Abstract
In plant breeding, one of the main purpose of multi-environment trial (MET) is to assess the intensity of genotype-by-environment (G×E) interactions in order to select high-performing lines of each environment. Most models to analyze such MET data consider only the additive genetic effects and the part of the non-additive genetic effects are confounded with the residual terms and this may lead to the non-negligible residual covariances between the same trait measured at multiple environments. In breeding programs it is also common to have the phenotype information from some environments available and values are missing in some other environments. In this study we focused on two problems: (1) to study the impact of different residual covariance structures on genomic prediction ability using different models to analyze MET data; (2) to compare the ability of different MET analysis models to predict the missing values in a single environment. Our results suggests that, it is important to consider the heterogeneous residual covariance structure for the MET analysis and multivariate mixed model seems to be especially suitable to predict the missing values in a single environment. We also present the prediction abilities based on Bayesian and frequentist approaches with different models using field data sets (maize and rice) having different levels of G×E interactions.
Highlights
Genomic selection (GS) [1] has revolutionized both animal and plant breeding programs with the advances in new genotyping technologies
In order to model the genotype by environment interaction we considered the following mixed model: y 1⁄4 Xb þ Zu þ Wv þ βi is a vector of fixed effects, ui is a vector of random additive genetic effects, v is the vector of random genotype by environment interaction effects, is a vector of error terms associated with the locations
Due to the strong genomic correlation between the environments. For both multiple environment cross validation (M_CV) and single environment cross validation (S_CV) cross validation procedures using model 1, the US, IDH and ANT1 residual covariance structures showed similar prediction abilities, whereas the prediction ability of IDV covariance structure was lower than the other residual structures
Summary
Genomic selection (GS) [1] has revolutionized both animal and plant breeding programs with the advances in new genotyping technologies. In GS, the selection decisions are based on the genomic estimated breeding values (GEBVs) which are calculated based on genome-wide dense set of markers. In both animal and plant breeding, GS will accelerate genetic gain for various complex traits. Increased genetic gains using GS have been already reported by many studies in crops [2] as well in livestock [3] breeding programs. Multi-environment trials (MET) are mainly used for two breeding purposes: 1) to find the stable high-performing lines—main GEBVs—across environments, 2) to find the most adapted superior genotype—specific GEBV—for a specific region.
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
