Genome-wide association for abdominal subcutaneous and visceral adipose reveals a novel locus for visceral fat in women.

paper Cited Public

Authors: Fox, Caroline S; Liu, Yongmei; White, Charles C; Feitosa, Mary; Smith, Albert V; Heard-Costa, Nancy; Lohman, Kurt; GIANT Consortium; MAGIC Consortium; GLGC Consortium; Johnson, Andrew D; Foster, Meredith C; Greenawalt, Danielle M; Griffin, Paula; Ding, Jinghong; Newman, Anne B; Tylavsky, Fran; Miljkovic, Iva; Kritchevsky, Stephen B; Launer, Lenore; Garcia, Melissa; Eiriksdottir, Gudny; Carr, J Jeffrey; Gudnason, Vilmunder; Harris, Tamara B; Cupples, L Adrienne; Borecki, Ingrid B
Year: 2012
Journal: PLoS genetics
PMID: 22589738
DOI: 10.1371/journal.pgen.1002695
PMCID: PMC3349734

Body fat distribution, particularly centralized obesity, is associated with metabolic risk above and beyond total adiposity. We performed genome-wide association of abdominal adipose depots quantified using computed tomography (CT) to uncover novel loci for body fat distribution among participants of European ancestry. Subcutaneous and visceral fat were quantified in 5,560 women and 4,997 men from 4 population-based studies. Genome-wide genotyping was performed using standard arrays and imputed to ~2.5 million Hapmap SNPs. Each study performed a genome-wide association analysis of subcutaneous adipose tissue (SAT), visceral adipose tissue (VAT), VAT adjusted for body mass index, and VAT/SAT ratio (a metric of the propensity to store fat viscerally as compared to subcutaneously) in the overall sample and in women and men separately. A weighted z-score meta-analysis was conducted. For the VAT/SAT ratio, our most significant p-value was rs11118316 at LYPLAL1 gene (p = 3.1 × 10E-09), previously identified in association with waist-hip ratio. For SAT, the most significant SNP was in the FTO gene (p = 5.9 × 10E-08). Given the known gender differences in body fat distribution, we performed sex-specific analyses. Our most significant finding was for VAT in women, rs1659258 near THNSL2 (p = 1.6 × 10-08), but not men (p = 0.75). Validation of this SNP in the GIANT consortium data demonstrated a similar sex-specific pattern, with observed significance in women (p = 0.006) but not men (p = 0.24) for BMI and waist circumference (p = 0.04 [women], p = 0.49 [men]). Finally, we interrogated our data for the 14 recently published loci for body fat distribution (measured by waist-hip ratio adjusted for BMI); associations were observed at 7 of these loci. In contrast, we observed associations at only 7/32 loci previously identified in association with BMI; the majority of overlap was observed with SAT. Genome-wide association for visceral and subcutaneous fat revealed a SNP for VAT in women. More refined phenotypes for body composition and fat distribution can detect new loci not previously uncovered in large-scale GWAS of anthropometric traits.

#	Section	Preview
20	Discussion — Potential Underlying Biology	fatty acid disposal as compared to men, but without concomitant worsened metabolic risk factor…
21	Discussion — Potential Underlying Biology	It is particularly notable that we uncovered a genome-wide significant finding with rs11118316 at…
22	Discussion — Potential Underlying Biology	There are several potential explanations that could potentially account for our observed genetic…
23	Discussion — Strengths and Limitations	Strengths of our study include directly measured visceral and subcutaneous fat using CT imaging.…
24	Discussion — Conclusions	We have uncovered new loci for body fat distribution phenotypes, highlighting that loci exist for…
25	Methods — Phenotype Definition	VAT and SAT were measured on CT following protocols established by each study as detailed in the…
26	Methods — Heritability Analyses	We created sex-and-cohort specific residuals, which were then pooled and analyzed using variance…
27	Methods — Genotyping	Genotyping was conducted as specified in the Table S1 and the Study Specific Methods. We applied…
28	Methods — Primary Association Analyses and Meta-Analysis	The primary analysis was conducted in each cohort separately using regression analysis, assuming…
29	Methods — Validation Analysis	Stage 2 validation was conducted for our novel lead SNP, rs1659258, using data from studies not part…
30	Methods — Analyses of Related Phenotypes	For each validated SNP, we obtained sex-specific association results for lipid and glycemic…
