Abstract
Aims/hypothesis
Common DNA variants of the transcription factor 7-like 2 gene (TCF7L2) are associated with type 2 diabetes. Familial combined hyperlipidaemia (FCHL) is characterised by hypertriacylglycerolaemia, hypercholesterolaemia, or both. Additionally, disturbances in glucose metabolism are commonly seen in FCHL. Therefore, we hypothesised that TCF7L2 may contribute to the genetic susceptibility for this common dyslipidaemia.
Methods
We investigated the effect of the TCF7L2 variants, rs7903146 and rs12255372, on FCHL and its component traits triacylglycerol (TG), total cholesterol (TC) and apolipoprotein B (ApoB) in 759 individuals from 55 Mexican families. As a replication sample, 719 individuals from 60 Finnish FCHL families were analysed. We also used quantitative RT-PCR to evaluate the transcript levels of TCF7L2 in 47 subcutaneous fat biopsies from unrelated Mexican FCHL and normolipidaemic participants.
Results
Significant evidence for association was observed for high TG for the T alleles of rs7903146 and rs12255372 (p = 0.005 and p = 0.01) in Mexican FCHL families. No evidence for association was observed for FCHL, TC, ApoB or glucose in Mexicans. When testing rs7903146 and rs12255372 for replication in Finnish FCHL families, these single nucleotide polymorphisms were associated with TG (p = 0.01 and p = 0.007). Furthermore, we observed statistically significant decreases in the mRNA levels (p = 0.0002) of TCF7L2 in FCHL- and TG-affected individuals. TCF7L2 expression was not altered by the SNP genotypes.
Conclusions/interpretation
These data show that rs7903146 and rs12255372 are significantly associated with high TG in FCHL families from two different populations. In addition, significantly decreased expression of TCF7L2 was observed in TG- and FCHL-affected individuals.
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Introduction
Recently intronic variants in the transcription factor 7-like 2 gene (TCF7L2 [MIM602228]) were strongly associated with type 2 diabetes in samples from Iceland, the USA and Denmark [1]. Since the original report, these findings have been replicated in numerous type 2 diabetes studies [2–7]. The evidence of association with type 2 diabetes seems to be strongest in Europids [1–4]. TCF7L2 is a high mobility group box-containing transcription factor that has a role in the WNT signalling pathway. WNT proteins are powerful regulators of cell proliferation and differentiation, and their signalling pathway involves proteins that directly participate in gene transcription and cell adhesion [8]. Alterations of the WNT signalling pathway have been found in human diseases, including cancer and skeletal, neuronal and cardiovascular disorders [9, 10].
Familial combined hyperlipidaemia (FCHL) is a complex genetic disorder, associated with coronary artery disease. Affected individuals with FCHL may present with hypertriacylglycerolaemia, hypercholesterolaemia or mixed hyperlipidaemia [11]. FCHL profiles have also been associated with clinical features observed in type 2 diabetes, such as hypertriacylglycerolaemia, hyperinsulinaemia and impaired glucose tolerance [12, 13]. Considering this phenotypic overlap, we hypothesised that the TCF7L2 variants previously associated with type 2 diabetes might also contribute to the FCHL phenotype. In this study, we investigated the role of the rs7903146 and rs12255372 variants, previously associated with type 2 diabetes [1], in FCHL and its component traits total cholesterol (TC), triacylglycerol (TG) and apolipoprotein B (ApoB) in multigenerational Mexican FCHL families. In addition, we tested fasting glucose for association in these Mexican FCHL families. The observed results for TG were tested for replication in Finnish FCHL families. We also examined TCF7L2 transcript levels in fat biopsies of 47 Mexican unrelated FCHL cases and control individuals for differential gene expression.
Methods
Mexican FCHL families
We investigated 55 extended Mexican FCHL families with a history of premature CHD, comprising 759 family members. All participants studied were Mexican Mestizos. These families were recruited in the Instituto Nacional de Ciencias Médicas y Nutrición Salvador Zubirán (INCMNSZ) in Mexico City, using the inclusion and exclusion criteria described previously [14, 15]. The Mexican age-specific and sex-specific (age/sex-specific) 90th percentiles for TC and TG [16] were used to classify the FCHL affection status. A total of 58 individuals were classified as type 2 diabetes-affected using the American Diabetes Association criteria [17]. Each participant provided written informed consent. The study design was approved by the ethics committees of the INCMNSZ and UCLA.
