Literature DB >> 29849618

Uncoupling Protein 2 and Peroxisome Proliferator-Activated Receptor γ Gene Polymorphisms in Association with Diabetes Susceptibility in Chinese Han Population with Variant Glucose Tolerance.

Meicen Zhou1,2, Shuli He3, Fan Ping1, Wei Li1, Lixin Zhu4, Xiangli Cui4, Linbo Feng5, Xuefeng Zhao5, Huabing Zhang1, Yuxiu Li1, Qi Sun1.   

Abstract

OBJECTIVE: To investigate the association of polymorphisms in uncoupling protein 2 (UCP2) and peroxisome proliferator-activated receptor (PPARγ) with glucolipid metabolism in Chinese Han population.
METHODS: Five hundred eighty-nine subjects were divided into normal glucose tolerance (NGT) group (n = 198) and abnormal glucose tolerance group (n = 358). HbA1c, blood lipid profile, plasma glucose, and insulin were determined. Insulin sensitivity (HOMA-IR and Matsuda index (ISIM)) and insulin secretion indexes (HOMA-β, early and total phase disposition index) were evaluated. Eight potential functional SNPs in UCP2 and 7 in PPARγ were selected. SNPs were genotyped on Sequenom MassARRAY platform.
RESULTS: The GG genotype of rs2920502 in PPARγ was associated with decreased risk of impaired glucose tolerance (G allele: OR: 0.818, 95%CI: 0.526-0.969, P = 0.042; GG: OR: 0.715, 95%CI: 0.527-0.97, P = 0.031). The TT genotype of rs3856806 in PPARγ was associated with increased risk of impaired glucose tolerance (T allele: OR: 1.46, 95%CI: 1.055-2.017, P = 0.022; TT: OR: 1.58, 95%CI: 1.104-2.761, P = 0.032). The GG genotype of rs2920502 in PPARγ had better blood glucose and increased insulin secretion and had lower HOMA-IR than GC/CC genotypes.
CONCLUSION: It probably could prevent insulin resistance in early stage by classifying the genotype of rs649446 and rs7109266 in UCP2. The GG genotype of rs2920502 in PPARγ had a decreased risk for diabetes. The TT genotype of rs3856806 in PPARγ had an increased risk for diabetes.

Entities:  

Year:  2018        PMID: 29849618      PMCID: PMC5907424          DOI: 10.1155/2018/4636783

Source DB:  PubMed          Journal:  Int J Endocrinol        ISSN: 1687-8337            Impact factor:   3.257


1. Introduction

Uncoupling protein 2 (UCP2), which is widely expressed in human tissues and serves as an uncoupler of oxidative phosphorylation, is involved in the regulation of glucolipid metabolism and ATP production [1, 2]. The association of the polymorphisms in UCP2 with diabetes and obesity have been widely evaluated, most studies focused on Ala55Val (rs660339) in exon 4, 45 bp insertion/deletion in exon 8, and -866G/A (rs659336) in the promoter region [3, 4]. The polymorphisms in UCP2 regulate the expression of mRNA and protein, which have vital effects on islet β-cell function and insulin sensitivity [5, 6]. The -866AA genotype carriers have decreased glucose-stimulated insulin secretion and have increased risk of diabetes than those GG genotype carriers [7]. Although a variant allele of the Ala55Val polymorphism was reported to be associated with lower energy expenditure and the 45 bp insertion/deletion polymorphisms were found to be functional on mRNA expression, the association of Ala55Val (rs660339) in exon 4 with diabetes remain controversial [8-10]. Peroxisome proliferator-activated receptor (PPARs) play pivotal roles in the control of the transcription of UCP2 [11, 12]. PPARs have three isoforms, including Pparα, Pparδ, and PPARγ. PPARγ is a regulator of lipid and glucose metabolism and therefore its synthetic ligands such as glitazone—the derivative of thiazolidinediones (e.g., troglitazone, rosiglitazone, and pioglitazone)—improve insulin and glucose parameters and increase whole body insulin sensitivity [13]. These PPARγ synthetic ligands could indirectly increase insulin-stimulated glucose uptake in adipocytes, skeletal muscle cells, and hepatocytes [13]. Our previous study found that the UCP2-deficient mice fed with a long-term high-fat diet had better insulin sensitivity, improved lipid metabolism, and upregulated expression of PPARγ in PPAR signaling pathway, which suggested the ameliorated lipid metabolism and insulin sensitivity in UCP2-deficient mice probably via PPARγ. It was most likely that among Ppar isoforms, PPARγ was the major regulator of UCP2 in high-fat diet [14]. One study based on Chinese Han population showed that functional SNPs of PPARγ were associated with MetS [15]. The relationship between potential functional SNPs and diabetes remains unknown. The inflammation pathway is involved in the pathophysiology of diabetes and obesity. Previous study showed that PPAR polymorphisms were independently associated with CRP levels in Chinese Han population; PPARs polymorphisms interact with overweight/obesity to set CRP levels [16]. In healthy children and adolescents, UCP2 -866G>A modified low-grade inflammatory state [17]. Whether UCP2 and PPARγ polymorphisms have an effect on inflammation state in diabetes remains unknown. In this study, we built a Chinese Han population cohort with variant glucose tolerance and aimed to further investigate the association of polymorphisms in the functional region of UCP2 and PPARγ with glucolipid metabolism.

2. Subjects and Methods

2.1. Subjects

All subjects were recruited from a type 2 diabetes project in a Beijing suburb in China between March 2014 and January 2015. Five hundred eighty-nine subjects without a history of diabetes underwent a 75 g OGTT. The 75 g OGTT was conducted after an overnight fast (>10 hours). Blood samples were collected at 0 minutes, 30 minutes, 60 minutes, and 120 minutes following the OGTT. The glucose tolerance status of each subject was classified based on the 1999 criteria of the WHO: a normal glucose tolerance (NGT), indicated by fasting plasma glucose (FPG) < 6.1 mmol/l and 2 h postprandial glucose (2 h PG) < 7.8 mmol/l; prediabetes, indicated by impaired fasting glucose (IFT): 6.1 mmol/l ≤ FPG < 7.0 mmol/l and 2 h PG < 7.8 mmol/l; impaired glucose tolerance (IGT), indicated by FPG < 6.1 mmol/l and 7.8 ≤ 2 h PG < 11.1 mmol/l; or IFT + IGT, with T2DM indicated by FPG ≥ 7.0 mmol/l or 2 h PG ≥ 11.1 mmol/l. The subjects who have a current history of cigarette smoking and alcohol drinking were excluded, and subjects with serious diseases such as heart disease, stroke, kidney disease, liver disease, and inflammatory disease were also excluded. Subjects who were on steroids or who were taking drugs interfering with lipid metabolism such as lipid-lowering agents, diuretics, β-blockers, and fish oil were excluded. On the basis of the 75 g OGTT results, subjects were divided into normal glucose tolerance (NGT) group (n = 198) and abnormal glucose tolerance group (n = 358). The study protocol was approved by the Ethics Committee of Peking Union Medical College Hospital. The subjects voluntarily signed informed consent forms.

2.2. Clinical Measurement

A standardized medical history and accurate physical examination were undertaken in all of the subjects before a 75 g OGTT was administered. Measurements of waist circumference (WC) (midway between the iliac crest and the costal margin) and hip circumference (HC) (at the level of the trochanters) were performed twice by the same observer, and the mean value was recorded. Weight and height were measured without shoes in light clothing, and body mass index (BMI) was calculated by dividing the body weight in kilograms by the square of the height in meters. Blood pressure measurements were obtained twice with a standard mercury sphygmomanometer with the subjects at rest, and the mean value was calculated.

2.3. Biochemical Measurements

Plasma glucose was measured by glucose oxidase assay. TC, TG, HDL-C, and LDL-C were determined using an automated analyzer. Serum insulin and C peptide were measured by chemiluminescent enzyme immunoassay. HbA1c analysis was performed by high-performance liquid chromatography (intra-assay CV < 3%, interassay CV < 10%).

2.4. Assessment of IR

Homeostatic model assessment of insulin resistance (HOMA-IR) was calculated to evaluate the IR [18].