31	Methods — Interaction Testing	We performed formal tests of interaction of rs1659258 by sex (women as compared to men) and age…
32	Methods — eSNP Analysis	Using publically available datasets, we tested for the association of rs1659258 in expression SNPs…
33	Methods — eSNP Analysis	For sex-specific expression data, we queried data from patients who underwent a Roux-en-Y gastric…
34	Methods — Study-Specific Information: Framingham Heart Study	In 1948, the Framingham Heart Study began when the Original Cohort was enrolled [70]. Beginning in…
35	Methods — Study-Specific Information: Framingham Heart Study	We observed association with the first principal component estimated using Eigenstrat [72]; this…
36	Methods — Study-Specific Information: Framingham Heart Study — Volumetric adipose tissue imaging	Subjects underwent eight-slice MDCT imaging of the chest and abdomen in a supine position as…
37	Methods — Study-Specific Information: Framingham Heart Study — Abdominal adipose tissue measurements	Subcutaneous and visceral adipose tissue volumes (SAT and VAT) were assessed (Aquarius 3D…
38	Methods — Study-Specific Information: Framingham Heart Study — Imputation	As a reference panel for imputation, we used Phase II CEU HapMap individuals; we imputed genotypes…
39	Methods — Study-Specific Information: Framingham Heart Study — Statistical analysis	We performed linear mixed effects regression modeling for SAT, VAT, and the VAT/SAT ratio to account…

Name	Type
14 loci local	variant
abdominal adipose depots local	phenotype
abdominal adipose tissue	phenotype
abdominal adiposity traits local	phenotype
abdominal fat distribution local	phenotype
Abdominal subcutaneous adipose tissue local	phenotype
abdominal subcutaneous fat local	phenotype
Abdominal subcutaneous fat local	phenotype
adipose depots in abdomen local	phenotype
adipose depots in thigh local	phenotype
adipose tissue	phenotype
adipose tissue density local	phenotype
adipose traits local	phenotype
adiposity	phenotype
adiposity phenotypes local	phenotype
African American	cohort
age	phenotype
AGES local	cohort
AGES-Reykjavik local	cohort
AGES-Reykjavik study local	cohort
AGES-Reykjavik Study local	cohort
aging	phenotype
alcohol	phenotype
anthropometric measurements local	phenotype
anthropometric traits	phenotype
Aortic calcium local	phenotype
Atherosclerosis Risk in Communities Study local	cohort
black participants	cohort
blood samples	cohort
BMI	phenotype
body composition	phenotype
Body Fat Distribution Phenotypes local	phenotype
body mass index	phenotype
Body mass index (BMI)	phenotype
body percent fat local	phenotype
C2orf51 local	gene
CARDIA	cohort
Cardiometabolic outcomes local	phenotype
cardiometabolic risk local	phenotype
cardiometabolic risk factors local	phenotype
cardiovascular disease	phenotype
Cardiovascular disease (CVD) local	phenotype
Caucasians	cohort
central fat distribution local	phenotype
central obesity	phenotype
cerebellum	anatomy
CEU	cohort
CEU HapMap individuals local	cohort
CHD	gene
Computed tomography (CT) local	drug
coronary calcification	phenotype
cortex	anatomy
discovery GWAS	cohort
EIF2AK3 local	gene
European ancestry	cohort
FABP1	gene
Family Heart Study local	cohort
family members	cohort
fasting glucose	phenotype
fat distribution	phenotype
fatty acid disposal local	phenotype
fatty acids	drug
fatty liver	phenotype
fibroblast local	cohort
first principal component local	phenotype
FOXI3 local	gene
Framingham Heart Study	cohort
Free fatty acid flux local	phenotype
FTO	gene
full sample	cohort
Gastric bypass eQTL dataset local	cohort
generalized adiposity local	phenotype
genetic variants	cohort
gene transcript levels local	phenotype
GIANT	cohort
GIANT consortium	cohort
GLGC local	cohort
Global Lipids Genetics Consortium local	cohort
glucose metabolism	phenotype
glycemic phenotype	phenotype
GWAS	cohort
HapMap3	cohort
HapMap CEU LCL local	cohort
HapMap LCL from 3 populations local	cohort
HDL cholesterol	phenotype
Health ABC local	cohort
hip circumference	phenotype
incident functional limitation local	phenotype
Insulin metabolism local	phenotype
IRS1	gene
IRS1 SNP local	variant
LCL	gene
lead SNP	cohort
lead SNP in GIANT local	variant
leukocytes local	cohort
leukocytes from patients with Celiac disease local	cohort
lipid metabolism	phenotype
lipid phenotype local	phenotype
liver	anatomy
low-density lipoprotein local	phenotype
lymphoblastoid cell lines (LCL) from children with asthma local	cohort