Finnish FCHL families
We genotyped 719 Finnish individuals from 60 FCHL families. The families were recruited in the Helsinki and Turku University Central Hospitals, as described previously [18–20]. All study participants gave their informed consent before participating in the study and were collected in agreement with the Helsinki Declaration. The inclusion criteria for FCHL probands were: TC and/or TG levels ≥age/sex-specific 90th Finnish population percentile. To ensure that families were affected with the strict original FCHL criteria of Goldstein et al. [11], we also used premature CHD as an inclusion criterion for the probands, in accord with our earlier studies [19, 20]. CHD was confirmed either by angiography (>50% stenosis in one or more coronary arteries) or probands having suffered from myocardial infarction. In these families 40 individuals were classified as type 2 diabetes-affected. The study design was approved by the ethics committees of the participating centres.
The phenotypic characteristics of the FCHL-affected and unaffected individuals in the Mexican and Finnish FCHL families are presented in Table 1.
Biochemical analyses of Mexican and Finnish families
In the Mexican FCHL families, all the measurements were performed by the Endocrinology and Metabolism Department of INCMNSZ with commercially available standardised methods, as previously described [14]. In the Finnish families, serum lipid and glucose parameters were measured as described earlier [18–20]. Patients who used lipid-lowering drugs were studied after their lipid-lowering treatment was withdrawn for 4 weeks, because based on the data of statin elimination rate and LDL kinetics, 1 month has been clinically recognised as a washout period for statins.
Single nucleotide polymorphism genotyping
We genotyped 1,478 individuals from the 55 extended Mexican FCHL families and 60 Finnish FCHL families for the single nucleotide polymorphisms (SNPs) rs7903146 and rs12255372. Primers were designed for PCR, using the Primer3 program, and for detection, using the SNP Primer Design software (Pyrosequencing). The Genotyping was performed with the Pyrosequencing technique on the automated PSQ HS96A platform (Biotage, Uppsala, Sweden). The genotype call rate was 95% for both SNPs. For quality control, we replicated 3.5% of the genotyped samples. The percentage agreement between samples was >99%. The genotype error rate was 0.6% for both SNPs. The genotypes of the individuals with Mendelian errors were called as 0 in the analysis. Both SNPs were tested for a possible violation of Hardy–Weinberg equilibrium (HWE) in non-related groups of family members (founders, probands and spouses). Both SNPs were in HWE in all of these groups.
Statistical analysis
Association analyses of qualitative and quantitative traits in Mexicans were performed using the quantitative transmission disequilibrium test (QTDT) [21] implemented in the genetic analysis package SOLAR [22–24]. The QTDT approach is robust to population stratification [23] and has been recognised as a powerful method that utilises data from all available relatives. In more homogeneous populations without population stratification such as the Finns, the quantitative trait linkage disequilibrium (QTLD) option is more powerful than the QTDT [23], because it utilises additional information by using also the founder genotypes. Stratification was tested as part of the QTLD procedure, which was further used in the analyses of the Finnish families. To evaluate the independent effect of the SNPs on TG, the analyses were performed using fasting glucose measurements as a covariate. For fasting glucose, the quantitative association analysis was performed by including age and sex as covariates. The glucose values were log10 transformed to approach a normal distribution. We also performed the association analysis for lipid traits by excluding the individuals with type 2 diabetes. Odds ratios and marginal effects, both adjusted for relatedness, were calculated for the qualitative lipid traits from the logistic regression coefficient obtained from SOLAR. For fasting glucose, analysed as a continuous trait, the effect size is provided as a β-coefficient obtained from SOLAR. Allele frequencies were estimated from all individuals using the DOWNFREQ program [25]. The PedCheck program was used to assess the genotype data for pedigree inconsistencies [26].
Real-time quantitative RT-PCR (qRT-PCR)
Total RNA from 47 fat biopsies from umbilical subcutaneous adipose tissue under local anaesthesia from 31 Mexican unrelated cases (nine female, 22 male, aged 37.3 ± 11.7 years, BMI 26.4 ± 2.3 kg/m2, TG 4.5 ± 2.7 mmol/l, TC 7.0 ± 1.6 mmol/l) and 16 unrelated control individuals (ten female, six male, aged 34.4 ± 12.5 years, BMI 25.1 ± 3.5 kg/m2, TG 0.98 ± 0.4 mmol/l, TC 4.3 ± 0.6 mmol/l) was isolated. Of these individuals, seven had type 2 diabetes. The RNA extraction has been described in detail previously [27, 28]. The integrity of the RNA was assessed using an Agilent 2100 Bioanalyzer (Agilent, Foster City, CA, USA). Synthesis of cDNA from 1 μg of Mexican FCHL fat biopsy total RNA was performed using the established methods for the SuperScript III First-Strand Synthesis System for RT-PCR (Qiagen, Valencia, CA, USA; P/N: 18080-051).
