Protein quantitative trait locus study in obesity during weight-loss identifies a leptin regulator

Jérôme Carayol; Christian Chabert; Alessandro Di Cara; Claudia Armenise; Gregory Lefebvre; Dominique Langin; Nathalie Viguerie; Sylviane Metairon; Wim H M Saris; Arne Astrup; Patrick Descombes; Armand Valsesia; Jörg Hager

doi:10.1038/s41467-017-02182-z

Protein quantitative trait locus study in obesity during weight-loss identifies a leptin regulator

Jérôme Carayol, Christian Chabert, Alessandro Di Cara, Claudia Armenise, Gregory Lefebvre, Dominique Langin, Nathalie Viguerie, Sylviane Metairon, Wim H M Saris, Arne Astrup, Patrick Descombes, Armand Valsesia, Jörg Hager

Obesity Research

23 Citations (Scopus)

76 Downloads (Pure)

Abstract

Thousands of genetic variants have been associated with complex traits through genomewide association studies. However, the functional variants or mechanistic consequences remain elusive. Intermediate traits such as gene expression or protein levels are good proxies of the metabolic state of an organism. Proteome analysis especially can provide new insights into the molecular mechanisms of complex traits like obesity. The role of genetic variation in determining protein level variation has not been assessed in obesity. To address this, we design a large-scale protein quantitative trait locus (pQTL) analysis based on a set of 1129 proteins from 494 obese subjects before and after a weight loss intervention. This reveals 55 BMI-associated cis-pQTLs and trans-pQTLs at baseline and 3 trans-pQTLs after the intervention. We provide evidence for distinct genetic mechanisms regulating BMI-associated proteins before and after weight loss. Finally, by functional analysis, we identify and validate FAM46A as a trans regulator for leptin.

Original language	English
Article number	2084
Journal	Nature Communications
Volume	8
Number of pages	14
ISSN	2041-1723
DOIs	https://doi.org/10.1038/s41467-017-02182-z
Publication status	Published - 1 Dec 2017

Keywords

Faculty of Science
Proteome analysis
Complex traits
Obesity
Protein quantitative trait locus (pQTL)
Weight loss
BMI-associated proteins
FAM46A
Trans regulator for leptin

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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Carayol et al_Nature Communications_2017_Vol 8_2084Final published version, 1.49 MBLicence: CC BY

Cite this

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title = "Protein quantitative trait locus study in obesity during weight-loss identifies a leptin regulator",

abstract = "Thousands of genetic variants have been associated with complex traits through genomewide association studies. However, the functional variants or mechanistic consequences remain elusive. Intermediate traits such as gene expression or protein levels are good proxies of the metabolic state of an organism. Proteome analysis especially can provide new insights into the molecular mechanisms of complex traits like obesity. The role of genetic variation in determining protein level variation has not been assessed in obesity. To address this, we design a large-scale protein quantitative trait locus (pQTL) analysis based on a set of 1129 proteins from 494 obese subjects before and after a weight loss intervention. This reveals 55 BMI-associated cis-pQTLs and trans-pQTLs at baseline and 3 trans-pQTLs after the intervention. We provide evidence for distinct genetic mechanisms regulating BMI-associated proteins before and after weight loss. Finally, by functional analysis, we identify and validate FAM46A as a trans regulator for leptin.",

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AU - Carayol, Jérôme

AU - Chabert, Christian

AU - Di Cara, Alessandro

AU - Armenise, Claudia

AU - Lefebvre, Gregory

AU - Langin, Dominique

AU - Viguerie, Nathalie

AU - Metairon, Sylviane

AU - Saris, Wim H M

AU - Astrup, Arne

AU - Descombes, Patrick

AU - Valsesia, Armand

AU - Hager, Jörg

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N2 - Thousands of genetic variants have been associated with complex traits through genomewide association studies. However, the functional variants or mechanistic consequences remain elusive. Intermediate traits such as gene expression or protein levels are good proxies of the metabolic state of an organism. Proteome analysis especially can provide new insights into the molecular mechanisms of complex traits like obesity. The role of genetic variation in determining protein level variation has not been assessed in obesity. To address this, we design a large-scale protein quantitative trait locus (pQTL) analysis based on a set of 1129 proteins from 494 obese subjects before and after a weight loss intervention. This reveals 55 BMI-associated cis-pQTLs and trans-pQTLs at baseline and 3 trans-pQTLs after the intervention. We provide evidence for distinct genetic mechanisms regulating BMI-associated proteins before and after weight loss. Finally, by functional analysis, we identify and validate FAM46A as a trans regulator for leptin.

AB - Thousands of genetic variants have been associated with complex traits through genomewide association studies. However, the functional variants or mechanistic consequences remain elusive. Intermediate traits such as gene expression or protein levels are good proxies of the metabolic state of an organism. Proteome analysis especially can provide new insights into the molecular mechanisms of complex traits like obesity. The role of genetic variation in determining protein level variation has not been assessed in obesity. To address this, we design a large-scale protein quantitative trait locus (pQTL) analysis based on a set of 1129 proteins from 494 obese subjects before and after a weight loss intervention. This reveals 55 BMI-associated cis-pQTLs and trans-pQTLs at baseline and 3 trans-pQTLs after the intervention. We provide evidence for distinct genetic mechanisms regulating BMI-associated proteins before and after weight loss. Finally, by functional analysis, we identify and validate FAM46A as a trans regulator for leptin.

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KW - Weight loss

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KW - Trans regulator for leptin

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DO - 10.1038/s41467-017-02182-z

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VL - 8

JO - Nature Communications

JF - Nature Communications

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ER -

Protein quantitative trait locus study in obesity during weight-loss identifies a leptin regulator

Abstract

Keywords

UN SDGs

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