lymphocytes local	cohort
LYPlAL1	gene
LYPLAL1 locus SNP local	variant
MACH v1.0.15/16 local	drug
MAGIC local	cohort
MAGIC consortium local	cohort
MDCT Study local	cohort
men	cohort
MESA	cohort
metabolic risk factor profiles local	phenotype
Metabolic risk factor profiles local	phenotype
NEGR1	gene
NISCH local	gene
NISCH-STAB1 locus local	variant
Non-oxidative free fatty acid disposal local	phenotype
NRXN3	gene
obesity	phenotype
offspring	cohort
osteoblasts local	cohort
participants	cohort
peripheral blood monocytes	cohort
Phase 2 HapMap SNPs local	variant
Phase II CEU HapMap individuals local	cohort
physical activity	phenotype
Pima Indian local	cohort
prefrontal cortex	anatomy
primary visual cortex	anatomy
radiation exposure local	drug
Reykjavik-cohort local	cohort
Reykjavik-study local	cohort
risk factor	phenotype
Roux-en-Y gastric bypass cohort local	cohort
Roux-en-Y gastric bypass patients local	cohort
rs11118316 local	variant
rs1659258 local	variant
rs4846567 local	variant
SAT local	drug
SAT local	phenotype
sex	phenotype
sex-and-cohort specific residuals local	phenotype
skin	drug
smoking	phenotype
smoking history	phenotype
SMYD1 local	gene
STAB1 local	gene
study cohort	cohort
subcutaneous adipose tissue local	phenotype
Subcutaneous adipose tissue local	phenotype
Subcutaneous adipose tissue (SAT) local	phenotype
subcutaneous fat local	phenotype
Subcutaneous fat local	phenotype
subjects	cohort
T cell local	cohort
Third Generation cohort local	cohort
THNSL2 local	gene
total cholesterol	phenotype
triglycerides	phenotype
unrelated individuals	cohort
Utah Health Family Tree Study local	cohort
validated SNP local	variant
VAT local	drug
VAT adjusted for BMI local	phenotype
VAT-adjusted-for-BMI local	phenotype
VAT area local	phenotype
VAT/SAT ratio local	phenotype
visceral adipose tissue	phenotype
Visceral adipose tissue (VAT) local	phenotype
Visceral adipose tissue (VAT) in women local	phenotype
Volumetric adipose tissue measurement local	phenotype
waist circumference	phenotype
waist-hip-ratio local	phenotype
waist-hip ratio adjusted for BMI	phenotype
Waist-hip-ratio (WHR) local	phenotype
waist-to-hip ratio	phenotype
weight-related health conditions local	phenotype
white participants	cohort
WHR-adjusted-for-BMI local	phenotype
women	cohort

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Genetics and epigenetics in the obesity phenotyping scenario.	Trang K et al.	—	2023	→
Genome-wide association meta-analysis identifies 17 loci associated with nonalcoholic fatty liver disease.	Chen Y et al.	—	2023	→
Genome-wide association study of abdominal MRI-measured visceral fat: The multiethnic cohort adiposity phenotype study.	Streicher SA et al.	—	2023	→
Knockout of murine Lyplal1 confers sex-specific protection against diet-induced obesity.	Vohnoutka RB et al.	—	2023	→
Large scale phenotype imputation and in vivo functional validation implicate ADAMTS14 as an adiposity gene.	Kentistou KA et al.	—	2023	→
Multi-trait discovery and fine-mapping of lipid loci in 125,000 individuals of African ancestry.	Kamiza AB et al.	—	2023	→
A Genome-Wide Association Study on Abdominal Adiposity-Related Traits in Adult Korean Men.	Kim HJ et al.	—	2022	→
Altered macronutrient composition and genetics influence the complex transcriptional network associated with adiposity in the Collaborative Cross.	Yam P et al.	—	2022	→
Clusters of risk factors in metabolic syndrome and their influence on central blood pressure in a global study.	Laucyte-Cibulskiene A et al.	—	2022	→
Deciphering signatures of natural selection via deep learning.	Qin X et al.	—	2022	→
Exploring the Genetic Association between Obesity and Serum Lipid Levels Using Bivariate Methods.	Ke J et al.	—	2022	→
Inherited basis of visceral, abdominal subcutaneous and gluteofemoral fat depots.	Agrawal S et al.	—	2022	→
Network Pharmacology Combined with Metabolomics Approach to Investigate the Toxicity Mechanism of Paclobutrazol.	Yue K et al.	—	2022	→
Sex Differences in Adiposity and Cardiovascular Diseases.	Li H et al.	—	2022	→
Strategies to identify causal common genetic variants and corresponding effector genes for paediatric obesity.	Littleton SH et al.	—	2022	→
Alcohol use and dysglycemia among people living with human immunodeficiency virus (HIV) in the Alcohol & Metabolic Comorbidities in PLWH: Evidence Driven Interventions (ALIVE-Ex) study.	Primeaux SD et al.	—	2021	→
