Abstract
Quantification of the simultaneous contributions of loci to multiple traits, a phenomenon called pleiotropy, is facilitated by the increased availability of high-throughput genotypic and phenotypic data. To understand the prevalence and nature of pleiotropy, the ability of multivariate and univariate genome-wide association study (GWAS) models to distinguish between pleiotropic and non-pleiotropic loci in linkage disequilibrium (LD) first needs to be evaluated. Therefore, we used publicly available maize and soybean genotypic data to simulate multiple pairs of traits that were either (i) controlled by quantitative trait nucleotides (QTNs) on separate chromosomes, (ii) controlled by QTNs in various degrees of LD with each other, or (iii) controlled by a single pleiotropic QTN. We showed that multivariate GWAS could not distinguish between QTNs in LD and a single pleiotropic QTN. In contrast, a unique QTN detection rate pattern was observed for univariate GWAS whenever the simulated QTNs were in high LD or pleiotropic. Collectively, these results suggest that multivariate and univariate GWAS should both be used to infer whether or not causal mutations underlying peak GWAS associations are pleiotropic. Therefore, we recommend that future studies use a combination of multivariate and univariate GWAS models, as both models could be useful for identifying and narrowing down candidate loci with potential pleiotropic effects for downstream biological experiments.
Highlights
The number of traits available from state-of-the-art phenotyping techniques typically exceeds the number of genes in many species’ genomes
For quantitative trait nucleotides (QTNs) where we specified the minor allele frequencies (MAFs) as an input parameter, the observed MAF distributions were similar to the user-inputted values
The main conclusion from this study is that the use of either univariate or multivariate genome-wide association study (GWAS) alone is insufficient for rigorously dissecting the genetic architecture of multiple traits
Summary
The number of traits available from state-of-the-art phenotyping techniques typically exceeds the number of genes in many species’ genomes. The human genome contains over 20, 000 genes (Wagner and Zhang, 2011), but the Human Metabolome Database (Wishart et al, 2007) alone has collected more than 114, 000 metabolite traits. Examples of important genes with pleiotropic effects in plant science include Lg1 and its contribution to inflorescence and leaf traits in maize (Foster et al, 2004; Lewis et al, 2014) and multiple disease resistance attributed to GH3-2 in rice (Fu et al, 2011) and Lr67 in wheat (Moore et al, 2015). With the recent acquisition of high-throughput phenotype and genotype data, it is possible to directly identify pleiotropic causal mutations (Wagner and Zhang, 2011)
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