The real-time quantitative RT-PCR (qRT-PCR) was performed according to established methods from Qiagen as outlined in the manual for the QuantiTect SYBR Green PCR Handbook. The qRT-PCR was performed in 10 μl reactions using QuantiTect SYBR Green PCR Kit (Quiagen; P/N: 204125) on an ABI PRISM 7900 HT Sequence Detection System (Applied Biosystems, Foster City, CA, USA). Primer pairs were designed so that one primer was on an exon–exon junction. Primer sequences are listed in Electronic supplementary material Table 1. Two housekeeping genes were used to normalise the expression: B2M and HPRT. A Student’s t test was applied to analyse for differential expression based on FCHL, TG, TC, ApoB, glucose and the SNP genotypes. The individuals defined as affected for FCHL were also affected for the TG trait. The real-time qRT-PCR experiments were performed twice, independently, using duplicates for each sample.
Results
We tested whether the TCF7L2 variants, rs7903146 and rs12255372, previously associated with type 2 diabetes [1], also contribute to the FCHL component traits and glucose levels in Mexicans with FCHL. In addition we analysed an independent study sample of Finnish FCHL families for replication. We restricted the association analyses with the lipid traits to qualitative analyses using the Mexican and Finnish age/sex-specific 90th population percentiles as cutoffs, because these FCHL families were ascertained through a proband, and an additional first-degree relative with high TC or TG, resulting in reduced variance of the TC and TG levels. Therefore, in these families, the variance of the quantitative lipid traits may be limited for effective quantitative analysis.
The allele frequencies of the T allele in the Mexicans were 0.15 and 0.16 for the SNPs rs7903146 and rs12255372, respectively, and the linkage disequilibrium between these SNPs was D′ = 0.86, r 2 = 0.7 in 134 unrelated spouses. We utilised the QTDT analysis in the Mexican families to test for association, and results with a p value ≤0.05 were considered significant, because TCF7L2 is a candidate gene and the lipid traits represent correlated traits. In these analyses, we corrected for glucose levels by including fasting glucose values as a covariate in the analysis in order to separate the known effects of TCF7L2 on diabetes-related traits from its potential effects on lipids in FCHL. We observed significant evidence for association for high TG levels for the T alleles of both rs7903146 and rs12255372 SNPs (p = 0.005 and p = 0.01, respectively) in the Mexican FCHL families. The association results remained significant when we excluded the 58 Mexican participants with type 2 diabetes from the analysis (p = 0.007 for rs7903146; and p = 0.01 for rs12255372; Table 2). The means by genotype of the analysed traits for SNPs rs7903146 and rs12255372 in the Mexicans are presented in Table 3. We also estimated the effect sizes for all tested traits (Table 4). For TG, the observed odds ratios were 1.83 (p = 0.005) and 1.67 (p = 0.01) for rs7903146 and rs12255372, respectively. Using the odds ratios we calculated that each copy of the T allele increased the probability of having high TG by 8 and 7% for SNPs rs7903146 and rs12255372, respectively, in these Mexican FCHL families. No consistent evidence of association was observed between the FCHL, TC or ApoB traits and either of the SNPs, and the p values remained non-significant (Table 4). Neither was the quantitative glucose trait associated with the TCF7L2 variants (Table 4). The latter result may, however, reflect the small number of type 2 diabetes-affected participants (n = 58) in these Mexican FCHL families.
To replicate this association with TG, we investigated the two SNPs for association with high TG in 60 extended Finnish FCHL families. In the Finns, the allele frequencies of the T allele were 0.19 and 0.17 for the SNPs rs7903146 and rs12255372, respectively, and the linkage disequilibrium between these SNPs was D′ = 0.89, r 2 = 0.7 in 144 unrelated spouses. Again utilising a qualitative approach where the TG trait was dichotomised based on the 90th age/sex-specific Finnish population percentiles [16] and fasting glucose included as a covariate, we observed significant associations with the T alleles of rs7903146 and rs12255372 for high TG levels (p = 0.01 and p = 0.007) using the QTLD test. As in the Mexicans, we also observed significant evidence for association when we excluded the 40 Finnish participants with type 2 diabetes from the analyses (p = 0.01 for rs7903146; and p = 0.008 for rs12255372; Table 2). The means by genotype of the TG trait for SNPs rs7903146 and rs12255372 in the Finns are presented in Table 3.