2.5. Assessment of β-Cell Function

The homeostasis model assessment of insulin secretion (HOMA-β) was calculated as basal insulin release [18]. Early-phase insulin release was calculated as the total insulin area under the curve divided by the total glucose area under the curve during the first 30 min of the OGTT (InsAUC30/GluAUC30), which was shown to have a strong correlation with first-phase insulin secretion [19]. Insulin secretion relative to insulin sensitivity (ISIM: Matsuda insulin sensitivity index) was expressed as the disposition index (DI), calculated as early-phase DI30 = [InsAUC30/GluACU30] × ISIM, (ΔIns30/ΔGlu30)/HOMA-IR and total-phase DI120 = [InsAUC120/GluACU120] × ISIM. Another formula for assessing early-phase insulin release was (ΔIns30/ΔGlu30)/HOMA-IR.

2.6. Measurement of Tumor Necrosis Factor-α (TNF-α) and Interleukine-6 (IL-6)

Serums were from fasting blood samples. The levels of TNF-α and IL-6 were performed as per the manufacturer's instructions (Cloud-Clone Corp., Houston, USA), and absorbance kinetics was measured through an ELISA reader.

2.7. SNP Selection, Genotyping, and Genotype Quality Control

Genomic DNA was extracted from peripheral blood samples using the QIAamp DNA blood mid kit (Qiagen, Hilden, Germany); purified DNA samples were diluted and quantified using a NanoDrop 1000 spectrophotometer (Thermo Fisher Scientific, Wilmington, DE, USA). We selected 8 potential functional SNPs of UCP2 and 7 potential functional SNPs of PPARγ, including promoter, exon, 5′ untranslated region and 3′ untranslated region based on the screening standards (the minor allele frequencies (MAF) are more than 20% in Han Chinese according to the HapMap Han Chinese in Beijing (CHB) group). Further, we reviewed the documents about the selected SNPs and forecasted their function according to NIH SNPinfo Web Server (http://snpinfo.niehs.nih.gov/) (Table 1). The MAFs of the selected SNPs in the study were listed in Table 2. All candidate SNPs were genotyped on Sequenom MassARRAY platform.
Table 1

The selected functional SNPs of UCP2 and PPARγ.

Gene nameSNP numberFunctionMinor allele frequencyData sourcesRelevant documentsFunction forecast
UCP2rs660339Missense0.422HapMapInvestigation of variants in UCP2 in Chinese type 2 diabetes and diabetic retinopathySplicing (ESE or ESS)/nsSNP
rs659366Promoter0.442HapMapThe common -866G/A polymorphism in the promoter region of the UCP-2 gene is associated with reduced risk of type 2 diabetes in Caucasians from ItalyTFBS
rs649446Promoter0.35HapMapNo reportTFBS
rs5867735′ near0.4761000 GenomesNo reportTFBS
rs344084265′ near0.4761000 GenomesNo reportTFBS
rs71092665′ near0.349HapMapNo reportTFBS
rs30194635′ near0.4761000 GenomesNo reportTFBS
rs5917585′ near0.422HapMapGenetic variants in the UCP2-UCP3 gene cluster and risk of diabetes in the Women's Health Initiative Observational StudyTFBS
PPARγ rs3856806Cds-synon0.233HapMapGene-gene interactions among PPARα/δ/γ polymorphisms for hypertriglyceridemia in Chinese Han population
rs2920502Promoter0.244HapMapGenetic variants in peroxisome proliferator-activated receptor-γ and retinoid X receptor-α gene and type 2 diabetes risk: a case-control study of a Chinese Han populationTFBS
rs170290075′ UTR0.1021000 GenomesNo reportTFBS/splicing
rs73021485Promoter0.3741000 GenomesNo report
rs738131685′ near0.1031000 GenomesNo report
rs29205035′ near0.321000 GenomesNo report
rs793108215′ near0.3711000 GenomesNo report

TFBS: transcription factor binding site.

Table 2

The MAFs of the selected SNPs in the study.

ChromosomeGene nameSNP numberAllelesDetection rate (%)MAF in CHBMAF in the study
11UCP2rs660339A/G99.80.420.47
rs659366T/C99.80.440.48
rs649446T/C99.80.350.34
rs586773T/A98.90.480.48
rs34408426G/A99.30.480.48
rs7109266A/G99.80.350.33
rs3019463T/C97.40.480.48
rs591758C/G99.80.420.48
3PPARγ rs2920503A/G97.70.320.31
rs73813168G/A98.50.100.12
rs79310821A/G99.20.370.35
rs73021485T/G99.70.370.35
rs2920502G/C99.30.240.31
rs17029007A/G98.90.100.13
rs3856806T/C99.50.230.20

MAF: minor allele frequency; CHB: Han Chinese in Beijing.

2.8. Statistical Analysis

Continuous variables were expressed as mean ± standard deviations (SD). Statistical significances for continuous variables were assessed using Student's t-test and for categorical variables using chi-square test. Hardy-Weinberg equilibrium tests were performed using Pearson's chi-square for each SNP among control subjects. One-way ANOVA was used to compare different genotypes of every SNP site for continuous variables. All the statistical analyses were performed using SPSS 19.0 for windows and SAS 9.2 (SAS Institute) and a P value of <0.05 was considered statistically significant.

3. Results

3.1. Allele Frequency Analysis

All loci conformed to Hardy-Weinberg equilibrium as shown in Supplementary Table 1. There was no significant difference in allele frequency of each SNP in UCP2 between prediabetes/diabetes group and normal glucose tolerance group (Table 3). In PPARγ, the G allele in rs2920502 decreased the risk of diabetes (OR: 0.818, 95%CI: 0.526–0.969, P = 0.042), the T allele in rs3856806 increased the risk of diabetes (OR: 1.46, 95%CI: 1.055–2.017, P = 0.022) (Table 3). In UCP2, there was no significant difference between alleles in each SNP.
Table 3

Allele frequency analysis between prediabetes/diabetes group and normal blood glucose group.

Gene nameSNP numberAllelePrediabetes/diabetes groupNormal blood glucose groupOdd ratio (OR)95% confidence interval (CI) P value
(N)(N)LowHigh
UCP2rs660339A3461870.9970.7751.2810.9778
G388209
rs659366T3511920.9730.7581.2480.828
C383204
rs649446T2441360.9490.7281.2380.700
C490260
rs586773T3511920.9590.7501.2270.741
A381200
rs34408426G3501930.9590.7501.2270.738
A380201
rs7109266A2401350.9350.7151.2220.624
G494261
rs3019463T3431880.9780.7631.2530.861
C373200
rs591758C3521940.9590.7501.2270.738
G382202
PPARγ rs2920503A2131260.9180.7081.1910.519
G499270
rs73813168G80580.6930.4741.0120.057
A646334
rs79310821A2651261.20.9241.5600.172
G467266
rs73021485T2711271.2410.9571.6090.104
G463269
rs2920502G2141320.8180.5260.9690.042
C516262
rs17029007A81600.6990.4861.0050.053
G645336
rs3856806T163661.4601.0552.0170.022
C567330

∗ P < 0.05.

3.2. Genotype Analysis

The association of SNPs with prediabetes/diabetes was assessed by crosstab test and logistic regression after adjustment for age and sex. In PPARγ, the frequency of GG genotype in rs2920502 was significantly lower in prediabetes/diabetes subjects (6.85%) than in the normal glucose tolerance subjects (12.69%); logistic regression analysis revealed that subjects with GG genotype of rs2920502 in PPARγ had less risk for prediabetes/diabetes compared to CC genotype (odd ratio (OR): 0.715; 95% confidence interval (CI): 0.527–0.97, P = 0.031). The frequency of TT genotype in rs3856806 was significantly higher in prediabetes/diabetes subjects than in the normal glucose tolerance subjects; logistic regression analysis showed that subjects with TT genotype of rs3856806 in PPARγ had higher risk for diabetes compared to CC (OR: 1.58, 95%CI: 1.104–2.761, P = 0.032). Furthermore, we, respectively, performed a logistic regression analysis under a recessive inheritance model (GG versus GC + CC) in rs2920502 and a dominant inheritance model (TT + TC/CC) in rs3856806; the regression showed that the odd ratio for GG versus GC + CC in rs2920502 was 0.506 (95%CI: 0.282–0.906, P = 0.022) and the odd ratio for TT + TC/CC in rs3856806 was 1.479 (95%CI: 1.026–2.133, P = 0.036). These were in accordance with the allele frequency analysis, which implied that G allele carriers in rs2920502 were less susceptible to develop diabetes and T allele carriers in rs3856806 were more susceptible to develop diabetes. No significant difference was found at other loci in PPARγ (Table 4). There was no significant difference in the genotype of each SNPs in UCP2 (Table 4).
Table 4

Genotype analysis between prediabetes/diabetes group and normal blood glucose group.

