107, 95%CI: 1.175-3.779), KCNQ1 gene mRNA expression and uric acid levels (OR=2.373, 95%CI: 1.366-4.119), as well as between uric acid levels and seafood intake (OR=2.321, 95%CI: 1.159-4.678). Conclusion The expression levels of the KCNQ1 gene may increase the risk of gout and further increase the risk through interaction with seafood intake and uric acid levels.
[1] CHEN Z Y,TANG Z Z,HUANG Z Y,et al.The prevalence of gout in mainland China from 2000 to 2016:a systematic review and meta-analysis[J].J Public Health,2017,25(5):521-529. [2] 林勇军,林忠文.痛风的相关基因和遗传学基础研究进展[J].内科,2017,12(4):495-497,555. LIN Y J,LIN Z W.Research progress on related genes and genetic basis of gout[J].Intern Med,2017,12(4):495-497,555.(in Chinese) [3] LI C G,LI Z Q,LIU S G,et al.Genome-wide association analysis identifies three new risk loci for gout arthritis in Han Chinese[J].Nat Commun,2015,6:1-6. [4] YASUDA K,MIYAKE K,HORIKAWA Y,et al.Variants in KCNQ1 are associated with susceptibility to type 2 diabetes mellitus[J].Nat Genet,2008,40(9):1092-1097. [5] 孙凯琳,王毅鹏.KCNQ1基因多态性与高尿酸血症的关联研究[J].中国现代医学杂志,2021,31(7):28-34. SUN K L,WANG Y P.Association study of KCNQ1 gene polymorphism with hyperuricemia[J].Chin J Mod Med,2021,31(7):28-34.(in Chinese) [6] 吴菊蕾,毛莉华,余婷婷,等.痛风与高尿酸血症患者膳食方式新理念[J].内科理论与实践,2024,19(2):144-148. WU J L,MAO L H,YU T T,et al.New concepts of dietary patterns in patients with gout and hyperuricemia[J].J Intern Med Concepts Pract,2024,19(2):144-148.(in Chinese) [7] 中华医学会内分泌学分会.中国高尿酸血症与痛风诊疗指南(2019)[J].中华内分泌代谢杂志,2020,36(1):1-13. Chinese Society of Endocrinology.Chinese guidelines for the diagnosis and treatment of hyperuricemia and gout(2019)[J].Chin J Endocrinol Metab,2020,36(1):1-13.(in Chinese) [8] 刘丹,何丽,张馨,等.中国人群食物频率法的建立与应用[J].卫生研究,2018,47(5):744-748,755. LIU D,HE L,ZHANG X,et al.Development and application of food frequency questionnaire in Chinese population[J].J Hyg Res,2018,47(5):744-748,755.(in Chinese) [9] 陈国强,赵清,张雪芳,等.KCNQ1和RFX3基因表达量作为原发性痛风诊断指标的探讨[J].国际检验医学杂志,2020,41(8):978-983. CHEN G Q,ZHAO Q,ZHANG X F,et al.Exploration of KCNQ1 and RFX3 gene expression levels as diagnostic indicators for primary gout[J].Int J Lab Med,2020,41(8):978-983.(in Chinese) [10] MASAYUKI S,HIROTAKA M,HIROFUMI N,et al.Common variant of BCAS3 is associated with gout risk in Japanese population:the first replication study after gout GWAS in Han Chinese[J].BMC Med Genet,2018,19(1):1-6. [11] 王静. 原发性痛风易感基因KCNQ1基因的单核苷酸多态性对基因表达及单核细胞功能影响的研究[D].青岛:青岛大学,2017. WANG J.Study on the effect of single nucleotide polymorphisms of KCNQ1 gene,a susceptibility gene for primary gout,on gene expression and monocyte function [D].Qingdao:Qingdao University,2017.(in Chinese) [12] UNOKI H,TAKAHASHI A,KAWAGUCHI T,et al.SNPs in KCNQ1 are associated with susceptibility to type 2 diabetes in East Asian and European populations[J].Nat Genet,2008,40(9):1098-1102. [13] 李佩华. 吸烟与高尿酸血症的相关性研究[D].大连:大连医科大学,2022. LI P H.Study on the correlation between smoking and hyperuricemia[D].Dalian:Dalian Medical University,2022.(in Chinese) [14] 吴兴华,陈玉柱,周为文,等.广西痛风患者膳食和饮酒危险因素的病例对照研究[J].应用预防医学,2016,22(1):19-25. WU X H,CHEN Y Z,ZHOU W W,et al.Case-control study on dietary and alcohol consumption risk factors in gout patients in Guangxi[J].Appl Prev Med,2016,22(1):19-25.(in Chinese) [15] 刘秀萍. 416例门诊痛风患者生活方式与膳食情况调查分析[D].沈阳:中国医科大学,2018. LIU X P.Investigation and analysis of lifestyle and dietary habits in 416 outpatients with gout[D].Shenyang:China Medical University,2018.(in Chinese) [16] CHOI H K,ATKINSON K,KARLSON E W,et al.Purine-rich foods,dairy and protein intake,and the risk of gout in men[J].N Engl J Med,2004,350(11):1093-1103. [17] CHEN-XU M,YOKOSE C,RAI S K,et al.Contemporary prevalence of gout and hyperuricemia in the United States and decadal trends:the National Health and Nutrition Examination Survey,2007-2016[J]. Arthritis Rheumatol,2019,71(6):991-999.