In the Finnish families the odds ratios for high TG were 1.51 (p = 0.007) and 1.45 (p = 0.01) for rs12255372 and rs7903146 (Table 4). Using the odds ratios we calculated that each copy of the T allele increased the probability of having high TG by 7 and 8% for SNPs rs7903146 and rs12255372, respectively, in these Finnish FCHL families.
To investigate transcript levels of TCF7L2 for differential expression in FCHL, we performed real-time qRT-PCR analysis in 47 subcutaneous fat biopsies from Mexican FCHL cases and normolipidaemic control individuals. The clinical characteristics of these participants are shown in the Methods. We observed statistically highly significant decreases in the mRNA levels of TCF7L2 in the FCHL- and TG-affected participants (p = 0.0002; Fig. 1a,b). We also observed significant associations in the TC- (p = 0.006) and ApoB- (p = 0.003) affected participants (Fig. 1c,d), reflecting the fact that many of the FCHL cases also exhibit high TC and ApoB levels. TCF7L2 expression was not altered by the SNP genotypes. No differences in the TCF7L2 expression were observed between cases and control individuals for glucose levels or type 2 diabetes. The latter may be due to the small number of type 2 diabetes participants (n = 7) among the Mexican individuals who underwent fat biopsy.
Discussion
Recent studies have consistently shown that TCF7L2 is a strong susceptibility gene for type 2 diabetes [2–7]. Although several studies support the association between type 2 diabetes and TCF7L2 variants [1–7], the underlying pathophysiological mechanisms of the associated TC7L2 variants are not known. In the present study, we investigated whether the TCF7L2 variants, rs7903146 and rs12255372, previously strongly associated with type 2 diabetes, also contribute to the FCHL component traits and glucose levels in 55 Mexican FCHL families. Furthermore, the observed results were analysed for replication in 60 Finnish FCHL families. Our data indicate that rs7903146 and rs12255372 show significant evidence for association with high TG for the same risk allele in both the Mexican and Finnish FCHL study samples.
In the Mexican study sample, the allele frequencies of the T alleles and the linkage disequilibrium between the SNPs rs7903146 and rs12255372 were lower than the corresponding values reported in European and African-American controls for type 2 diabetes [1–5]. The allele frequencies for the T alleles of rs7903146 and rs12255372 observed in this study were, however, in a good agreement with a previous TCF7L2 study for type 2 diabetes in Mexicans [29]. Regarding the Finns, the allele frequencies of this study correspond well with the allele frequencies reported previously in Finns for type 2 diabetes [30]. The data presented in this study provide strong evidence of an association between TCF7L2 gene variants and high TG levels in FCHL families from two different populations. Although we observed differences in the allele frequencies for these variants between Mexican and Finnish populations, we detected significant evidence for association with high TG for the same SNPs. Importantly, the results were further supported by gene expression analysis of 47 fat biopsies from Mexican FCHL-affected individuals and controls.
We observed significantly lower gene expression of TCF7L2 in unrelated TG- and FCHL-affected individuals than in unrelated normolipidaemic controls. In agreement with previous studies performed in subcutaneous fat biopsies from type 2 diabetes cases and controls [31–33], TCF7L2 expression was not altered by the rs7903146 and rs12255372 genotypes. It is worth noting that in these previous studies the TCF7L2 expression was, however, lower in type 2 diabetes-affected individuals. The function of TCF7L2 in adipose tissue is not known. We hypothesise that TCF7L2 and its as yet unknown variants may be involved in adipogenesis or adipose function by altering transcriptional regulation of genes leading to deposition TG.
We have previously reported that the upstream transcription factor 1 (USF1) and the hepatic nuclear factor-4 alpha (HNF4A) transcription factor are implicated in FCHL [14, 15, 18]. In the present study, we demonstrate for the first time that a third transcription factor, TCF7L2, previously associated with type 2 diabetes is also associated with a primary FCHL component trait, TG, in Mexican and Finnish FCHL families. As all of these transcription factors regulate a cascade of downstream genes, it is tempting to hypothesise that relatively minor changes in transregulation of multiple target genes of USF1, HNF4A and TCF7L2 contribute to the complex FCHL phenotype. Further studies to explore the role of TCF7L2 in FCHL could include resequencing of TCF7L2 and regional linkage disequilibrium analysis in both Mexican and Finnish FCHL participants. This should help identify additional variants to be tested for differences in gene expression and functional significance in FCHL.