Characterization of Hepatitis B Virus Integrations Identified in Hepatocellular Carcinoma Genomes.	Mathkar PP et al.	—	2021	→
Circulating microRNAs are associated with variability in fasting blood glucose over 12-months and target pathways related to type 2 diabetes: A pilot study.	Flowers E et al.	—	2021	→
Circulating MicroRNAs predict glycemic improvement and response to a behavioral intervention.	Flowers E et al.	—	2021	→
Dysmetabolic adipose tissue in obesity: morphological and functional characteristics of adipose stem cells and mature adipocytes in healthy and unhealthy obese subjects.	Porro S et al.	—	2021	→
Genetics of Body Fat Distribution: Comparative Analyses in Populations with European, Asian and African Ancestries.	Sun C et al.	—	2021	→
Genetics of Obesity: What We Have Learned Over Decades of Research.	Bouchard C	—	2021	→
Genetic underpinnings of regional adiposity distribution in African Americans: Assessments from the Jackson Heart Study.	Anwar MY et al.	—	2021	→
Genome-wide association study of neck circumference identifies sex-specific loci independent of generalized adiposity.	Liu Y et al.	—	2021	→
Genomics of body fat distribution.	Saini S et al.	—	2021	→
Identification of TBX15 as an adipose master trans regulator of abdominal obesity genes.	Pan DZ et al.	—	2021	→
Insights into non-autoimmune type 1 diabetes with 13 novel loci in low polygenic risk score patients.	Qu J et al.	—	2021	→
Knockout of murine <i>Lyplal1</i> confers sex-specific protection against diet-induced obesity	Vohnoutka RB et al.	—	2021	—
m6A RNA Methylation in Systemic Autoimmune Diseases-A New Target for Epigenetic-Based Therapy?	Wardowska A	—	2021	→
Association of serum uric acid with visceral, subcutaneous and hepatic fat quantified by magnetic resonance imaging.	Rospleszcz S et al.	—	2020	→
Autozygosity influences cardiometabolic disease-associated traits in the AWI-Gen sub-Saharan African study.	Ceballos FC et al.	—	2020	→
Highly Conserved Molecular Features in IgLONs Contrast Their Distinct Structural and Biological Outcomes.	Venkannagari H et al.	—	2020	→
Investigation of gene-gene interactions in cardiac traits and serum fatty acid levels in the LURIC Health Study.	Zhou J et al.	—	2020	→
Sex Differences in Genomic Drivers of Adipose Distribution and Related Cardiometabolic Disorders: Opportunities for Precision Medicine.	Lumish HS et al.	—	2020	→
The role of m<sup>6</sup>A modification in physiology and disease.	Yang C et al.	—	2020	→
Aldehyde Dehydrogenases Genetic Polymorphism and Obesity: From Genomics to Behavior and Health.	Hu C	—	2019	→
A low visceral fat proportion, independent of total body fat mass, protects obese adolescent girls against fatty liver and glucose dysregulation: a longitudinal study.	Umano GR et al.	—	2019	→
BMI-associated gene variants in <i>FTO</i> and cardiometabolic and brain disease: obesity or pleiotropy?	Ganeff IMM et al.	—	2019	→
Determinants of body fat distribution in humans may provide insight about obesity-related health risks.	Frank AP et al.	—	2019	→
Epigenome-wide meta-analysis of DNA methylation and childhood asthma.	Reese SE et al.	—	2019	→
Established and emerging strategies to crack the genetic code of obesity.	Tam V et al.	—	2019	→
Gene-by-Sex Interactions in Mitochondrial Functions and Cardio-Metabolic Traits.	Norheim F et al.	—	2019	→
Gene-Environment Interactions on Body Fat Distribution.	Li X et al.	—	2019	→
Genetic analysis of hsCRP in American Indians: The Strong Heart Family Study.	Best LG et al.	—	2019	→
Genetic variation in CADM2 as a link between psychological traits and obesity.	Morris J et al.	—	2019	→
Genome-wide association study of body fat distribution identifies adiposity loci and sex-specific genetic effects.	Rask-Andersen M et al.	—	2019	→
Genome-wide meta-analysis of SNP-by9-ACEI/ARB and SNP-by-thiazide diuretic and effect on serum potassium in cohorts of European and African ancestry.	Irvin MR et al.	—	2019	→
Integrating genetic, transcriptional, and biological information provides insights into obesity.	Wang L et al.	—	2019	→
Novel and known signals of selection for fat deposition in domestic sheep breeds from Africa and Eurasia.	Mastrangelo S et al.	—	2019	→
Novel Genetic Locus of Visceral Fat and Systemic Inflammation.	Shin J et al.	—	2019	→
Propensity for Intra-abdominal and Hepatic Adiposity Varies Among Ethnic Groups.	Lim U et al.	—	2019	→
Regional fat depot masses are influenced by protein-coding gene variants.	Neville MJ et al.	—	2019	→
