Mapping Epistatic Quantitative Trait Loci With One-Dimensional Genome Searches

Mapping Epistatic Quantitative Trait Loci With One-Dimensional Genome Searches

Jean-Luc Jannink^a and Ritsert Jansen^a
^a Wageningen-UR Centre for Biometry, Plant Research International, 6700 AA Wageningen, The Netherlands

Corresponding author: Jean-Luc Jannink, Agronomy Department, Iowa State University, Ames, IA 50011-1010., jjannink{at}iastate.edu (E-mail)

Communicating editor: J. A. M. VAN ARENDONK

The discovery of epistatically interacting QTL is hampered bythe intractability and low power to detect QTL in multidimensionalgenome searches. We describe a new method that maps epistaticQTL by identifying loci of high QTL by genetic background interaction.This approach allows detection of QTL involved not only in pairwisebut also higher-order interaction, and does so with one-dimensionalgenome searches. The approach requires large populations derivedfrom multiple related inbred-line crosses as is more typicallyavailable for plants. Using maximum likelihood, the method contrastsmodels in which QTL allelic values are either nested within,or fixed over, populations. We apply the method to simulateddoubled-haploid populations derived from a diallel among threeinbred parents and illustrate the power of the method to detectQTL of different effect size and different levels of QTL bygenetic background interaction. Further, we show how the methodcan be used in conjunction with standard two-locus QTL detectionmodels that use two-dimensional genome searches and find thatthe method may double the power to detect first-order epistasis.

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