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. 2019 Apr 1;28(7):1212-1224.
doi: 10.1093/hmg/ddy435.

Functionally oriented analysis of cardiometabolic traits in a trans-ethnic sample

Lauren E Petty  1   2 Heather M Highland  2   3 Eric R Gamazon  1   4 Hao Hu  5 Mandar Karhade  2 Hung-Hsin Chen  1   2 Paul S de Vries  2 Megan L Grove  2 David Aguilar  6 Graeme I Bell  7 Chad D Huff  5 Craig L Hanis  2 HarshaVardhan Doddapaneni  8 Donna M Munzy  8 Richard A Gibbs  8 Jianzhong Ma  2 Esteban J Parra  9 Miguel Cruz  10 Adan Valladares-Salgado  10 Dan E Arking  11 Alvaro Barbeira  12 Hae Kyung Im  12 Alanna C Morrison  2 Eric Boerwinkle  2 Jennifer E Below  1   2
Affiliations

Functionally oriented analysis of cardiometabolic traits in a trans-ethnic sample

Lauren E Petty et al. Hum Mol Genet. .

Abstract

Interpretation of genetic association results is difficult because signals often lack biological context. To generate hypotheses of the functional genetic etiology of complex cardiometabolic traits, we estimated the genetically determined component of gene expression from common variants using PrediXcan (1) and determined genes with differential predicted expression by trait. PrediXcan imputes tissue-specific expression levels from genetic variation using variant-level effect on gene expression in transcriptome data. To explore the value of imputed genetically regulated gene expression (GReX) models across different ancestral populations, we evaluated imputed expression levels for predictive accuracy genome-wide in RNA sequence data in samples drawn from European-ancestry and African-ancestry populations and identified substantial predictive power using European-derived models in a non-European target population. We then tested the association of GReX on 15 cardiometabolic traits including blood lipid levels, body mass index, height, blood pressure, fasting glucose and insulin, RR interval, fibrinogen level, factor VII level and white blood cell and platelet counts in 15 755 individuals across three ancestry groups, resulting in 20 novel gene-phenotype associations reaching experiment-wide significance across ancestries. In addition, we identified 18 significant novel gene-phenotype associations in our ancestry-specific analyses. Top associations were assessed for additional support via query of S-PrediXcan (2) results derived from publicly available genome-wide association studies summary data. Collectively, these findings illustrate the utility of transcriptome-based imputation models for discovery of cardiometabolic effect genes in a diverse dataset.

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Figures

Figure 1
Figure 1
Z-scores for novel gene GReX-trait association across relevant tissues for fibrinogen. Comparison of Z-scores across all cardiovascular trait-assessed tissues for a single trait, fibrinogen, demonstrating concordance of effects for each gene. Size of the point represents magnitude, color indicates direction of effect (blue points are positively associated with the trait, red points are negatively associated with the trait), and shade indicates the R2 from the prediction model. Missing points indicate that there is no model available for the given gene in that tissue.
See this image and copyright information in PMC

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