Transcriptome profiling of four candidate milk genes in milk and tissue samples of temperate and tropical cattle.	Morenikeji OB et al.	—	2019	→
Alignment of diet prescription to genotype does not promote greater weight loss success in women with obesity participating in an exercise and weight loss program.	Coletta AM et al.	—	2018	→
AMPK activation negatively regulates GDAP1, which influences metabolic processes and circadian gene expression in skeletal muscle.	Lassiter DG et al.	—	2018	→
An Association Mapping Framework To Account for Potential Sex Difference in Genetic Architectures.	Kang EY et al.	—	2018	→
Associations of adult genetic risk scores for adiposity with childhood abdominal, liver and pericardial fat assessed by magnetic resonance imaging.	Monnereau C et al.	—	2018	→
Big Data and medicine: a big deal?	Mayer-Schönberger V et al.	—	2018	→
Cohort Profile: The Oxford Biobank.	Karpe F et al.	—	2018	→
Comprehensive review and annotation of susceptibility SNPs associated with obesity-related traits.	Dong SS et al.	—	2018	→
Dynamic changes in p66Shc mRNA expression in peripheral blood mononuclear cells following resistance training intervention in old frail women born to obese mothers: a pilot study.	Berry A et al.	—	2018	→
Exploring Coronary Artery Disease GWAs Targets With Functional Links to Immunometabolism.	Hughes MF et al.	—	2018	→
Genes that make you fat, but keep you healthy.	Loos RJF et al.	—	2018	→
Genetics of self-reported risk-taking behaviour, trans-ethnic consistency and relevance to brain gene expression.	Strawbridge RJ et al.	—	2018	→
Genetic Variants Associated With Obesity and Insulin Resistance in Hispanic Boys With Nonalcoholic Fatty Liver Disease.	Rausch JC et al.	—	2018	→
Genome-Wide Study of Subcutaneous and Visceral Adipose Tissue Reveals Novel Sex-Specific Adiposity Loci in Mexican Americans.	Gao C et al.	—	2018	→
High fat diet consumption differentially affects adipose tissue inflammation and adipocyte size in obesity-prone and obesity-resistant rats.	Poret JM et al.	—	2018	→
Investigation of common, low-frequency and rare genome-wide variation in anorexia nervosa.	Huckins LM et al.	—	2018	→
Metabolic syndrome and extensive adipose tissue inflammation in morbidly obese Göttingen minipigs.	Renner S et al.	—	2018	→
Metabolic Syndrome Prediction Using Machine Learning Models with Genetic and Clinical Information from a Nonobese Healthy Population.	Choe EK et al.	—	2018	→
Pharmacogenetics of oral antidiabetes drugs: evidence for diverse signals at the IRS1 locus.	Prudente S et al.	—	2018	→
Re-analysis of public genetic data reveals a rare X-chromosomal variant associated with type 2 diabetes.	Bonàs-Guarch S et al.	—	2018	→
Splicing QTL of human adipose-related traits.	Ma L et al.	—	2018	→
The case of GWAS of obesity: does body weight control play by the rules?	Müller MJ et al.	—	2018	→
The role of visceral and subcutaneous adipose tissue measurements and their ratio by magnetic resonance imaging in subjects with prediabetes, diabetes and healthy controls from a general population without cardiovascular disease.	Storz C et al.	—	2018	→
Using Adipose Measures from Health Care Provider-Based Imaging Data for Discovery.	Cha EDK et al.	—	2018	→
WDR11-mediated Hedgehog signalling defects underlie a new ciliopathy related to Kallmann syndrome.	Kim YJ et al.	—	2018	→
A high-coverage Neandertal genome from Vindija Cave in Croatia.	Prüfer K et al.	—	2017	→
An endophenotype approach to the genetics of alcohol dependence: a genome wide association study of fast beta EEG in families of African ancestry.	Meyers JL et al.	—	2017	→
Association of gene coding variation and resting metabolic rate in a multi-ethnic sample of children and adults.	Hellwege JN et al.	—	2017	→
Associations between body mass index-related genetic variants and adult body composition: The Fenland cohort study.	Clifton EA et al.	—	2017	→
Autonomous cortisol secretion in adrenal incidentalomas and increased visceral fat accumulation during follow-up.	Yener S et al.	—	2017	→
Dietary Fatty Acid Composition Modulates Obesity and Interacts with Obesity-Related Genes.	Hammad SS et al.	—	2017	→
Differential DNA Methylation in Monozygotic Twins Discordant for Female Sexual Functioning.	Burri A et al.	—	2017	→
Genetic Basis for Sex Differences in Obesity and Lipid Metabolism.	Link JC et al.	—	2017	→
