Serum Urate Concentrations and the Risk of Hyperuricemia

blood blood serum Urate Concent proportionalityns and the Risk of HyperuricemiaCommon UCP2 mutations convey to serum urate parsimoniousnesss and the take a chance of hyperuricemiaLuyu Yang, Zheng Dong, Jingru zhou, Yanyun Ma, Weilin Pu, Dongbao Zhao, Hongjun He, Hengdong Ji, Yajun Yang, Xiaofeng Wang, Xia Xu, Yafei Pang, Hejian Zou,Li Jin,Chengde Yang*, Jiucun Wang**Corresponding authorThese authors equally contributed to this sphere.AbstractElevated serum urate, which is correct at eightfold takes including componenttic variants, is a risk component for gout and former(a) metabolic diseases. This reputation aimed to investigate the fellowship betwixt UCP2 variants and serum urate as well as hyperuricemia in a Chinese population. In complete, 4332 individuals were geno emblemd for both common UCP2 variants, -866G/A and Ala55Val. These loci were not associated either serum urate level or with a risk of hyperuricemia in the measure company of subjects. However, in f e manfuls, -866G/A and Ala55Val were associated with a tear down serum urate (P = 0.006 and 0.014seperately) and vie a protective role against hyperuricemia (OR = 0.80, P = 0.018 OR = 0.79, P = 0.016). These intimacys were not discover in the males. subsequently further stratification, the devil loci were associated with serum urate in dense, but not underweight females. The haplotype A-T (-866G/A-Ala55Val) was a protective grammatical constituent for hyperuricemia in the female subgroup (OR = 0.80, P=0.017). This lay out field of honor identified a novel gene, UCP2, that twines the serum urate concent proportionalityn and the risk of hyperuricemia, and the degree of tie beam varies with gender and BMI levels.IntroductionUric acid is the final product of purine oxidation in humans. Elevated serum urate, or hyperuricemia, has long been recognized as an independent risk factor for gout 1-2. There is a renewed interest in hyperuricemia and its association with a number of other clinical disorders including hypertension, atherosclerosis, cardiovascular disease, chronic kidney diseases, and abdominal fleshiness, glucose intolerance, insulin resistance, and dyslipidemia, which are often subsumed under the term metabolic syndrome 3.Serum urate is balanced betwixt uric acid production in the liver and its disposal via the kidney and gut 4. The position of hyperuricemia could be ca employ by disruptions in any part of this metabolic process. Both transmitted and environmental factors, such(prenominal) as gender and body mass index (BMI), have a strong outcome on the risk of hyperuricemia 3. Among those factors, the attribution of genetic factors is estimated to be as high as 73% 5. Recent genome-wide association studies (GWAS) have identified 28 loci associated with serum urate concentration 6. However, only approximately 7% of the variation in serum urate concentration could be explained by those reported loci, suggesting the missing heritability rem ained to be explored 6.Human uncoupling proteins (UCPs) are mitochondrial transporters present in the inner membrane of mitochondria 7. UCPs are capable of uncoupling ATP production from mitochondrial respiration by causation proton leak and preventing mitochondrial hyperpolarization and the formation of reactive oxygen species (ROS) 8. Among the five identified UCPs, UCP2 is widely expressed in well-nigh all mammalian tissues including white adipose tissue, liver, kidney, pancreatic islets, macrophages and retinal endothelial cells, indicating its involvement in a variety of physiologic or pathologic events 9-12. Two of the most common polymorphisms of this gene, -866G/A (rs659366) in the booster station and Ala55Val (rs660339) in codon 55, were identified as being associated with diametrical phenotypes 7, 12, including obesity, insulin resistance, type 2 diabetes mellitus (T2D), low-density lipoprotein (LDL) particle size, coronary thrombosis incidence and other metabolic dis orders 9-10, 13-21.Given the involvement of UCP2 and hyperuricemia in a variety of metabolic disorders, we selected the two common loci -866G/A and Ala55Val to explore the association between genetic UCP2 variants and hyperuricemia in a Chinese population, fling a new diagnostic or therapeutic target for hyperuricemia.ResultsThere was noassociation between SNPs and serum urateThe two loci were proven in Hardy-Weinberg equilibrium (-866G/A P = 0.990 Ala55Val P = 0.690). For -866G/A, AA, AG, and GG genotypes accounted for 21.6%, 49.9%, and 28.6% of hyperuricemic patients, respectively in muscular controls, the distribution was 21.2%, 49.6%, and 29.3%, respectively. As shown in Table 1, the -866G/A polymorphism was not rear to be associated with serum urate (AA/GG genus Beta = -0.008, P = 0.644 AG/GGBeta = -0.012, P = 0.474) or with the risk of hyperuricemia (AA/GG OR = 1.05, P = 0.603 AG/GGOR = 1.03, P = 0.667). For Ala55Val, the TT, TC, and CC genotype distribution was 21.5%, 50.5% and 28.0% in hyperuricemic patients, respectively, and the distribution was 21.5%, 49.8% and 28.6% in hearty controls, respectively. No association was observed between Ala55Val