Genome-Wide Meta-Analysis Unravels Interactions between Magnesium Homeostasis and Metabolic Phenotypes.

Corre, T.; Arjona, F.J.; Hayward, C.; Youhanna, S.; de Baaij, JHF; Belge, H.; Nägele, N.; Debaix, H.; Blanchard, M.G.; Traglia, M.; Harris, S.E.; Ulivi, S.; Rueedi, R.; Lamparter, D.; Macé, A.; Sala, C.; Lenarduzzi, S.; Ponte, B.; Pruijm, M.; Ackermann, D.; Ehret, G.; Baptista, D.; Polasek, O.; Rudan, I.; Hurd, T.W.; Hastie, N.D.; Vitart, V.; Waeber, G.; Kutalik, Z.; Bergmann, S.; Vargas-Poussou, R.; Konrad, M.; Gasparini, P.; Deary, I.J.; Starr, J.M.; Toniolo, D.; Vollenweider, P.; Hoenderop, JGJ; Bindels, RJM; Bochud, M.; Devuyst, O.

doi:10.1681/ASN.2017030267

Genome-Wide Meta-Analysis Unravels Interactions between Magnesium Homeostasis and Metabolic Phenotypes.

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Serval ID

serval:BIB_E9CC84D13755

Type

Article: article from journal or magazin.

Collection

Publications

Institution

UNIL/CHUV

Title

Genome-Wide Meta-Analysis Unravels Interactions between Magnesium Homeostasis and Metabolic Phenotypes.

Journal

Journal of the American Society of Nephrology

Author(s)

Corre T., Arjona F.J., Hayward C., Youhanna S., de Baaij JHF, Belge H., Nägele N., Debaix H., Blanchard M.G., Traglia M., Harris S.E., Ulivi S., Rueedi R., Lamparter D., Macé A., Sala C., Lenarduzzi S., Ponte B., Pruijm M., Ackermann D., Ehret G., Baptista D., Polasek O., Rudan I., Hurd T.W., Hastie N.D., Vitart V., Waeber G., Kutalik Z., Bergmann S., Vargas-Poussou R., Konrad M., Gasparini P., Deary I.J., Starr J.M., Toniolo D., Vollenweider P., Hoenderop JGJ, Bindels RJM, Bochud M., Devuyst O.

ISSN

1533-3450 (Electronic)

ISSN-L

1046-6673

Publication state

Published

Issued date

01/2018

Peer-reviewed

Oui

Volume

Number

Pages

335-348

Language

english

Notes

Publication types: Journal Article ; Meta-Analysis ; Research Support, Non-U.S. Gov't
Publication Status: ppublish

Abstract

Magnesium (Mg 2+ ) homeostasis is critical for metabolism. However, the genetic determinants of the renal handling of Mg 2+ , which is crucial for Mg 2+ homeostasis, and the potential influence on metabolic traits in the general population are unknown. We obtained plasma and urine parameters from 9099 individuals from seven cohorts, and conducted a genome-wide meta-analysis of Mg 2+ homeostasis. We identified two loci associated with urinary magnesium (uMg), rs3824347 (P=4.4×10 -13 ) near TRPM6, which encodes an epithelial Mg 2+ channel, and rs35929 (P=2.1×10 -11 ), a variant of ARL15, which encodes a GTP-binding protein. Together, these loci account for 2.3% of the variation in 24-hour uMg excretion. In human kidney cells, ARL15 regulated TRPM6-mediated currents. In zebrafish, dietary Mg 2+ regulated the expression of the highly conserved ARL15 ortholog arl15b, and arl15b knockdown resulted in renal Mg 2+ wasting and metabolic disturbances. Finally, ARL15 rs35929 modified the association of uMg with fasting insulin and fat mass in a general population. In conclusion, this combined observational and experimental approach uncovered a gene-environment interaction linking Mg 2+ deficiency to insulin resistance and obesity.

Keywords

ADP-Ribosylation Factors/genetics, Adiposity/genetics, Animals, Gene-Environment Interaction, Genome-Wide Association Study, Homeostasis/genetics, Humans, Insulin/blood, Insulin Resistance/genetics, Kidney/metabolism, Magnesium/administration & dosage, Magnesium/blood, Magnesium/urine, Mice, Obesity/genetics, Phenotype, Polymorphism, Single Nucleotide, RNA, Messenger/metabolism, TRPM Cation Channels/genetics, Zebrafish, Gene-environment interaction, Genetic determinants, Magnesium homeostasis, Metabolic syndrome, Tubular transport, zebrafish

OAI-PMH

oai:serval.unil.ch:BIB_E9CC84D13755

DOI

10.1681/ASN.2017030267

Pubmed

29093028

Web of science

000419070800033

Open Access

Yes

Create date

16/11/2017 11:26