To the best of our knowledge, these data are the first to demonstrate that the T alleles in rs7903146 and rs12255372 are significantly associated with high TG levels in Mexican FCHL families, and a replication of this association in an independent study sample of Finnish FCHL families. The observed significant differential expression of TCF7L2 between Mexican FCHL- and TG-affected participants and normolipidaemic control individuals provides functional evidence that TCF7L2 is indeed involved in the pathogenesis of FCHL.
Abbreviations
- ApoB:
-
apolipoprotein B
- FCHL:
-
familial combined hyperlipidaemia
- INCMNSZ:
-
Instituto Nacional de Ciencias Médicas y Nutrición Salvador Zubirán
- qRT-PCR:
-
quantitative RT-PCR
- QTDT:
-
quantitative transmission disequilibrium test
- QTLD:
-
quantitative trait linkage disequilibrium
- SNP:
-
single nucleotide polymorphism
- TC:
-
total cholesterol
- TCF7L2:
-
transcription factor 7-like 2
- TG:
-
triacylglycerol
References
Grant SF, Thorleifsson G, Reynisdottir I et al (2006) Variant of transcription factor 7-like 2 (TCF7L2) gene confers risk of type 2 diabetes. Nat Genet 38:320–323
Groves CJ, Zeggini E, Minton J et al (2006) Association analysis of 6,736 UK subjects provides replication and confirms TCF7L2 as a type 2 diabetes susceptibility gene with a substantial effect on individual risk. Diabetes 55:2640–2644
Scott LJ, Bonnycastle LL, Willer CJ et al (2006) Association of transcription factor 7-like 2 (TCF7L2) variants with type 2 diabetes in a Finnish sample. Diabetes 55:2649–2653
Humphries SE, Gable D, Cooper JA et al (2006) Common variants in the TCF7L2 gene and predisposition to type 2 diabetes in UK European whites, Indian Asians and Afro-Caribbean men and women. J Mol Med 84(12 Suppl):1–10
Cauchi S, Meyre D, Dina C et al (2006) Transcription factor TCF7L2 genetic study in the French population: expression in human beta-cells and adipose tissue and strong association with type 2 diabetes. Diabetes 55:2903–2908
Damcott CM, Pollin TI, Reinhart LJ et al (2006) Polymorphisms in the transcription factor 7-like 2 (TCF7L2) gene are associated with type 2 diabetes in the Amish: replication and evidence for a role in both insulin secretion and insulin resistance. Diabetes 55:2654–2659
Lehman DM, Hunt KJ, Leach RJ et al (2007) Haplotypes of transcription factor 7-like 2 (TCF7L2) gene and its upstream region are associated with type 2 diabetes and age of onset in Mexican Americans. Diabetes 56:389–393
Nelson WJ, Nusse R (2004) Convergence of Wnt, beta-catenin, and cadherin pathways. Science 303:1483–1487
Clevers H (2006) Wnt/beta-catenin signaling in development and disease. Cell 127:469–480
Mani A, Radhakrishnan J, Wang H et al (2007) LRP6 mutation in a family with early coronary disease and metabolic risk factors. Science 315:1278–1282
Goldstein JL, Schrott HG, Hazzard WR, Bierman EL, Motulsky AG (1973) Hyperlipidemia in coronary heart disease. II. Genetic analysis of lipid levels in 176 families and delineation of a new inherited disorder, combined hyperlipidemia. J Clin Invest 52:1544–1568
Nikkilä EA, Aro A (1973) Family study of serum lipids and lipoproteins in coronary heart-disease. Lancet 1:954–959
Vakkilainen J, Porkka KV, Nuotio I et al (1998) Glucose intolerance in familial combined hyperlipidaemia: EUFAM Study Group. Eur J Clin Invest 28:24–32
Huertas-Vazquez A, Aguilar-Salinas C, Lusis AJ et al (2005) Familial combined hyperlipidemia in Mexicans: association with upstream transcription factor 1 and linkage on chromosome 16q24.1. Arterioscler Thromb Vasc Biol 25:1985–1991
Weissglas-Volkov D, Huertas-Vazquez A, Suviolahti E et al (2006) Common hepatic nuclear factor-4alpha variants are associated with high serum lipid levels and the metabolic syndrome. Diabetes 55:1970–1977
Aguilar-Salinas CA, Olaiz G, Valles V et al (2002) High prevalence of low HDL cholesterol concentrations and mixed hyperlipidemia in a Mexican nationwide survey. J Lipid Res 42:1298–1307
