Identification of Quantitative Trait Loci for Glucose Homeostasis

Rich, Stephen S.; Bowden, Donald W.; Haffner, Steven M.; Norris, Jill M.; Saad, Mohammed F.; Mitchell, Braxton D.; Rotter, Jerome I.; Langefeld, Carl D.; Wagenknecht, Lynne E.; Bergman, Richard N.

doi:10.2337/diabetes.53.7.1866

Cited by 51 publications

(44 citation statements)

References 45 publications

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“…Each pedigree was examined for consistency of stated family structure and is described in detail elsewhere. 23 Maximum likelihood estimates of allele frequencies were computed using the largest set of unrelated individuals and tested for departures from Hardy-Weinberg equilibrium proportions. Each of the SNPs evaluated in this work were examined for Mendelian inconsistencies in their genotypes using PEDCHECK.…”

Section: Positional Candidate Genesmentioning

confidence: 99%

Genetic mapping of a 17q chromosomal region linked to obesity phenotypes in the IRAS family study

et al. 2006

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Objective: Obesity is widely accepted to be influenced by both environmental and genetic factors. Several recent studies have used the positional cloning approach in an attempt to discover genes contributing to obesity. In the IRAS Family Study a genomewide scan was performed on 1425 individuals of Hispanic descent (90 extended pedigree families) to identify regions of the genome linked to obesity phenotypes. Methods: Nonparametric QTL linkage analysis was performed using a variance components approach. The genome scan was performed in two phases: an initial genome scan in 45 families and a replication scan in 45 families. Fine mapping and candidate gene analyses were also performed. General estimating equations (GEE1) and quantitative pedigree disequilibrium tests (QPDT) were used for association analysis of single SNP and haplotype data. Results: Evidence for linkage to obesity traits was observed in each scan on the long arm of chromosome 17. When data from both scans was combined, a region on chromosome 17q was identified with evidence of linkage to visceral adipose tissue (VAT; LOD 3.11), waist circumference (WAIST) (LOD 2.5) and body mass index (BMI) (LOD 2.81). Nine additional microsatellite markers were identified and genotyped on all Hispanic individuals, with a mean marker density of approximately 1 marker/3 cM. Evidence of linkage remained significant with LOD 3.05 for VAT, LOD 2.44 for BMI and LOD 1.92 for WAIST. Fine mapping analyses suggest the possibility of two different obesity loci. In addition, the LOD -1 interval of the major VAT peak decreased from 83-108 to 95-111 cM. Three positional candidate genes under the peak: somatostatin receptor 2 (SSTR2), galanin receptor 2 (GALR2), and growth hormone bound protein receptor 2 (GRB2) were chosen for detailed evaluation. Multiple polymorphisms within each candidate were genotyped and tested for association with the obesity phenotypes. Little evidence of association was detected between polymorphisms and obesity traits. Conclusion: In conclusion, replication of linkage and fine mapping suggest that a region on chromosome 17q contains a gene (or genes) that contributes to the genetic etiology of obesity with the strongest evidence for linkage to VAT. Candidate genes in the region do not appear to account for the evidence of linkage. Additional studies are necessary to identify the obesity-related polymorphisms.

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Section: Positional Candidate Genesmentioning

confidence: 99%

Genetic mapping of a 17q chromosomal region linked to obesity phenotypes in the IRAS family study

et al. 2006

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“…The clustering of these metabolic traits along with their heritable features suggests that defects in one or more genes may contribute to metabolic syndrome. Linkage analysis has been widely adopted to narrow down the broad chromosomal regions harbouring susceptibility loci and to elucidate genetic features of various metabolic phenotypes, as well as to categorically define metabolic syndrome [7][8][9]. The results, however, are mostly limited to identifying: (1) regions with logarithm of the odds (LOD) scores of linkage between a chromosomal locus and a trait that are of merely marginal significance; or (2) regions with modest contributions to overall trait variation [10].…”

Section: Introductionmentioning

confidence: 99%

Bivariate genome-wide scan for metabolic phenotypes in non-diabetic Chinese individuals from the Stanford, Asia and Pacific Program of Hypertension and Insulin Resistance Family Study

Chiu¹,

Chuang

Kao³

et al. 2007

Diabetologia

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Aims/hypothesis Hypertension, obesity, impaired glucose tolerance and dyslipidaemia are metabolic abnormalities that often cluster together more often than expected by chance alone. Since these metabolic variables are highly heritable and are at least partially genetically determined, the clustering of defects in these traits implies that pleiotropic effects, where a common set of genes influences more than one trait simultaneously, are likely.Methods We conducted bivariate linkage analyses for highly correlated traits, aiming to dissect the genetic architecture affecting these traits, in 411 Chinese families participating in the Stanford Asia-Pacific Program of Hypertension and Insulin Resistance Study. Results We confirmed the pleiotropic effects of the locus at 37 cM on chromosome 20 on the following pairs: (1) fasting insulin and insulin AUC (empirical p=0.0006); (2) fasting insulin and homeostasis model assessment of

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“…Insulin resistance is an important risk factor, necessary but not sufficient to cause the disease. There may be a genetic component to resistance (36), but many nongenetic factors can contribute, including obesity (particularly truncal obesity), lack of exercise, onset of puberty, pregnancy, and a group of conditions and therapies such as polycystic ovarian syndrome, infection, and treatment for HIV. We are now aware that a reduced compensatory response of insulin secretion in the face of insulin resistance is necessary for the development of frank type 2 diabetes.…”

Section: Branch #1: Clinical Tools and The Disposition Indexmentioning

confidence: 99%