Gene nameSNP numberGenotypePrediabetes/diabetes groupNormal blood glucose groupOdd ratio (OR)95% confidence interval (CI) P value
LowHigh
UCP2rs660339AA77420.9960.7741.280.9781
AG192103
GG9853
rs659366TT80450.9720.7571.2470.968
TC191102
CC9651
rs649446TT38191.0030.7391.3620.699
TC16898
CC16181
rs586773TT83470.9590.7491.2260.9377
TA18598
AA9851
rs34408426GG83470.9590.7491.2260.9444
GA18499
AA9851
rs7109266AA36180.9970.7291.3630.631
AG16899
GG16381
rs3019463TT82450.9790.7631.2550.9793
TC17998
CC9751
rs591758CC83470.9590.7491.2260.9443
CG186100
GG9851
PPARγ rs2920503AA34230.8910.6651.1930.438
AG14580
GG17795
rs73813168GG220.7010.2621.8770.480
AA285140
AG7654
rs79310821AA44231.1080.8341.4710.480
AG17780
GG14593
rs73021485TT47231.1590.8751.5350.304
GG14394
GT17781
rs2920502GG25250.7150.5270.970.031
CC17690
CG16482
rs17029007AA530.9050.4391.8640.786
AG7154
GG287141
rs3856806TT1631.581.1042.7610.032
CC218136
CT13158

∗ P < 0.05.

3.3. Haplotype Analysis

There was a linkage disequilibrium in PPARγ and UCP2, respectively. The haplotype frequency distribution of each gene between prediabetes/diabetes and normal glucose tolerance was summarized in Table 5; however, haplotype frequency was not significantly different between prediabetes/diabetes and control.
Table 5

The haplotype frequency distribution between prediabetes/diabetes and normal glucose tolerance.

Gene nameHaplotypePrediabetes/diabetes, normal glucose tolerance frequency χ 2 P value
UCP2GCCAAGCG0.511, 0.5130.0030.953
ATTTGATC0.318, 0.3290.1330.715
ATCTGGTC0.146, 0.1430.0210.884
PPARγ CAATCG0.362, 0.3162.4730.1158
TAGGCG0.307, 0.3180.1490.6992
CAGGGG0.182, 0.1840.0080.9304
CGGGGA0.109, 0.1463.2680.0706
CAGGCG0.029, 0.0250.1470.7015

3.4. Association of Genotype with Demographic Characteristics

In UCP2, the waist-to-hip ratio in subjects with AA genotype of rs7109266 were higher than that in subjects with GG or GA genotype, but age, BMI, and blood pressure were not different among genotypes of other SNPs (Table 6). Age, BMI, blood pressure, and waist-to-hip ratio were not different among genotypes of selected SNPs in PPARγ (Table 7).
Table 6

Association of genotype and demographic characteristics in UCP2.

GenotypeAge (year)BMI (kg/m2)Waist-to-hip ratioSystolic blood pressure (mmHg)Diastolic blood pressure (mmHg)
rs660339
GG52.87 ± 1.0325.62 ± 0.290.94 ± 0.00129.51 ± 1.6175.28 ± 0.78
AA54.22 ± 1.0025.94 ± 0.350.95 ± 0.02128.74 ± 1.7876.42 ± 0.96
GA54.00 ± 0.6626.07 ± 0.230.94 ± 0.00126.78 ± 1.0376.62 ± 0.59
P value0.5570.510.4920.30.405
rs659366
CC53.26 ± 1.0325.55 ± 0.280.94 ± 0.00129.69 ± 1.6575.39 ± 0.79
TT54.48 ± 1.0025.91 ± 0.340.95 ± 0.02128.60 ± 1.7676.15 ± 0.93
TC53.68 ± 0.6726.11 ± 0.230.94 ± 0.00126.75 ± 1.0276.67 ± 0.59
P value0.6830.3530.5030.2690.452
rs649446
CC52.47 ± 0.7825.63 ± 0.230.94 ± 0.00128.65 ± 1.1875.85 ± 0.64
TT56.44 ± 1.5126.71 ± 0.480.97 ± 0.04128.98 ± 2.5974.18 ± 1.41
TC54.29 ± 0.6826.02 ± 0.250.94 ± 0.00126.87 ± 1.1576.91 ± 0.61
P value0.0580.1320.0550.50.138
rs7109266
GG52.61 ± 0.7825.64 ± 0.230.93 ± 0.00128.65 ± 1.1775.78 ± 0.64
AA56.28 ± 1.5726.65 ± 0.500.98 ± 0.04129.26 ± 2.7074.69 ± 1.44
GA54.24 ± 0.6826.03 ± 0.250.94 ± 0.00126.82 ± 1.1476.84 ± 0.61
P value0.0680.1770.017 0.4560.254
rs591758
GG53.24 ± 1.0325.59 ± 0.280.94 ± 0.00129.77 ± 1.6375.56 ± 0.78
CC54.71 ± 0.9925.95 ± 0.340.95 ± 0.02128.62 ± 1.7676.05 ± 0.90
CG53.57 ± 0.6726.08 ± 0.240.94 ± 0.00126.64 ± 1.0376.64 ± 0.60
P value0.5390.450.430.2240.558
rs586773
AA53.24 ± 1.0325.59 ± 0.280.94 ± 0.00129.77 ± 1.6375.56 ± 0.78
TT54.71 ± 0.9925.95 ± 0.340.95 ± 0.02128.62 ± 1.7676.05 ± 0.90
AT53.64 ± 0.6826.07 ± 0.240.94 ± 0.00126.67 ± 1.0376.66 ± 0.61
P value0.5530.4590.4360.2350.548
rs34408426
AA53.24 ± 1.0325.59 ± 0.280.94 ± 0.00129.77 ± 1.6375.56 ± 0.78
GG54.71 ± 0.9925.95 ± 0.340.95 ± 0.02128.62 ± 1.7676.05 ± 0.90
AG53.64 ± 0.6726.06 ± 0.240.94 ± 0.00126.77 ± 1.0376.74 ± 0.60
P value0.5520.4780.430.260.495
rs3019463
CC53.24 ± 1.0425.60 ± 0.280.94 ± 0.00129.84 ± 1.6475.53 ± 0.79
TT54.71 ± 1.0125.98 ± 0.340.95 ± 0.02128.83 ± 1.7976.04 ± 0.92
TC53.58 ± 0.6826.03 ± 0.240.94 ± 0.00126.29 ± 1.0376.38 ± 0.61
P value0.5510.5190.4290.1380.709

∗ P < 0.05.

Table 7

Association of genotype and demographic characteristics in PPARγ.

GenotypeAge (year)BMI (kg/m2)Waist-to-hip ratioSystolic blood pressure (mmHg)Diastolic blood pressure (mmHg)
rs2920503
CC53.99 ± 0.7126.09 ± 0.220.94 ± 0.01128.06 ± 1.1076.26 ± 0.57
CT54.25 ± 0.7425.69 ± 0.270.94 ± 0.00128.02 ± 1.2975.99 ± 0.71
TT50.03 ± 1.5425.78 ± 0.470.94 ± 0.00126.33 ± 2.4475.91 ± 1.45
P value0.4300.5020.5830.8060.946
rs73813168
AA53.79 ± 0.5725.92 ± 0.190.94 ± 0.01128.15 ± 0.8776.04 ± 0.48
GA53.41 ± 1.0025.89 ± 0.320.94 ± 0.01127.27 ± 1.8277.02 ± 0.93
GG52.25 ± 6.1328.91 ± 1.870.94 ± 0.01124.75 ± 15.3069.00 ± 4.65
P value0.920.290.9950.8450.215
rs79310821
GA54.33 ± 0.6725.73 ± 0.230.94 ± 0.00127.97 ± 1.0676.23 ± 0.61
GG52.11 ± 0.7726.19 ± 0.250.94 ± 0.00127.57 ± 1.3076.31 ± 0.69
AA53.66 ± 1.5525.77 ± 0.520.93 ± 0.01128.56 ± 2.4375.95 ± 1.11
P value0.0510.3780.7350.9240.969
rs73021485
GT55.29 ± 0.6725.73 ± 0.230.95 ± 0.01128.21 ± 1.0676.30 ± 0.61
GG53.87 ± 0.7826.17 ± 0.250.94 ± 0.00127.35 ± 1.3076.17 ± 0.69
TT54.29 ± 1.5325.81 ± 0.500.93 ± 0.01128.13 ± 2.3875.75 ± 1.08
P value0.0580.4250.5770.8670.923
rs2920502
GC54.15 ± 0.7125.93 ± 0.220.95 ± 0.01128.24 ± 1.1976.62 ± 0.64
CC53.97 ± 0.7225.77 ± 0.240.93 ± 0.00127.89 ± 1.1275.98 ± 0.61
GG50.36 ± 1.8526.72 ± 0.610.94 ± 0.00126.33 ± 2.7875.10 ± 1.43
P value0.0980.2740.3520.8030.561
rs17029007
GG53.76 ± 0.5725.92 ± 0.190.94 ± 0.01128.17 ± 0.8676.07 ± 0.47
GA53.74 ± 1.0325.87 ± 0.340.94 ± 0.01126.59 ± 1.8677.01 ± 0.96
AA50.75 ± 4.2027.74 ± 1.040.94 ± 0.01128.88 ± 10.2068.75 ± 2.56
P value0.7680.3990.9920.6980.069
rs3856806
CC52.84 ± 0.6225.84 ± 0.200.94 ± 0.00128.17 ± 1.0176.17 ± 0.53
TC54.77 ± 0.8426.03 ± 0.300.95 ± 0.01127.02 ± 1.2676.35 ± 0.73
TT55.45 ± 2.4726.33 ± 0.710.93 ± 0.01130.75 ± 5.3175.50 ± 2.73
P value0.0520.7650.6130.6160.932