American Diabetes Association (2006) Diagnosis and classification of diabetes mellitus. Diabetes Care 29:S43–S48
Pajukanta P, Nuotio I, Terwilliger JD et al (1998) Linkage of familial combined hyperlipidemia to chromosome 1q21–q23. Nat Genet 18:369–373
Soro A, Pajukanta P, Lilja HE et al (2002) Genome scans provide evidence for low-HDL-C loci on chromosomes 8q23, 16q24.1-24.2, and 20q13.11 in Finnish families. Am J Hum Genet 70:1333–1340
Pajukanta P, Terwilliger JD, Perola M et al (1999) Genomewide scan for familial combined hyperlipidemia genes in Finnish families, suggesting multiple susceptibility loci influencing triglyceride, cholesterol, and apolipoprotein B levels. Am J Hum Genet 64:1453–1463
Abecasis GR, Cardon LR, Cookson WO (2000) A general test of association for quantitative traits in nuclear families. Am J Hum Genet 66:279–292
Almasy L, Blangero J (1998) Multipoint quantitative trait linkage analysis in general pedigrees. Am J Hum Genet 62:1198–1211
Havill LM, Dyer TD, Richardson DK, Mahaney MC, Blangero J (2005) The quantitative trait linkage disequilibrium test: a more powerful alternative to the quantitative transmission disequilibrium test for use in the absence of population stratification. BMC Genet 30:1–6
Blangero J, Goring HH, Kent JW Jr et al (2005) Quantitative trait nucleotide analysis using Bayesian model selection. Hum Biol 77:541–559
Göring HH, Terwilliger JD (2000) Linkage analysis in the presence of error III: marker loci and their map as nuisance parameters. Am J Hum Genet 66:1298–1309
O’Connell JR, Weeks DE (1998) PedCheck: a program for identification of genotype incompatibilities in linkage analysis. Am J Hum Genet 63:259–266
Pajukanta P, Lilja HE, Sinsheimer JS et al (2004) Familial combined hyperlipidemia is associated with upstream transcription factor 1 (USF1). Nat Genet 36:371–376
Naukkarinen J, Gentile M, Soro-Paavonen A et al (2005) USF1 and dyslipidemias: converging evidence for a functional intronic variant. Hum Mol Genet 14:2595–2605
Parra EJ, Cameron E, Simmonds L et al (2007) Association of TCF7L2 polymorphisms with type 2 diabetes in Mexico City. Clin Genet 71:359–366
Scott LJ, Mohlke KL, Bonnycastle LL et al (2007) A genome-wide association study of type 2 diabetes in Finns detects multiple susceptibility variants. Science 5829:1341–1345
Cauchi S, Meyre D, Dina C et al (2006) Transcription factor TCF7L2 genetic study in the French population: expression in human beta-cells and adipose tissue and strong association with type 2 diabetes. Diabetes 55:2903–2908
Wang J, Kuusisto J, Vanttinen M et al (2007) Variants of transcription factor 7-like 2 (TCF7L2) gene predict conversion to type 2 diabetes in the Finnish Diabetes Prevention Study and are associated with impaired glucose regulation and impaired insulin secretion. Diabetologia 50:1192–1200
Elbein SC, Chu WS, Das SK et al (2007) Transcription factor 7-like 2 polymorphisms and type 2 diabetes, glucose homeostasis traits and gene expression in US participants of European and African descent. Diabetologia 50:1621–1630
Acknowledgements
We thank the family members for their participation in this study. L. Peltonen is thanked for sample collection. We also thank M. Lupsakko, L. Riba and S. Ramirez for laboratory technical assistance. This research was supported by US National Institutes of Health grants HL082762, HL-28481, as well as by American Heart Association grant 0430180N. A. Huertas-Vazquez was supported by American Heart Association grant 0725232Y. D. Weissglas-Volkov and C. Plaisier were supported by National Human Genome Research Institute grant T32 HG02536.
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Huertas-Vazquez, A., Plaisier, C., Weissglas-Volkov, D. et al. TCF7L2 is associated with high serum triacylglycerol and differentially expressed in adipose tissue in families with familial combined hyperlipidaemia. Diabetologia 51, 62–69 (2008). https://doi.org/10.1007/s00125-007-0850-6
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DOI: https://doi.org/10.1007/s00125-007-0850-6