Genomewide Association Scan of a Mortality Associated Endophenotype for a Long and Healthy Life in the Long Life Family Study.	Singh J et al.	—	2017	→
Genome-wide association study for feed efficiency and growth traits in U.S. beef cattle.	Seabury CM et al.	—	2017	→
Genomic variants at 20p11 associated with body fat mass in the European population.	Pei YF et al.	—	2017	→
Induced Pluripotent Stem Cell Differentiation Enables Functional Validation of GWAS Variants in Metabolic Disease.	Warren CR et al.	—	2017	→
Interaction between prenatal pesticide exposure and a common polymorphism in the <i>PON1</i> gene on DNA methylation in genes associated with cardio-metabolic disease risk-an exploratory study.	Declerck K et al.	—	2017	→
<i>Lyplal1</i> is dispensable for normal fat deposition in mice.	Watson RA et al.	—	2017	→
Multiethnic genome-wide meta-analysis of ectopic fat depots identifies loci associated with adipocyte development and differentiation.	Chu AY et al.	—	2017	→
Multilevel modelling of somatotype components: the Portuguese sibling study on growth, fitness, lifestyle and health.	Pereira S et al.	—	2017	→
Predicting the impact of non-coding variants on DNA methylation.	Zeng H et al.	—	2017	→
Progress toward Understanding Protein S-acylation: Prospective in Plants.	Li Y et al.	—	2017	→
Recent Advances in Human Genetics and Epigenetics of Adiposity: Pathway to Precision Medicine?	Fall T et al.	—	2017	→
Sexual dimorphism in obesity-related genes in the epicardial fat during aging.	Kocher C et al.	—	2017	→
Sexual dimorphisms in genetic loci linked to body fat distribution.	Pulit SL et al.	—	2017	→
The genetic underpinnings of body fat distribution.	Pulit SL et al.	—	2017	→
Whole-exome sequencing study reveals common copy number variants in protocadherin genes associated with childhood obesity in Koreans.	Moon S et al.	—	2017	→
A compendium of human genes regulating feeding behavior and body weight, its functional characterization and identification of GWAS genes involved in brain-specific PPI network.	Ignatieva EV et al.	—	2016	→
A genome-wide association study meta-analysis of clinical fracture in 10,012 African American women.	Taylor KC et al.	—	2016	→
A genome-wide investigation of food addiction.	Cornelis MC et al.	—	2016	→
A Genome-Wide mQTL Analysis in Human Adipose Tissue Identifies Genetic Variants Associated with DNA Methylation, Gene Expression and Metabolic Traits.	Volkov P et al.	—	2016	→
A GWA study reveals genetic loci for body conformation traits in Chinese Laiwu pigs and its implications for human BMI.	Zhou L et al.	—	2016	→
Analysis of Positive Selection at Single Nucleotide Polymorphisms Associated with Body Mass Index Does Not Support the "Thrifty Gene" Hypothesis.	Wang G et al.	—	2016	→
Effects of Obesity Related Genetic Variations on Visceral and Subcutaneous Fat Distribution in a Chinese Population.	Wang T et al.	—	2016	→
Fat depot-specific expression of HOXC9 and HOXC10 may contribute to adverse fat distribution and related metabolic traits.	Brune JE et al.	—	2016	→
Genetic Influences on Plasma Homocysteine Levels in African Americans and Yoruba Nigerians.	Kim S et al.	—	2016	→
Genome-wide association studies suggest sex-specific loci associated with abdominal and visceral fat.	Sung YJ et al.	—	2016	→
[Genomwide association studies on obesity: what can we learn from these studies].	Kronenberg F et al.	—	2016	→
H3Africa AWI-Gen Collaborative Centre: a resource to study the interplay between genomic and environmental risk factors for cardiometabolic diseases in four sub-Saharan African countries.	Ramsay M et al.	—	2016	→
High-throughput allele-specific expression across 250 environmental conditions.	Moyerbrailean GA et al.	—	2016	→
Influence of ADRB2 Gln27Glu and ADRB3 Trp64Arg polymorphisms on body weight and body composition changes after a controlled weight-loss intervention.	Szendrei B et al.	—	2016	→
Investigation of Genetic Variation Underlying Central Obesity amongst South Asians.	Scott WR et al.	—	2016	→
N6-methyladenosine modification in mRNA: machinery, function and implications for health and diseases.	Maity A et al.	—	2016	→
New loci for body fat percentage reveal link between adiposity and cardiometabolic disease risk.	Lu Y et al.	—	2016	→
Potential link between excess added sugar intake and ectopic fat: a systematic review of randomized controlled trials.	Ma J et al.	—	2016	→
Recent progress in genetics, epigenetics and metagenomics unveils the pathophysiology of human obesity.	Pigeyre M et al.	—	2016	→