3.5. Association of Genotype with Insulin Secretion Function, Blood Glucose, and Lipid Profiles

Subjects with TT genotype of rs649446 or with AA genotype of rs7109266 in UCP2 had higher fasting insulin, HOMA-IR, and HOMA-β than subjects with other genotypes, but blood glucose profiles including fasting and 2 hr postprandial glucose were not significantly different among genotypes (Table 8). There was no significant difference in glucose profiles and insulin secretion in other loci of UCP2 (Table 8). The serum lipid TC, TG, HDL-C, and LDL-C were not significantly different among genotypes of selected SNPs in UCP2 (Table 9).
Table 8

Association of genotype with insulin secretion function and blood glucose in UCP2.

GenotypeHbA1c%FPG (mmol/l)Glu30′ (mmol/l)Glu60′ (mmol/l)Glu120′ (mmol/l)Ins0′ (μIU/ml)Ins30′ (μIU/ml)Ins60′ (μIU/ml)Ins120′ (μIU/ml)HOMA-IRHOMA-β DI30 DI120
rs660339
GG6.06 ± 0.116.89 ± 0.2111.37 ± 0.3111.26 ± 0.429.66 ± 0.4611.79 ± 0.7778.32 ± 5.2478.70 ± 4.7651.97 ± 3.603.43 ± 0.2388.43 ± 5.73414.74 ± 23.47536.01 ± 24.80
AA5.99 ± 0.116.80 ± 0.2311.23 ± 0.3211.38 ± 0.449.55 ± 0.4812.48 ± 1.1669.12 ± 4.9174.85 ± 4.5357.01 ± 3.973.92 ± 0.4390.93 ± 6.62383.99 ± 27.42514.93 ± 28.03
GA6.01 ± 0.076.68 ± 0.1311.01 ± 0.2110.92 ± 0.298.83 ± 0.2812.29 ± 0.6171.72 ± 3.2878.81 ± 3.4758.45 ± 3.073.97 ± 0.3389.23 ± 3.38420.51 ± 17.56587.96 ± 34.53
P value0.8940.6770.5920.6330.1870.8490.3790.8030.4120.5240.950.5180.294
rs659366
CC6.05 ± 0.116.88 ± 0.2211.37 ± 0.3211.28 ± 0.439.68 ± 0.4711.80 ± 0.7977.38 ± 5.2778.68 ± 4.8252.52 ± 3.683.43 ± 0.2488.80 ± 5.86410.35 ± 23.43535.63 ± 25.18
TT5.93 ± 0.116.74 ± 0.2211.09 ± 0.3111.07 ± 0.439.31 ± 0.4612.56 ± 1.1271.34 ± 5.0575.55 ± 4.7758.35 ± 4.313.88 ± 0.4292.55 ± 6.54395.63 ± 27.34526.68 ± 27.42
TC6.04 ± 0.076.71 ± 0.1411.07 ± 0.2111.04 ± 0.298.92 ± 0.2812.24 ± 0.6071.39 ± 3.2578.60 ± 3.4157.57 ± 2.983.99 ± 0.3388.32 ± 3.34418.18 ± 17.59583.49 ± 34.57
P value0.6770.7960.7060.8890.3270.840.560.8710.5260.5180.8210.7770.43
rs649446
CC6.06 ± 0.096.84 ± 0.1611.24 ± 0.2411.20 ± 0.339.46 ± 0.3412.05 ± 0.5575.14 ± 3.9979.96 ± 3.9556.72 ± 3.323.61 ± 0.1890.91 ± 4.38404.52 ± 18.16535.54 ± 20.23
TT6.06 ± 0.166.90 ± 0.3211.50 ± 0.4711.65 ± 0.6510.06 ± 0.7316.71 ± 2.9674.87 ± 7.7483.49 ± 7.8667.33 ± 7.155.78 ± 1.53108.66 ± 12.90335.15 ± 26.95466.10 ± 31.42
TC5.98 ± 0.076.67 ± 0.1511.01 ± 0.2110.93 ± 0.298.81 ± 0.3011.38 ± 0.5070.59 ± 3.3275.06 ± 3.2454.06 ± 2.763.59 ± 0.2383.77 ± 3.10433.37 ± 19.96599.24 ± 37.91
P value0.7650.6760.5810.5670.1560.003 0.6550.4690.1760.006 0.026 0.0660.096
rs7109266
GG6.07 ± 0.096.86 ± 0.1611.24 ± 0.2411.24 ± 0.339.48 ± 0.3412.03 ± 0.5574.80 ± 3.9679.68 ± 3.9256.77 ± 3.293.62 ± 0.1890.40 ± 4.35402.30 ± 18.07533.33 ± 20.14
AA6.07 ± 0.176.96 ± 0.3311.58 ± 0.5011.79 ± 0.6710.16 ± 0.7717.11 ± 3.1276.19 ± 8.1084.59 ± 8.2068.44 ± 7.515.98 ± 1.61109.45 ± 13.52334.04 ± 28.21461.60 ± 33.00
GA5.97 ± 0.076.64 ± 0.1510.99 ± 0.2110.87 ± 0.298.78 ± 0.3011.37 ± 0.4970.64 ± 3.3175.15 ± 3.2353.93 ± 2.753.57 ± 0.2384.30 ± 3.09434.69 ± 19.84601.13 ± 37.71
P value0.6010.5020.490.4010.1070.001 0.6560.4490.1370.003 0.031 0.060.078
rs591758
GG6.05 ± 0.116.87 ± 0.2111.33 ± 0.3111.24 ± 0.429.66 ± 0.4611.91 ± 0.7977.66 ± 5.2278.40 ± 4.7552.65 ± 3.633.46 ± 0.2389.39 ± 5.7410.86 ± 23.20534.33 ± 24.89
CC5.94 ± 0.116.78 ± 0.2311.11 ± 0.3011.11 ± 0.419.32 ± 0.4513.43 ± 1.3673.30 ± 5.0678.32 ± 4.8359.57 ± 4.334.45 ± 0.7094.35 ± 6.42392.34 ± 26.39525.85 ± 26.71
CG6.04 ± 0.076.70 ± 0.1411.07 ± 0.2111.04 ± 0.298.91 ± 0.2911.79 ± 0.4870.32 ± 3.2577.56 ± 3.4356.98 ± 3.003.71 ± 0.2187.12 ± 3.36419.88 ± 17.95585.93 ± 35.37
P value0.730.7750.770.920.3430.3220.4570.9870.4850.2090.570.6820.381
rs586773
AA6.05 ± 0.116.87 ± 0.2111.33 ± 0.3111.24 ± 0.429.66 ± 0.4611.91 ± 0.7977.66 ± 5.2278.40 ± 4.7552.65 ± 3.633.46 ± 0.2389.39 ± 5.79410.86 ± 23.20534.33 ± 24.89
TT5.94 ± 0.116.78 ± 0.2311.11 ± 0.3011.11 ± 0.419.32 ± 0.4513.43 ± 1.3673.30 ± 5.0678.32 ± 4.8359.57 ± 4.334.45 ± 0.7094.35 ± 6.42392.34 ± 26.39525.85 ± 26.71
AT6.04 ± 0.076.71 ± 0.1411.10 ± 0.2111.09 ± 0.308.93 ± 0.2911.80 ± 0.4970.25 ± 3.2977.60 ± 3.4657.04 ± 3.033.73 ± 0.2286.95 ± 3.39418.26 ± 18.06583.80 ± 35.73
P value0.7110.8040.7980.9520.3650.330.4530.9880.4840.2140.5570.7130.413
rs34408426
AA6.05 ± 0.116.87 ± 0.2111.33 ± 0.3111.24 ± 0.429.66 ± 0.4611.91 ± 0.7977.66 ± 5.2278.40 ± 4.7552.65 ± 3.633.46 ± 0.2389.39 ± 5.79410.86 ± 23.20534.33 ± 24.89
GG5.94 ± 0.116.78 ± 0.2311.11 ± 0.3011.11 ± 0.419.32 ± 0.4513.43 ± 1.3673.30 ± 5.0678.32 ± 4.8359.57 ± 4.334.45 ± 0.7094.35 ± 6.42392.34 ± 26.39525.85 ± 26.71
AG6.03 ± 0.076.67 ± 0.1311.02 ± 0.2111.00 ± 0.298.90 ± 0.2911.81 ± 0.4970.71 ± 3.2877.99 ± 3.4657.37 ± 3.023.71 ± 0.2187.48 ± 3.38421.79 ± 18.08588.64 ± 35.70
P value0.7470.6980.6940.8820.3310.3320.4990.9970.4710.2090.6020.6460.35
rs3019463
CC6.03 ± 0.116.85 ± 0.2111.30 ± 0.3111.19 ± 0.429.60 ± 0.4611.91 ± 0.7977.96 ± 5.2578.59 ± 4.7852.63 ± 3.663.45 ± 0.2489.77 ± 5.82413.23 ± 23.25537.30 ± 24.89
TT5.96 ± 0.116.82 ± 0.2311.15 ± 0.3111.23 ± 0.429.40 ± 0.4613.54 ± 1.3972.78 ± 5.1179.20 ± 4.9060.35 ± 4.414.51 ± 0.7294.20 ± 6.53381.46 ± 25.95518.95 ± 26.89
TC6.02 ± 0.076.67 ± 0.1411.08 ± 0.2211.00 ± 0.308.91 ± 0.2911.75 ± 0.5070.74 ± 3.3078.34 ± 3.5057.65 ± 3.083.70 ± 0.2287.13 ± 3.38425.19 ± 18.44593.35 ± 36.28
P value0.8640.740.8470.8830.3690.2780.4730.990.410.1720.590.390.275

