Combining Genomic and Phenomic Information for Predicting Grain Protein Content and Grain Yield in Spring Wheat.

Karansher S Sandhu,Megan J Lewien,Paul D Mihalyov,Arron H Carter,Michael O Pumphrey

doi:10.3389/fpls.2021.613300

Karansher S Sandhu, Megan J Lewien + Show 3 more

Open Access

https://doi.org/10.3389/fpls.2021.613300

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Abstract

Genomics and high throughput phenomics have the potential to revolutionize the field of wheat (Triticum aestivum L.) breeding. Genomic selection (GS) has been used for predicting various quantitative traits in wheat, especially grain yield. However, there are few GS studies for grain protein content (GPC), which is a crucial quality determinant. Incorporation of secondary correlated traits in GS models has been demonstrated to improve accuracy. The objectives of this research were to compare performance of single and multi-trait GS models for predicting GPC and grain yield in wheat and to identify optimal growth stages for collecting secondary traits. We used 650 recombinant inbred lines from a spring wheat nested association mapping (NAM) population. The population was phenotyped over 3 years (2014–2016), and spectral information was collected at heading and grain filling stages. The ability to predict GPC and grain yield was assessed using secondary traits, univariate, covariate, and multivariate GS models for within and across cycle predictions. Our results indicate that GS accuracy increased by an average of 12% for GPC and 20% for grain yield by including secondary traits in the models. Spectral information collected at heading was superior for predicting GPC, whereas grain yield was more accurately predicted during the grain filling stage. Green normalized difference vegetation index had the largest effect on the prediction of GPC either used individually or with multiple indices in the GS models. An increased prediction ability for GPC and grain yield with the inclusion of secondary traits demonstrates the potential to improve the genetic gain per unit time and cost in wheat breeding.

Highlights

Important traits are often controlled by a large number of small effect quantitative trait locus (QTLs), which have been challenging to take advantage of in plant breeding (Bernardo, 2008)
We observed that inclusion of secondary correlated traits into covariate and multivariate genomic selection (GS) models resulted in a significant (p < 0.05) improvement in prediction accuracies for both traits, which can be attributed to the genetic correlation between primary and secondary traits used in this study
Our study demonstrates the improvement in GS prediction accuracies for grain yield and grain protein content (GPC) in wheat with the inclusion of secondary correlated traits in the models and identifies the most effective Spectral reflectance indices (SRI) and plant growth stage for secondary data collection

Summary

Introduction

Important traits are often controlled by a large number of small effect quantitative trait locus (QTLs), which have been challenging to take advantage of in plant breeding (Bernardo, 2008). Genome-wide association studies (GWAS) have offered a solution for dissecting the genetic basis of complex traits like disease resistance, grain yield, and end-use quality traits (Jernigan et al, 2018; Lewien et al, 2018). The small effect of these QTLs makes them inefficient to be used with marker-assisted selection (MAS) (Bernardo, 2008). Genomic selection (GS) has demonstrated the capacity to overcome the limitation of MAS and quantitative traits and is being implemented in various crop plants to improve genetic gain through selection (Jannink et al, 2010)

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