Sex-Specific Association between Longitudinal Changes in Adiposity, FTO rs9939609 Polymorphism, and Leukocyte Telomere Length.	Shin C et al.	—	2016	→
The 22q11 PRODH/DGCR6 deletion is frequent in hyperprolinemic subjects but is not a strong risk factor for ASD.	Richard AC et al.	—	2016	→
The Decay of Disease Association with Declining Linkage Disequilibrium: A Fine Mapping Theorem.	Maadooliat M et al.	—	2016	→
The Framingham Heart Study--67 years of discovery in metabolic disease.	Long MT et al.	—	2016	→
A Common Variant of NGEF Is Associated with Abdominal Visceral Fat in Korean Men.	Kim HJ et al.	—	2015	→
Advancement in genetic variants conferring obesity susceptibility from genome-wide association studies.	Wang T et al.	—	2015	→
Apolipoprotein E (APOE) genotype regulates body weight and fatty acid utilization-Studies in gene-targeted replacement mice.	Huebbe P et al.	—	2015	→
Association Between LYPLAL1 rs12137855 Polymorphism With Ultrasound-Defined Non-Alcoholic Fatty Liver Disease in a Chinese Han Population.	Yuan C et al.	—	2015	→
Biology of upper-body and lower-body adipose tissue--link to whole-body phenotypes.	Karpe F et al.	—	2015	→
Comparative Analyses of QTLs Influencing Obesity and Metabolic Phenotypes in Pigs and Humans.	Pant SD et al.	—	2015	→
Differential positive selection of malaria resistance genes in three indigenous populations of Peninsular Malaysia.	Liu X et al.	—	2015	→
FTO influences adipogenesis by regulating mitotic clonal expansion.	Merkestein M et al.	—	2015	→
Genetic Determination of Serum Levels of Diabetes-Associated Adipokines.	Schleinitz D	—	2015	→
Genome-Wide Association Identifies SLC2A9 and NLN Gene Regions as Associated with Entropion in Domestic Sheep.	Mousel MR et al.	—	2015	→
Genome-wide association study identifies African-ancestry specific variants for metabolic syndrome.	Tekola-Ayele F et al.	—	2015	→
Insight in genome-wide association of metabolite quantitative traits by exome sequence analyses.	Demirkan A et al.	—	2015	→
Insights into the Genetic Susceptibility to Type 2 Diabetes from Genome-Wide Association Studies of Obesity-Related Traits.	Karaderi T et al.	—	2015	→
Modulation of genetic associations with serum urate levels by body-mass-index in humans.	Huffman JE et al.	—	2015	→
Natural Selection and Functional Potentials of Human Noncoding Elements Revealed by Analysis of Next Generation Sequencing Data.	Jha P et al.	—	2015	→
New genetic loci link adipose and insulin biology to body fat distribution.	Shungin D et al.	—	2015	→
Obesity associated Lyplal1 gene is regulated in diet induced obesity but not required for adipocyte differentiation.	Lei X et al.	—	2015	→
Performance of case-control rare copy number variation annotation in classification of autism.	Engchuan W et al.	—	2015	→
The anatomical distribution of genetic associations.	Wells A et al.	—	2015	→
The phenotypic manifestations of rare genic CNVs in autism spectrum disorder.	Merikangas AK et al.	—	2015	→
A CTNNA3 compound heterozygous deletion implicates a role for αT-catenin in susceptibility to autism spectrum disorder.	Bacchelli E et al.	—	2014	→
Common variants of GIP are associated with visceral fat accumulation in Japanese adults.	Nakayama K et al.	—	2014	→
Convergence of genes and cellular pathways dysregulated in autism spectrum disorders.	Pinto D et al.	—	2014	→
Ethnic disparities in the prevalence of the metabolic syndrome in American adults: data from the Examination of National Health and Nutrition Examination Survey 1999-2010.	Ramphal L et al.	—	2014	→
Gene-centric meta-analyses for central adiposity traits in up to 57 412 individuals of European descent confirm known loci and reveal several novel associations.	Yoneyama S et al.	—	2014	→
Genetic discoveries in AD using CSF amyloid and tau.	Cruchaga C et al.	—	2014	→
Genetic evidence for a normal-weight "metabolically obese" phenotype linking insulin resistance, hypertension, coronary artery disease, and type 2 diabetes.	Yaghootkar H et al.	—	2014	→
Genome-wide association study of smoking behaviours among Bangladeshi adults.	Argos M et al.	—	2014	→
Molecular heterogeneities of adipose depots - potential effects on adipose-muscle cross-talk in humans, mice and farm animals.	Komolka K et al.	—	2014	→
Pleiotropic genes for metabolic syndrome and inflammation.	Kraja AT et al.	—	2014	→