polymorphism and serum urate (TT/CC Beta = -0.013, P = 0.460 TC/CCBeta = -0.017, P = 0.324). There was no difference in the distribution of the genotypes or alleles among hyperuricemic patients and healthy controls (TT/CC OR = 1.02, P = 0.824 TC/CCOR = 1.04, P = 0.652). Therefore, no statistically real evidence support the genetic effect of -866G/A and Ala55Val on serum urate or the risk of hyperuricemia in the total group of subjects.UCP2 variants were associated withserum urate andhyperuricemia in female subgroupsAs shown in Table 1, we stratified all subjects into male and female subgroups to further explore the gender-related genetic effects of the two polymorphisms. In the male subgroups, there were no remarkable associations between the two loci and serum urate or the risk of hyperuricemia (all P 0.025). However, some nominal significant associations were found between -866G/A and the hyperuricemia risk (genotype AA OR = 1.26, P = 0.038 allele A OR = 1.12, P = 0.035), indicating a possible risky effect of the -866G/A variant on hyperuricemia incidence in males.A significant association was found between SNPs and serum urate and hyperuricemia in the female subgroups. The -866G/A genotypes were associated with a start out serum urate (AA/GG Beta = -0.078, P = 0.015 AG/GG Beta = -0.104, P = 0.001) and a change magnitude risk of hyperuricemia (AG/GG OR = 0.71, P = 0.025). The subjects carrying allele A had a reduce serum urate and a decreased risk of hyperuricemia (A/G Beta = -0.054, P = 0.006 OR = 0.80, P = 0.018). For Ala55Val, genotype TT carriers showed a lower serum urate (TT/CC Beta = -0.075, P = 0.022) and a decreased risk of hyperuricemia (TT/CC OR = 0.64, P = 0.020). Genotype TC carriers only had a lower serum urate (TC/CC Beta = -0.082, P = 0.012) but no decreased risk of hyperuricemia (TC/CC OR = 0.77, P = 0.093). Allele T was associated with a lower serum urate (T/C Beta = -0.049, P = 0.016) and a decreased risk of hyperuricemia (T/C OR = 0.79, P = 0.016).Further abbreviation of associationin femaleswith different BMI levelsFurther abridgment was performed regarding the genetic effect of UCP2 variants on serum urate and the risk of hyperuricemia among females with different BMI levels (Table 2). The bulk of the females enrolled were stratified into sane- or overweight group (Table 2). In the underweight subgroup, whose sample size was limited after stratification, no significant association was observed between the two loci and serum urate or hyperuricemia risk (all P 0.025, Table 2). In the normal weight subgroup, -866G/A genotype AA+AG carriers were associated with a lower serum urate (AA+AG/GG Beta = -0.095, P = 0.022) but not with a decreased risk of hyperuricemia (AA+AG/GG OR = 0.65, P = 0.076). However, the Ala55Val genotypes or alleles showed no statistical association with serum urate (TT+TC/CC Beta = -0.070, P = 0.091 T/C Beta = -0.047, P = 0.106) or hyperuricemia (TT+TC/CC OR = 0.72, P = 0.173 T/C OR = 0.72, P = 0.051). In the overweight subgroup, the genotypes of both loci were associated a lower serum urate (AA+AG/GG Beta = -0.138, P = 0.001 TT+TC/CC Beta = -0.130, P = 0.003) and a significant, or at least marginal, decreased risk of hyperuricemia (AA+AG/GG OR = 0.62, P = 0.015 TT+TC/CC OR = 0.74, P = 0.027). However, the alleles of the loci were associated with a lower serum urate level (A/G Beta = -0.072, P = 0.019 T/C Beta = -0.072, P = 0.019) but not with a decreased risk of hyperuricemia (A/G OR = 0.75, P = 0.036 T/C OR = 0.74, P = 0.027). Our results suggested a stronger effect of UCP2 variants on overweight females than on normal weight females (Table 2).Association between haplotypes and risk of hyperuricemiaAs listed in Table 3, the haplotypes of the two loci were estimated in the total group of subjects and after stratification by gender. The -866G/A and Ala55Val variants were in strong linkage disequilibrium (D = 0.974, r2 = 0.936). The wild type haplotype G-C (-866G/A-Ala55Val) was applied as the reference one. Haplotype A-T made up for the most frequent one, while single version at -866G/A or Ala55Val each accounted for less than 1 percent (Table 3). In the total group of subjects, no haplotypes were jibe with susceptibility of hyperuricemia. In the female subgroups, haplotype A-T (-866G/A-Ala55Val) was associated with a decreased risk of hyperuricemia however, this association was useless in males. No further significant associations between hyperuricemia and other two rare haplotypes were found in our study, partly due to the limited size of the rare haplotypes carriers (Table 3). These results correlated with the association between genotypes or alleles and hyperuricemia (Table 1). handlingUncoupling protein 2 (UCP2) is present in the inner mitochondrial membr ane and mainly decreases the ATP level and ROS produced by electron transport therefore, UCP2 is involved in a board range of pathological processes. In the present study, we number one foc utilize on the relationship between UCP2 variants and serum urate and hyperuricemia, potentially examining the scope of the loci related to hyperuricemia.The present study revealed no association