∗ P < 0.05. DI30 (early-phase disposition index of insulin secretion) = [InsAUC30/GluAUC30] × ISIM, DI120 (total-phase disposition of insulin secretion) = [InsAUC120/GluAUC120] × ISIM.

Table 9

Association of genotype with lipid profiles in UCP2.

GenotypeTC (mmol/l)TG (mmol/l)HDL-C (mmol/l)LDL-C (mmol/l)TG/HDL-C
rs660339
GG5.44 ± 0.091.81 ± 0.161.35 ± 0.042.82 ± 0.061.45 ± 0.12
AA5.49 ± 0.101.72 ± 0.101.30 ± 0.032.85 ± 0.071.45 ± 0.10
GA5.39 ± 0.062.16 ± 0.411.29 ± 0.022.83 ± 0.041.79 ± 0.32
P value0.7020.6780.3590.930.627
rs659366
CC5.44 ± 0.091.73 ± 0.141.34 ± 0.052.83 ± 0.061.41 ± 0.11
TT5.49 ± 0.101.69 ± 0.101.30 ± 0.032.86 ± 0.071.43 ± 0.09
TC5.39 ± 0.062.22 ± 0.421.29 ± 0.022.82 ± 0.041.82 ± 0.32
P value0.6720.5360.4050.9190.519
rs649446
CC5.35 ± 0.072.34 ± 0.531.34 ± 0.032.77 ± 0.051.85 ± 0.40
TT5.61 ± 0.161.66 ± 0.121.29 ± 0.042.95 ± 0.121.40 ± 0.12
TC5.44 ± 0.061.72 ± 0.071.28 ± 0.022.86 ± 0.051.48 ± 0.07
P value0.2540.390.2570.1570.544
rs7109266
GG5.35 ± 0.072.33 ± 0.521.34 ± 0.032.77 ± 0.051.84 ± 0.40
AA5.56 ± 0.171.63 ± 0.121.28 ± 0.042.93 ± 0.121.39 ± 0.13
GA5.45 ± 0.061.73 ± 0.071.28 ± 0.022.87 ± 0.041.48 ± 0.07
P value0.3510.4040.2490.2060.563
rs591758
GG5.44 ± 0.091.72 ± 0.131.34 ± 0.042.84 ± 0.061.41 ± 0.11
CC5.49 ± 0.101.69 ± 0.101.30 ± 0.032.86 ± 0.071.43 ± 0.09
CG5.38 ± 0.062.23 ± 0.431.29 ± 0.022.82 ± 0.041.83 ± 0.33
P value0.6330.5090.4970.8460.501
rs586773
AA5.44 ± 0.091.72 ± 0.131.34 ± 0.042.84 ± 0.061.41 ± 0.11
TT5.49 ± 0.101.69 ± 0.101.30 ± 0.032.86 ± 0.071.43 ± 0.09
AT5.38 ± 0.062.23 ± 0.431.30 ± 0.022.82 ± 0.041.82 ± 0.33
P value0.6350.5150.5150.8550.508
rs34408426
AA5.44 ± 0.091.72 ± 0.131.34 ± 0.042.84 ± 0.061.41 ± 0.11
GG5.49 ± 0.101.69 ± 0.101.30 ± 0.032.86 ± 0.071.43 ± 0.09
AG5.37 ± 0.062.20 ± 0.431.29 ± 0.022.81 ± 0.041.82 ± 0.33
P value0.5360.5540.4490.8290.521
rs3019463
CC5.43 ± 0.091.72 ± 0.141.34 ± 0.052.83 ± 0.061.41 ± 0.11
TT5.51 ± 0.101.69 ± 0.101.30 ± 0.032.87 ± 0.071.43 ± 0.09
TC5.38 ± 0.072.23 ± 0.441.30 ± 0.022.81 ± 0.041.82 ± 0.34
P value0.5380.5220.5610.7440.527
Subjects with GG genotype of rs2920502 in PPARγ had better HbA1c, 0 min, 30 min, and 120 min blood glucose, increased 60 min and 120 min insulin secretion after taking 75 g glucose, and lower serum TC, TG, and LDL-C compared to GC/CC genotypes (Table 10); the HOMA-IR in GG genotype was lower than GC/CC genotypes. Subjects with TT genotype of rs2920503 in PPARγ had better HbA1c, 0 min, 30 min, 60 min, and 120 min blood glucose and had increased serum insulin in 120 min after taking 75 g glucose compared to TC/CC genotypes (Table 10). Subjects with TT genotypes of rs3856806 had higher fasting blood glucose than TC/CC genotypes, and postprandial blood glucose and insulin secretion were not significantly different among genotypes. The blood glucose at 0 min, 30 min, 60 min, and 120 min after taking 75 g glucose in subjects with AA/GG genotype of rs79310821 were better than subjects with GA genotype. The blood glucose at 0 min, 30 min, 60 min, and 120 min after taking 75 g glucose in subjects with TT/GG genotype of rs79310821 was better than that in subjects with TG genotype, and index of insulin secretion-HOMA-β, DI30, and DI120 were higher in TT/GG genotype than in TG genotype. The serum lipid profiles were not significantly different in other loci in PPARγ (Table 11).
Table 10

Association of genotype with insulin secretion function and blood glucose in PPARγ.

