On the Hypothesis-free Testing of Metabolite Ratios in Genome-wide and Metabolome-wide Association Studies

Overview

Journal BMC Bioinformatics

Publisher Biomed Central

Specialty Biology

Date 2012 Jun 8

PMID 22672667

Citations 62

Authors

Ann-Kristin Petersen

Jan Krumsiek

Brigitte Wagele

Fabian J Theis

H-Erich Wichmann

Christian Gieger

Karsten Suhre

Affiliations

Soon will be listed here.

Abstract

Background: Genome-wide association studies (GWAS) with metabolic traits and metabolome-wide association studies (MWAS) with traits of biomedical relevance are powerful tools to identify the contribution of genetic, environmental and lifestyle factors to the etiology of complex diseases. Hypothesis-free testing of ratios between all possible metabolite pairs in GWAS and MWAS has proven to be an innovative approach in the discovery of new biologically meaningful associations. The p-gain statistic was introduced as an ad-hoc measure to determine whether a ratio between two metabolite concentrations carries more information than the two corresponding metabolite concentrations alone. So far, only a rule of thumb was applied to determine the significance of the p-gain.

Results: Here we explore the statistical properties of the p-gain through simulation of its density and by sampling of experimental data. We derive critical values of the p-gain for different levels of correlation between metabolite pairs and show that B/(2*α) is a conservative critical value for the p-gain, where α is the level of significance and B the number of tested metabolite pairs.

Conclusions: We show that the p-gain is a well defined measure that can be used to identify statistically significant metabolite ratios in association studies and provide a conservative significance cut-off for the p-gain for use in future association studies with metabolic traits.

Citing Articles

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