between the two polymorphisms of UCP2 and serum urate or hyperuricemia in the total group of subjects. However, because serum urate is extensively influenced by gender differences, we stratified the total group of subjects and unconquerable that -866G/A and Ala55Val were associated with serum urate and hyperuricemia in females 25-26. Females with the -866G/A genotype AA+AG or allele A had lower serum urate and a decreased risk of hyperuricemia, indicating a protective role of -866G/A for hyperuricemia in females.The -866G/A variant is a utilitarian polymorphism located in the promoter region and putat ively changes the transcription factor binding sites 7. The wild type G allele in -866G/A was associated with lower UCP2 mRNA smell 19, 27. Increased UCP2 mRNA expression from the A allele was translated into an enlarged amount of UCP2 protein, with corresponding induced proton leak, decreased ATP/ADP ratio and enhanced elimination of ROS 10, 19. Hypermethylation in the promoter region could affect the binding of transcripation factors, ca employ aberrant gene expression. Consistent with our expectations, we found a typical CpG island in the UCP2 promoter region, which included the locus of the -866G/A variant, using information from the University of California-Santa Cruz (UCSC Santa Cruz, CA, USA) database (http//genome.ucsc.edu/cgi-bin/hgGateway). We atomic number 5ieve the UCP2 promoter variant -866G/A could shape this CpG island and protect the UCP2 promoter region from desoxyribonucleic acid methylation, uncovering a novel underlying mechanism that determines -866G/A increa ses UCP2 transcription.Uric acid accumulation is caused by the acceleration of ATP degradation to AMP, a precursor of uric acid, and UCP2 could decrease the ATP level and lower redundant AMP for uric acid formation 7, 28. Moreover, an elevation of serum urate concentration occurs as a physiologic response to increased oxidative stress 31. Because the ROS level could be down- modulate by UCP2, a counter-regulatory increase of serum urate as an antioxidant defense is less urgent. Therefore, the -866G/A variant in the promoter region cogency serve as a protective factor through a higher UCP2 mRNA level and increased translation of the UCP2 protein, which magnate regulate ROS and modify the ATP/ADP ratio.The other locus, Ala55Val, is a missense variant in exon 4 and is associated with an altered degree of uncoupling 7. In our study, a protective effect for hyperuricemia and lower serum urate were observed in genotype TT and allele T in the female subgroups. However, the genetic effect of the Ala55Val variant was less clear. Several researchers identified an association of Ala55Val with the BMI level and type 2 diabetes mellitus (T2D), with polemic conclusions within cohorts, and few functional studies were performed 14, 32-33. Similar to -866G/A, the protective role of the Ala55Val variant for hyperuricemia superpower also be attributed to altered UCP2 transcription.In the male subgroups, a less statistically significant but possible effect of -866G/A and Ala55Val was observed for hyperuricemia risk and higher serum urate. Similar gender-associated genetic effects of UCP2 variants were to a greater extent or less observed for diseases other than hyperuricemia 7. For example, Heidema et al. suggested a genetic effect of UCP2 on weight gain was regulated through different mechanism in males and females 34. Lee, et al. demonstrated that the association between UCP2 variants and BMI was more apparent among female subjects 35. Cheurfa et al. confirmed the associati on of UCP2 variants with coronary artery diseases in males but not females 36. In the present study, we found UCP2 variants -866G/A and Ala55Val had a stronger effect on females with hyperuricemia. One possible explanation for the gender-associated genetic effects of UCP2 might be a regulation role of sex hormones such as estrogen. Estrogen was reported to tighten UCP2 in a breast cancer cell line and papillary thyroidal cancer cells 37-38. interpreted together, these results suggest the UCP2 protein level was down-regulated by estrogen in females but reversed by the variants of -866G/A and Ala55Val, providing a plausible explanation for the specific protective effects of UCP2 variants on females 37. elementtic effects on hyperuricemia and obesity have been widely recognized 3. In the present study, we found that -866G/A and Ala55Val were associated with lower serum urate and a decreased risk of hyperuricemia in overweight, but not underweight, females (Table 2). The relative smal l sample size might limit the correlation digest in the underweight group. However, we did observe females with higher BMI level were more apt(predicate) to benefit from the protective genetic effect of -866G/A and Ala55Val, where the association was significant between the two SNPs and serum urate level of risk of hyperuricemia. In the contrast, among the normal weight females, -866G/A, but not Ala55Val, showed a significant association with a low risk of hyperuricemia, indicating a less contribution from the protective effect of UCP2 variants than seen in overweight females. It