GenotypeHbA1c%FPG (mmol/l)Glu30′ (mmol/l)Glu60′ (mmol/l)Glu120′ (mmol/l)Ins0′ (μIU/ml)Ins30′ (μIU/ml)Ins60′ (μIU/ml)Ins120′ (μIU/ml)HOMA-IRHOMA-β DI30 DI120
rs2920503
CC6.06 ± 0.086.84 ± 0.1611.34 ± 0.2311.16 ± 0.329.17 ± 0.3311.59 ± 0.5773.21 ± 3.4974.50 ± 3.4450.88 ± 2.743.69 ± 0.3385.26 ± 3.25423.09 ± 18.98577.78 ± 37.56
CT6.10 ± 0.086.87 ± 0.1611.32 ± 0.2511.55 ± 0.339.69 ± 0.3513.10 ± 0.8672.05 ± 3.9182.18 ± 3.9553.29 ± 6.524.15 ± 0.3292.27 ± 5.27387.24 ± 19.31527.33 ± 20.78
TT5.59 ± 0.115.98 ± 0.129.82 ± 0.299.33 ± 0.447.72 ± 0.3512.05 ± 0.9278.26 ± 8.0678.79 ± 6.9562.76 ± 3.493.31 ± 0.29101.01 ± 6.49460.64 ± 35.70592.80 ± 31.89
P value0.019 0.039 0.012 0.01 0.034 0.2950.770.3320.024 0.4050.1860.1780.434
rs73813168
AA6.02 ± 0.066.77 ± 0.1211.16 ± 0.1811.14 ± 0.249.32 ± 0.2511.90 ± 0.4171.68 ± 2.7778.64 ± 2.7657.65 ± 2.393.67 ± 0.1787.72 ± 2.87402.67 ± 13.84556.93 ± 24.92
GA6.04 ± 0.116.78 ± 0.2311.21 ± 0.3211.13 ± 0.468.87 ± 0.4612.14 ± 1.0475.88 ± 5.2776.82 ± 5.2252.35 ± 4.133.99 ± 0.6389.11 ± 5.46439.29 ± 29.79570.00 ± 31.05
GG5.85 ± 0.125.99 ± 0.1911.09 ± 0.8010.54 ± 1.916.21 ± 1.1212.59 ± 3.3499.09 ± 51.5473.55 ± 20.4643.04 ± 15.773.35 ± 0.86102.59 ± 30.85414.77 ± 154.51513.87 ± 66.05
P value0.9470.8140.990.970.3360.960.5060.9390.4790.7770.8640.4770.946
rs79310821
GA6.16 ± 0.087.08 ± 0.1811.59 ± 0.2411.76 ± 0.339.92 ± 0.3512.81 ± 0.8768.22 ± 3.2476.64 ± 3.4756.29 ± 3.033.92 ± 0.3683.64 ± 3.79412.36 ± 20.56522.64 ± 21.28
GG5.91 ± 0.086.52 ± 0.1310.80 ± 0.2210.68 ± 0.318.71 ± 0.3112.14 ± 0.4876.31 ± 3.9678.00 ± 3.6356.77 ± 3.093.80 ± 0.2891.79 ± 4.26403.67 ± 16.44586.01 ± 36.88
AA5.89 ± 0.116.39 ± 0.1710.67 ± 0.3710.13 ± 0.518.30 ± 0.5210.14 ± 0.6278.61 ± 8.3980.96 ± 8.1956.84 ± 6.703.50 ± 0.33105.43 ± 8.54442.89 ± 46.25583.89 ± 43.95
P value0.0550.015 0.029 0.012 0.009 0.1920.210.8560.9930.8550.0690.6950.301
rs73021485
GT6.14 ± 0.087.06 ± 0.1811.59 ± 0.2411.74 ± 0.329.86 ± 0.3412.32 ± 0.8268.11 ± 3.2276.83 ± 3.4756.48 ± 3.034.14 ± 0.4082.09 ± 3.90373.32 ± 17.21509.27 ± 19.15
GG5.91 ± 0.086.51 ± 0.1310.80 ± 0.2210.67 ± 0.318.67 ± 0.3112.17 ± 0.4876.73 ± 3.9778.64 ± 3.6656.42 ± 3.093.56 ± 0.1796.67 ± 4.06438.29 ± 20.28564.71 ± 19.91
TT5.97 ± 0.126.51 ± 0.1910.74 ± 0.3910.30 ± 0.558.59 ± 0.5711.87 ± 1.2578.18 ± 8.1480.13 ± 7.8656.92 ± 6.443.52 ± 0.4891.36 ± 9.05460.55 ± 37.27724.86 ± 133.17I
P value0.1120.028 0.031 0.019 0.021 0.9490.1860.890.9970.3630.041 0.018 0.004
rs2920502
GC6.20 ± 0.107.11 ± 0.1911.58 ± 0.2611.67 ± 0.358.98 ± 0.2811.75 ± 0.6471.26 ± 3.8873.99 ± 3.5954.91 ± 5.563.56 ± 0.1784.54 ± 4.31436.29 ± 20.24561.96 ± 19.83
CC6.02 ± 0.067.15 ± 0.1111.85 ± 0.1911.76 ± 0.279.76 ± 0.3812.55 ± 0.7373.30 ± 3.4770.05 ± 3.5750.38 ± 2.984.33 ± 0.4296.17 ± 4.05373.56 ± 17.36507.65 ± 19.37
GG5.74 ± 0.116.25 ± 0.2410.72 ± 0.4610.43 ± 0.647.82 ± 0.5212.68 ± 1.0080.64 ± 7.3185.24 ± 7.5662.44 ± 3.162.81 ± 0.1983.97 ± 6.40470.32 ± 37.73743.78 ± 136.80
P value0.009 0.01 0.049 0.0680.032 0.6630.5790.015 0.019 0.041 0.1040.015 0.002
rs17029007
GG6.01 ± 0.066.77 ± 0.1211.14 ± 0.1811.12 ± 0.249.30 ± 0.2512.18 ± 0.5071.74 ± 2.7578.71 ± 2.7457.73 ± 2.403.76 ± 0.1989.10 ± 3.15402.92 ± 13.76557.25 ± 24.78
GA6.00 ± 0.116.76 ± 0.2411.23 ± 0.3311.16 ± 0.488.98 ± 0.4912.35 ± 1.0975.56 ± 5.3276.13 ± 5.3952.52 ± 4.264.05 ± 0.6590.98 ± 5.74437.31 ± 30.27563.96 ± 31.32
AA6.26 ± 0.506.01 ± 0.1610.68 ± 0.629.78 ± 1.216.35 ± 0.7910.79 ± 1.81111.10 ± 30.9779.93 ± 13.8149.28 ± 10.872.87 ± 0.4789.40 ± 17.08514.60 ± 108.50642.35 ± 83.52
P value0.8370.6840.9030.7410.2310.920.1380.9040.5320.7250.960.3190.873
rs3856806
CC5.96 ± 0.066.57 ± 0.1110.92 ± 0.1810.78 ± 0.258.93 ± 0.2611.87 ± 0.4175.61 ± 3.1477.37 ± 3.0756.12 ± 2.583.51 ± 0.1491.40 ± 3.05432.97 ± 16.46582.14 ± 29.37
TC6.12 ± 0.107.11 ± 0.2211.58 ± 0.2911.68 ± 0.399.69 ± 0.4012.75 ± 1.0869.35 ± 4.2178.76 ± 4.1656.36 ± 3.544.33 ± 0.5386.40 ± 5.67377.68 ± 20.08518.92 ± 22.77
TT6.08 ± 0.217.88 ± 0.4711.33 ± 0.8211.60 ± 1.249.27 ± 1.4212.59 ± 2.0162.15 ± 8.8177.54 ± 11.0758.24 ± 12.154.36 ± 1.2282.71 ± 11.35358.63 ± 57.56506.31 ± 62.29
P value0.3260.047 0.1270.1210.2570.650.3380.9640.9810.1550.6190.0850.302

∗ P < 0.05. DI30 (early-phase disposition index of insulin secretion) = [InsAUC30/GluAUC30] × ISIM, DI120 (total-phase disposition of insulin secretion) = [InsAUC120/GluAUC120] × ISIM.

Table 11

Association of genotype with lipid profiles in PPARγ.