Schizophrenia gene expression profile reverted to normal levels by antipsychotics.	Crespo-Facorro B et al.	—	2014	→
Sex differences in disease genetics: evidence, evolution, and detection.	Gilks WP et al.	—	2014	→
Single-nucleotide polymorphisms and DNA methylation markers associated with central obesity and regulation of body weight.	Goni L et al.	—	2014	→
Sugar-sweetened beverage consumption is associated with abdominal fat partitioning in healthy adults.	Ma J et al.	—	2014	→
Targeting protein palmitoylation: selective inhibitors and implications in disease.	Chavda B et al.	—	2014	→
The genetics of fat distribution.	Schleinitz D et al.	—	2014	→
Waist circumference is genetically correlated with incident Type 2 diabetes in Mexican-American families.	Mamtani M et al.	—	2014	→
A 680 kb duplication at the FTO locus in a kindred with obesity and a distinct body fat distribution.	Davies RW et al.	—	2013	→
Abdominal fat distribution and its relationship to brain changes: the differential effects of age on cerebellar structure and function: a cross-sectional, exploratory study.	Raschpichler M et al.	—	2013	→
A common functional promoter variant links CNR1 gene expression to HDL cholesterol level.	Feng Q et al.	—	2013	→
A comprehensive analysis of adiponectin QTLs using SNP association, SNP cis-effects on peripheral blood gene expression and gene expression correlation identified novel metabolic syndrome (MetS) genes with potential role in carcinogenesis and systemic inflammation.	Zhang Y et al.	—	2013	→
Adiposity and insulin resistance in humans: the role of the different tissue and cellular lipid depots.	Hocking S et al.	—	2013	→
Association of DXA-derived bone mineral density and fat mass with African ancestry.	Ochs-Balcom HM et al.	—	2013	→
Association of obesity susceptibility gene variants with metabolic syndrome and related traits in 1,443 Czech adolescents.	Dušátková L et al.	—	2013	→
Candidate gene association study of BMI-related loci, weight, and adiposity in old age.	Murphy RA et al.	—	2013	→
Fat chance! Getting a grip on a slippery modification.	Tom CT et al.	—	2013	→
Gene × environment interactions in obesity: the state of the evidence.	Ahmad S et al.	—	2013	→
Genetic control of obesity and gut microbiota composition in response to high-fat, high-sucrose diet in mice.	Parks BW et al.	—	2013	→
Genetics of obesity and type 2 diabetes in African Americans.	McCormack S et al.	—	2013	→
Genome-wide association of body fat distribution in African ancestry populations suggests new loci.	Liu CT et al.	—	2013	→
Genome-wide association study of serum selenium concentrations.	Gong J et al.	—	2013	→
GWAS of 126,559 individuals identifies genetic variants associated with educational attainment.	Rietveld CA et al.	—	2013	→
Mapping eQTLs in the Norfolk Island genetic isolate identifies candidate genes for CVD risk traits.	Benton MC et al.	—	2013	→
NUDT3 rs206936 is associated with body mass index in obese Japanese women.	Kitamoto A et al.	—	2013	→
Obesity genomics: assessing the transferability of susceptibility loci across diverse populations.	Lu Y et al.	—	2013	→
Pleiotropy between genetic markers of obesity and risk of prostate cancer.	Edwards TL et al.	—	2013	→
Positive natural selection of TRIB2, a novel gene that influences visceral fat accumulation, in East Asia.	Nakayama K et al.	—	2013	→
QTL mapping of leukocyte telomere length in American Indians: the Strong Heart Family Study.	Zhu Y et al.	—	2013	→
Replication study of 15 recently published Loci for body fat distribution in the Japanese population.	Hotta K et al.	—	2013	→
Systematic evaluation of validated type 2 diabetes and glycaemic trait loci for association with insulin clearance.	Goodarzi MO et al.	—	2013	→
The IRS1 G972R polymorphism and glomerular filtration rate in patients with type 2 diabetes of European ancestry.	De Cosmo S et al.	—	2013	→
Topographical body fat distribution links to amino acid and lipid metabolism in healthy obese women [corrected].	Martin FP et al.	—	2013	→
Visceral adiposity in gastrointestinal and hepatic carcinogenesis.	Vongsuvanh R et al.	—	2013	→
Developmental origins of genotype-phenotype correlations in chronic diseases of old age.	McCormack S et al.	—	2012	→
Molecular nutrition research: the modern way of performing nutritional science.	Norheim F et al.	—	2012	→
The impact of intronic single nucleotide polymorphisms and ethnic diversity for studies on the obesity gene FTO.	Jacobsson JA et al.	—	2012	→