was also implied from our results that the tw1functional 866GA promoter variant displayed a stronger effect. The interactions between obesity, uric acid and UCP2 were complicated. BMI has long been viewed as an inhering factor influencing uric acid 3. UCP2 transcription was activated by fatty acids 16. A recent meta-analysis revealed that UCP2 -866G/A and Ala55Val are associated with a risk of obesity 32 . Subtle intermediary obesity related phenotypes such as elevated triglycerides, total cholesterol concentrations, increased the risk of dyslipidemia and circulating leptin levels were also observed to be correlated with UCP2 variants 40. Based on these results, we assumed lipid metabolism material such as fatty acids participated in and enhanced the genetic effect of UCP2 variants on serum urate regulation, explaining the stronger genetic effect of UCP2 variants on females with higher BMI levels observed in the present study.The -866G/A and Ala55Val variants were in strong linkage disequilibrium (D = 0.974, r2 = 0.936). The haplotype frequency analysis revealed that variants of the two loci were more in co-variant haplotype A-T (-866G/A-Ala55Val) compared with the single variant forms of G-T or A-C (Table 3). Haplotype A-T was associated with a decreased risk of hyperuricemia only in females, which was accordant with the genotype or alleles results. However, the small size of the two rare haplotypes might limit the power of association analysis with hyperuricemia risk to a certain extent. The susceptibility of hyperuricemia in the two rare haplotype carriers required institution in a larger cohort.ConclusionThe present study identified a novel gene, UCP2, with two loci, -866G/A and Ala55Val this gene influenced the serum urate concentrations and the risk of hyperuricemia in females. The associations of those loci were affected by gender and BMI. This study supported the potential involvement of this gene in the prevention, prediction and treatment of hyperuricemia.Materials and methodsExperimental determinationA total of 4332 subjects were enrolled from the Taizhou Longitudinal Study 22 and included 1387 hyperuricemic patients and 2945 healthy controls. The associations of common UCP2 variants with serum urate and hyperuricemia were tested by linear infantile fixation and logistic regression with or without gender stratification, respectively. A body mass index (BMI) subgroup was also used for further analysis.ParticipantsAll subjects were enrolled from Taizhou Longitudinal Study 22, of which 1387 individuals had serum urate level over 7 mg/dl and were treated as hyperuricemic patients, and 2945 individuals had normal serum urate ( 7 mg/dl) and were treated as healthy controls 23. The subjects were carve up into subgroups (underweight BMI 18.5 normal weight 18.50 BMI Genetic analysisGenetic analysis was carried out in accordance with the create verbally informed consent and guideline offered by the Ethical Committees of the School of Life Science of Fudan University. For genetic analysis, peripheral device blood was collected from all the individuals included in this study. Genomic desoxyribonucleic acid was extracted from whole blood using the QIAamp DNA Blood Mini kit (QIAGEN, Germany) and was stored at -20. The DNA concentration and quality (including optical density (OD) 260/280 and 260/230 measurements) were determined usi ng a Nanodrop Lite spectrophotometer (Thermo Fisher Scientific, Waltham, MA, USA). Genotyping of -866G/A and Ala55Val in UCP2 were performed by SNPscan according to the manufacturers instructions.Statistical analysisThe clinical characteristics were presented as the close SD. Students t-test was used to test for a significant difference in the mean age, BMI and serum urate between hyperuricemic patients and healthy controls. The chi-square test was used to describe the gender distribution difference between hyperuricemic patients and healthy controls.The chi-square test was used to test Hardy-Weinberg equilibrium (HWE) of the two loci. We conducted a logistic regression analysis to calculate adjusted odd ratio (OR) with 95% confidence interval (95% CI) and P-values to describe the distribution of -866G/A and Ala55Val adjusted for age and gender between hyperuricemic patients and healthy controls. A linear regression was performed to calculate Beta and P-values to estimate the effe ct on serum urate in different genotypes and alleles. Genotype GG, allele G of -866G/A and genotype CC, allele C of Ala55Val were used as references, respectively. Stratification into subgroups was performed on the basis of gender and different BMI values for further analysis. Haplotype frequencies between the hyperuricemic patients and controls were estimated by OR (95% CI) and chi-square test. The haplotype of the most frequent (-866G/A-Ala55Val, G-C) was used as the reference. A 2-sided P-value less than 0.025 was considered statistically significant after multiple correlation by Bonferroni method. 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The computations involved in this study were supported by Fudan University High-End Computing Center.Author contributions statement