GenotypeTC (mmol/l)TG (mmol/l)HDL-C (mmol/l)LDL-C (mmol/l)TG/HDL-C
rs2920503
CC5.51 ± 0.072.25 ± 0.461.32 ± 0.032.87 ± 0.051.81 ± 0.35
CT5.36 ± 0.081.72 ± 0.101.28 ± 0.022.83 ± 0.051.44 ± 0.08
TT5.26 ± 0.111.78 ± 0.161.33 ± 0.082.66 ± 0.081.56 ± 0.17
P value0.1540.530.4570.1460.594
rs73813168
AA5.37 ± 0.051.78 ± 0.081.29 ± 0.022.80 ± 0.031.49 ± 0.06
GA5.44 ± 0.112.67 ± 0.941.37 ± 0.052.97 ± 0.082.11 ± 0.72
GG5.26 ± 0.591.36 ± 0.231.27 ± 0.132.73 ± 0.441.06 ± 0.12
P value0.0540.2450.1640.0570.313
rs79310821
GA5.49 ± 0.061.70 ± 0.081.30 ± 0.022.88 ± 0.041.41 ± 0.07
GG5.42 ± 0.081.81 ± 0.111.33 ± 0.032.83 ± 0.051.49 ± 0.09
AA5.20 ± 0.121.88 ± 0.241.25 ± 0.032.67 ± 0.091.61 ± 0.18
P value0.1470.6290.2830.1090.484
rs73021485
GT5.49 ± 0.061.70 ± 0.081.29 ± 0.022.88 ± 0.041.41 ± 0.07
GG5.41 ± 0.082.30 ± 0.521.33 ± 0.032.83 ± 0.051.87 ± 0.40
TT5.19 ± 0.121.85 ± 0.231.26 ± 0.032.67 ± 0.091.58 ± 0.18
P value0.1440.4520.3130.1090.464
rs2920502
GC5.48 ± 0.072.39 ± 0.081.31 ± 0.022.90 ± 0.051.82 ± 0.08
CC5.72 ± 0.204.35 ± 2.431.28 ± 0.022.98 ± 0.153.40 ± 0.07
GG5.32 ± 0.061.73 ± 0.111.42 ± 0.122.75 ± 0.041.22 ± 0.26
P value0.034 0.004∗∗ 0.070.031 0.006∗∗
rs17029007
GG5.37 ± 0.051.78 ± 0.071.29 ± 0.022.80 ± 0.031.49 ± 0.06
GA5.58 ± 0.102.70 ± 0.981.38 ± 0.052.91 ± 0.072.13 ± 0.75
AA5.55 ± 0.451.46 ± 0.231.29 ± 0.092.94 ± 0.311.15 ± 0.17
P value0.1650.2330.0710.3340.301
rs3856806
CC5.42 ± 0.062.04 ± 0.351.30 ± 0.022.84 ± 0.041.71 ± 0.27
TC5.44 ± 0.081.91 ± 0.161.32 ± 0.022.81 ± 0.051.52 ± 0.11
TT5.39 ± 0.271.48 ± 0.171.25 ± 0.062.88 ± 0.161.27 ± 0.16
P value0.9710.8820.7410.8460.811

∗ P < 0.05 and ∗∗ P < 0.01.

3.6. Association of Genotype with Inflammation

There was no significant difference in TNF-α among genotypes in UCP2. The serum IL-6 was higher in subjects with TT genotype of rs660339 than in GG/GA genotype, and IL-6 was higher in subjects with TT genotype of rs649446 than in CC/TC genotype (Table 12). There was no significant difference in inflammation indicators among genotypes in PPARγ (Table 13).
Table 12

Association of genotype with inflammation in UCP2.

GenotypeTNF-α (fmol/ml)IL-6 (pg/ml)
rs660339
GG23.44 ± 0.861.62 ± 0.08
AA22.25 ± 0.951.42 ± 0.10
GA22.40 ± 0.571.70 ± 0.05
P value0.5270.034
rs659366
CC23.31 ± 0.871.64 ± 0.08
TT22.10 ± 0.941.46 ± 0.10
TC22.55 ± 0.571.67 ± 0.05
P value0.5980.111
rs649446
CC23.28 ± 0.661.68 ± 0.06
TT20.97 ± 1.481.95 ± 0.16
TC22.37 ± 0.591.65 ± 0.06
P value0.2570.001∗∗
rs7109266
GG23.22 ± 0.661.68 ± 0.06
AA20.78 ± 1.501.52 ± 0.17
GA22.45 ± 0.601.65 ± 0.06
P value0.2570.063
rs591758
GG23.37 ± 0.861.64 ± 0.08
CC21.81 ± 0.891.46 ± 0.10
CG22.65 ± 0.591.68 ± 0.06
P value0.4390.111
rs586773
AA23.37 ± 0.861.64 ± 0.08
TT21.81 ± 0.891.46 ± 0.10
AT22.61 ± 0.591.67 ± 0.06
P value0.4370.12
rs34408426
AA23.37 ± 0.861.64 ± 0.08
GG21.81 ± 0.891.46 ± 0.10
AG22.56 ± 0.591.67 ± 0.06
P value0.4340.124
rs3019463
CC23.34 ± 0.861.64 ± 0.08
TT22.15 ± 0.891.47 ± 0.10
TC22.58 ± 0.601.66 ± 0.06
P value0.6060.17

∗ P < 0.05 and ∗∗ P < 0.01. TNF-α: tumor necrosis factor-α; IL-6: interleukine-6. IL-6 has been nature logarithm transformed.

Table 13

Association of genotype with inflammation in PPARγ.

GenotypeTNF-α (fmol/ml)IL-6 (pg/ml)
rs2920503
CC22.60 ± 0.6457.77 ± 0.96
CT22.42 ± 0.6260.82 ± 1.02
TT23.51 ± 1.5160.76 ± 2.40
P value0.7780.081
rs73813168
AA23.11 ± 0.491.63 ± 0.05
GA21.68 ± 0.881.56 ± 0.09
GG16.44 ± 4.271.76 ± 0.27
P value0.1640.742
rs79310821
GA23.02 ± 0.631.64 ± 0.06
GG22.34 ± 0.661.59 ± 0.07
AA22.29 ± 1.251.64 ± 0.11
P value0.7230.844
rs73021485
GT22.99 ± 0.631.64 ± 0.06
GG22.32 ± 0.671.59 ± 0.07
TT22.28 ± 1.221.60 ± 0.11
P value0.7350.81
rs2920502
GC22.78 ± 0.671.57 ± 0.06
CC22.70 ± 0.611.68 ± 0.06
GG21.41 ± 1.411.45 ± 0.14
P value0.6650.231
rs17029007
GG23.03 ± 0.491.63 ± 0.05
GA21.70 ± 0.871.55 ± 0.10
AA17.39 ± 3.821.80 ± 0.22
P value0.1370.634
rs3856806
CC22.62 ± 0.521.58 ± 0.05
TC22.63 ± 0.791.69 ± 0.07
TT21.87 ± 2.181.58 ± 0.24
P value0.9490.419

TNF-α: tumor necrosis factor-α; IL-6: interleukine-6. IL-6 has been nature logarithm transformed.

