Effect of Trait Heritability, Training Population Size and Marker Density on Genomic Prediction Accuracy Estimation in 22 bi-parental Tropical Maize Populations.

Ao Zhang,Michael Olsen,José Crossa,Xuecai Zhang,Yubo Liu,Shiliang Cao,Haiqiu Yu,Kassa Semagn,Zhenhai Cui,Boddupalli M Prasanna,Yoseph Beyene,Hongwu Wang,Felix San Vicente,Yanye Ruan,Juan Burgueño

doi:10.3389/fpls.2017.01916

Abstract

Genomic selection is being used increasingly in plant breeding to accelerate genetic gain per unit time. One of the most important applications of genomic selection in maize breeding is to predict and select the best un-phenotyped lines in bi-parental populations based on genomic estimated breeding values. In the present study, 22 bi-parental tropical maize populations genotyped with low density SNPs were used to evaluate the genomic prediction accuracy (rMG) of the six trait-environment combinations under various levels of training population size (TPS) and marker density (MD), and assess the effect of trait heritability (h2), TPS and MD on rMG estimation. Our results showed that: (1) moderate rMG values were obtained for different trait-environment combinations, when 50% of the total genotypes was used as training population and ~200 SNPs were used for prediction; (2) rMG increased with an increase in h2, TPS and MD, both correlation and variance analyses showed that h2 is the most important factor and MD is the least important factor on rMG estimation for most of the trait-environment combinations; (3) predictions between pairwise half-sib populations showed that the rMG values for all the six trait-environment combinations were centered around zero, 49% predictions had rMG values above zero; (4) the trend observed in rMG differed with the trend observed in rMG/h, and h is the square root of heritability of the predicted trait, it indicated that both rMG and rMG/h values should be presented in GS study to show the accuracy of genomic selection and the relative accuracy of genomic selection compared with phenotypic selection, respectively. This study provides useful information to maize breeders to design genomic selection workflow in their breeding programs.

Highlights

Genomic selection (GS) is being used increasingly in plant breeding to accelerate genetic gain (Crossa et al, 2010; Zhang et al, 2015; Roorkiwal et al, 2016; Edriss et al, 2017)
Our results are consistent with the previous studies, good rMG values could be obtained in bi-parental maize populations, when the h2 of the target trait is high and the genome is covered with sufficient markers, i.e., mean distance between markers is
The main objectives of this study were to evaluate the rMG value of the six trait-environment combinations in 22 bi-parental tropical maize populations genotyped with low-density SNPs and assess the effect of h2, training population size (TPS), and marker density (MD) on rMG estimation in bi-parental populations

Summary

Introduction

Genomic selection (GS) is being used increasingly in plant breeding to accelerate genetic gain (Crossa et al, 2010; Zhang et al, 2015; Roorkiwal et al, 2016; Edriss et al, 2017). Using recombinant inbred lines derived from a cross between B73 and Mo17, Massman et al (2013) showed that GS produced from 14 to 50% higher genetic gains for stover and grain yield than marker assisted recurrent selection for several traits in a maize biparental population. This result was verified in tropical maize (Beyene et al, 2015; Vivek et al, 2017). The average genetic gain per selection cycle was 2.8%, when only the selection cycles were considered as the total breeding time

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