Large-scale GWAS of food liking reveals genetic determinants and genetic correlations with distinct neurophysiological traits

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作者
Sebastian May-Wilson
Nana Matoba
Kaitlin H. Wade
Jouke-Jan Hottenga
Maria Pina Concas
Massimo Mangino
Eryk J. Grzeszkowiak
Cristina Menni
Paolo Gasparini
Nicholas J. Timpson
Maria G. Veldhuizen
Eco de Geus
James F. Wilson
Nicola Pirastu
机构
[1] University of Edinburgh,Centre for Global Health Research, Usher Institute
[2] University of North Carolina at Chapel Hill,Department of Genetics
[3] University of North Carolina at Chapel Hill,UNC Neuroscience Center
[4] University of Bristol,Population Health Sciences, Bristol Medical School
[5] Medical Research Council (MRC) Integrative Epidemiology Unit (IEU) at the University of Bristol,Dept of Biological Psychology, FGB
[6] Vrije Universiteit Amsterdam,Department of Twin Research and Genetic Epidemiology
[7] Institute for Maternal and Child Health—IRCCS,Department of Medicine, Surgery and Health Sciences
[8] Burlo Garofolo,Department of Anatomy, Faculty of Medicine
[9] King’s College London,MRC Human Genetics Unit, Institute of Genetics and Cancer
[10] NIHR Biomedical Research Centre at Guy’s and St Thomas’ Foundation Trust,undefined
[11] University of Trieste,undefined
[12] Mersin University,undefined
[13] Amsterdam Public Health research institute,undefined
[14] University of Edinburgh,undefined
[15] Human Technopole,undefined
来源
Nature Communications | / 13卷
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摘要
We present the results of a GWAS of food liking conducted on 161,625 participants from the UK-Biobank. Liking was assessed over 139 specific foods using a 9-point scale. Genetic correlations coupled with structural equation modelling identified a multi-level hierarchical map of food-liking with three main dimensions: “Highly-palatable”, “Acquired” and “Low-caloric”. The Highly-palatable dimension is genetically uncorrelated from the other two, suggesting that independent processes underlie liking high reward foods. This is confirmed by genetic correlations with MRI brain traits which show with distinct associations. Comparison with the corresponding food consumption traits shows a high genetic correlation, while liking exhibits twice the heritability. GWAS analysis identified 1,401 significant food-liking associations which showed substantial agreement in the direction of effects with 11 independent cohorts. In conclusion, we created a comprehensive map of the genetic determinants and associated neurophysiological factors of food-liking.
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