4. Discussion

The effects of UCP2 on proton leakage and the decline in ATP synthesis in β-cells show that this protein is a negative regulator of insulin secretion. Increased expression of UCP2 results in decreased ATP synthesis, which inhibits ATP-sensitive potassium (K-ATP) channels, leading to the decline of glucose-stimulated insulin secretion [1]. Our previous study showed that UCP2 deficiency led to the amelioration of lipid metabolism and improved blood glucose by simultaneously promoting insulin sensitivity and β-cell function [1, 2]. Obesity and T2DM closely associated with SNPs in UCP2, including rs660339 (Ala55Val), rs659366 (-866G/A), and rs591758 [7]. In this study based on Chinese Han population in Beijing district, we selected 8 SNPs in the functional region of UCP2, and the results indicated that the alleles and genotypes were not significantly different between prediabetes/diabetes and control. Further genotype and clinical features analysis showed that subjects with TT genotype of rs649446 or subjects with AA genotype of rs7109266 in UCP2 had higher HOMA-IR and HOMA-β, subjects with AA genotype of rs7109266 also had higher waist-to-hip ratio, which suggested that subjects with TT genotype of rs649446 or subjects with AA genotype of rs7109266 were more susceptible to develop insulin resistance. Previous study showed that human islets with GA genotype of UCP2-866 polymorphism have decreased glucose-stimulated insulin secretion compared to GG genotype islets [3]. However, the pathway between UCP2 polymorphism and HOMA index has not been elaborated clearly. The study was the first one to investigate the association of the above SNPs with insulin resistance in Chinese Han population in Beijing district, it probably could give certain suggestion to prevent insulin resistance in early stage by classifying the genotype of the above SNPs inUCP2. The inflammation pathway is involved in the pathophysiology of diabetes and obesity. The study indicated that subjects with GG/GA genotype of rs660339 in UCP2 had higher serum IL-6 levels than those with AA genotype, and subjects with TT genotype of rs649446 had higher IL-6 than those with CC/TC genotypes. IL-6 is a central player in the regulation of inflammation, leading to insulin resistance. Its quantitative release from adipose tissue results in a subclinical and systemic elevation of IL-6 plasma levels with increasing body fat content, which may be implicated in the proinflammatory state leading to insulin resistance [20]. On the other hand, IL-6 produced in the working muscle during physical activity could act as an energy sensor by activating AMP-activated kinase and enhancing glucose disposal, lipolysis, and fat oxidation. In addition, both impaired IL-6 secretion and action are risk factors for weight gain [21]. Previous study suggested that people with GG/GA genotype of rs660339 in UCP2 had an increased risk for diabetes, obesity, and metabolic syndrome; the elevated IL-6 in the subjects with GG/GA genotype suggested that these kinds of SNP was closely related to inflammation, which play an important role in the mechanism of diabetes and its complications. PPARγ, which is a central nuclear receptor, is involved in fatty acid and glucose metabolism and is closely associated with insulin sensitivity. In clinical work, PPARγ agonist glitazone—the derivative of thiazolidinediones—could improve insulin resistance by indirectly increasing insulin-stimulated glucose uptake in adipocytes, skeletal muscle cells, and hepatocytes and inhibiting proinflammation cytokines produced from mononuclear macrophages [22]. Our previous study showed that UCP2 deficiency could improve insulin sensitivity and β-cell function by PPAR signaling pathway. PPARγ regulates UCP2 in the condition of a high-fat diet [14]. Among the selected 7 SNPs of PPARγ in our study, two loci (rs2920502 and rs3856806) were reported to be related to glucolipid metabolism [22]. This study suggested that subjects with GG genotype of rs2920502 in PPARγ, who had better early- and total-stage insulin secretion function and better serum lipid condition, had a decreased risk for diabetes in Chinese Han population of Beijing district. Prakash et al. reported that in Nanjing and Southwest district of China, GG genotype of rs2920502 was a protective factor for metabolism syndrome, GG carriers had elevated serum adiponectin, which is a kind of anti-inflammatory and antiatherosclerosis cytokine that could prevent metabolism syndrome; therefore, GG genotype of rs2920502 probably improved glucolipid metabolism by regulating the secretion of adiponectin [22]. In our study, subjects with TT genotype of rs3856806 in PPARγ had an increased risk for diabetes, and the result was in accordance with a previous study based on Chinese Han population; however, studies based on Indians and Singaporeans showed that TT genotype of rs3856806 could decrease the risk for diabetes. Evidence also showed that rs3856806 in PPARγ had a close relationship with metabolic syndrome, subjects with TT genotype had higher BMI in males, and those with TT/TC genotypes had higher systolic blood pressure, HOMA-IR, and larger body fat percentage, which were all related to insulin sensitivity. For that reason, rs3856806 was considered as the vital regulation loci of insulin sensitivity. In our study based on Chinese Han population in Beijing district, the sample size was limited; we found that the alleles and genotypes of rs2920503, rs73813168, rs79310821, rs73021485, and rs1702907 in PPARγ had no significant difference between prediabetes/diabetes and normal glucose tolerance, but the genotype-phenotype analysis suggested that subjects with TT genotype of rs2920503 had better insulin secretion function and blood glucose status and subjects with AA/GG genotypes of rs79310821 or with TT/GG genotypes of rs73021485 had better blood glucose status. Studies with a larger sample size are needed to confirm the association of SNPs in PPARγ with diabetes. In summary, this study investigated the association of polymorphism of UCP2 and PPARγ with glucolipid metabolism based on Chinese Han population in Beijing district; it probably could give certain suggestions to prevent insulin resistance in the early stage by classifying the genotype of rs649446 and rs7109266 in UCP2. The polymorphism of PPARγ closely associated with glucolipid metabolism. Subjects with GG genotype of rs2920502 in PPARγ, who had better early- and total-stage insulin secretion function and better serum lipid condition, had a decreased risk for diabetes. Subjects with TT genotype of rs3856806 in PPARγ had an increased risk for diabetes.
  22 in total

1.  Polymorphisms in the PPARγ gene and their association with metabolic syndrome in Uyghurs and Kazakhs from Xinjiang, China.

Authors:  J Chen; R L Ma; H Guo; Y S Ding; J Y Zhang; J M Liu; M Kerm; M Zhang; S Z Xu; S G Li; S X Guo
Journal:  Genet Mol Res       Date:  2015-06-11

2.  Uncoupling protein-2: a novel gene linked to obesity and hyperinsulinemia.

Authors:  C Fleury; M Neverova; S Collins; S Raimbault; O Champigny; C Levi-Meyrueis; F Bouillaud; M F Seldin; R S Surwit; D Ricquier; C H Warden
Journal:  Nat Genet       Date:  1997-03       Impact factor: 38.330

3.  Association of PPAR-γ gene polymorphisms with obesity and obesity-associated phenotypes in North Indian population.

Authors:  Jai Prakash; Neena Srivastava; Shally Awasthi; C Agarwal; S Natu; Naresh Rajpal; Balraj Mittal
Journal:  Am J Hum Biol       Date:  2012-03-12       Impact factor: 1.937

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Authors:  M Hoene; C Weigert
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5.  Dual Peroxisome Proliferator-Activated Receptor-alpha/gamma Agonists : In the Treatment of Type 2 Diabetes Mellitus and the Metabolic Syndrome.

Authors:  Harrihar A Pershadsingh
Journal:  Treat Endocrinol       Date:  2006

6.  The -866A/A genotype in the promoter of the human uncoupling protein 2 gene is associated with insulin resistance and increased risk of type 2 diabetes.

Authors:  Monica D'Adamo; Lucia Perego; Marina Cardellini; Maria Adelaide Marini; Simona Frontoni; Francesco Andreozzi; Angela Sciacqua; Davide Lauro; Paolo Sbraccia; Massimo Federici; Michele Paganelli; Antonio E Pontiroli; Renato Lauro; Francesco Perticone; Franco Folli; Giorgio Sesti
Journal:  Diabetes       Date:  2004-07       Impact factor: 9.461

Review 7.  The polymorphisms of UCP2 and UCP3 genes associated with fat metabolism, obesity and diabetes.

Authors:  J-J Jia; X Zhang; C-R Ge; M Jois
Journal:  Obes Rev       Date:  2009-04-21       Impact factor: 9.213

8.  Investigation of variants in UCP2 in Chinese type 2 diabetes and diabetic retinopathy.

Authors:  Yinchen Shen; Zujia Wen; Ning Wang; Zhi Zheng; Kun Liu; Xin Xia; Qing Gu; Yongyong Shi; Xun Xu
Journal:  PLoS One       Date:  2014-11-14       Impact factor: 3.240

9.  Changes in insulin sensitivity and insulin release in relation to glycemia and glucose tolerance in 6,414 Finnish men.

Authors:  Alena Stancáková; Martin Javorský; Teemu Kuulasmaa; Steven M Haffner; Johanna Kuusisto; Markku Laakso
Journal:  Diabetes       Date:  2009-02-17       Impact factor: 9.461

10.  Expression profiling analysis: Uncoupling protein 2 deficiency improves hepatic glucose, lipid profiles and insulin sensitivity in high-fat diet-fed mice by modulating expression of genes in peroxisome proliferator-activated receptor signaling pathway.

Authors:  Mei-Cen Zhou; Ping Yu; Qi Sun; Yu-Xiu Li
Journal:  J Diabetes Investig       Date:  2015-09-02       Impact factor: 4.232
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1.  PPARɣ2, aldose reductase, and TCF7L2 gene polymorphisms: relation to diabetes mellitus.

Authors:  Hadeel Ahmed Shawki; Ekbal M Abo-Hashem; Magdy M Youssef; Maha Shahin; Rasha Elzehery
Journal:  J Diabetes Metab Disord       Date:  2022-01-03

Review 2.  Uncoupling Proteins as Therapeutic Targets for Neurodegenerative Diseases.

Authors:  Colin J Barnstable; Mingliang Zhang; Joyce Tombran-Tink
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