Scalable Sparse Testing Genomic Selection Strategy for Early Yield Testing Stage.

Sikiru Adeniyi Atanda,Yoseph Beyene,Gbadebo Olaoye,Kate Dreher,Daniel Dzidzienyo,Juan Burgueño,Manje Gowda,Michael Olsen,Kelly R Robbins,Eric Yirenkyi Danquah,Prasanna M Boddupalli,Renaud Rincent,Pangirayi Tongoona,Jose Crossa

doi:10.3389/fpls.2021.658978

Abstract

To enable a scalable sparse testing genomic selection (GS) strategy at preliminary yield trials in the CIMMYT maize breeding program, optimal approaches to incorporate genotype by environment interaction (GEI) in genomic prediction models are explored. Two cross-validation schemes were evaluated: CV1, predicting the genetic merit of new bi-parental populations that have been evaluated in some environments and not others, and CV2, predicting the genetic merit of half of a bi-parental population that has been phenotyped in some environments and not others using the coefficient of determination (CDmean) to determine optimized subsets of a full-sib family to be evaluated in each environment. We report similar prediction accuracies in CV1 and CV2, however, CV2 has an intuitive appeal in that all bi-parental populations have representation across environments, allowing efficient use of information across environments. It is also ideal for building robust historical data because all individuals of a full-sib family have phenotypic data, albeit in different environments. Results show that grouping of environments according to similar growing/management conditions improved prediction accuracy and reduced computational requirements, providing a scalable, parsimonious approach to multi-environmental trials and GS in early testing stages. We further demonstrate that complementing the full-sib calibration set with optimized historical data results in improved prediction accuracy for the cross-validation schemes.

Highlights

Due to climate change threatening crop productivity in sub-Saharan Africa (SSA), breeding for drought tolerance and yield stability across target environments is a high priority for the International Maize and Wheat Improvement Center (CIMMYT) tropical maize breeding program (Beyene et al, 2015, 2019)
To identify a scalable strategy that optimizes the representation of genetic space of the genotypes across environments leading to efficient use of information across the environments at the early yield testing stage, we evaluated two different breeding scenarios: (1) predicting the genetic merit of new bi-parental populations across environments or, (2) predicting different subsets of a bi-parental population across environments
Except for when the environment was classified as year by management by location (LMY 1, 2, 3, 4, 5, and 6), where the unstructured model (US) model was responsive to the training set and did not consistently converge, the results for factor analytic (FA) and US models were equivalent regardless of the cross-validation schemes (Result not shown)

Summary

Introduction

Due to climate change threatening crop productivity in sub-Saharan Africa (SSA), breeding for drought tolerance and yield stability across target environments is a high priority for the International Maize and Wheat Improvement Center (CIMMYT) tropical maize breeding program (Beyene et al, 2015, 2019). To achieve genetic gain improvement in alignment with these breeding objectives, the CIMMYT maize breeding programs leverage novel technologies such as doubled. To identify parental lines for the breeding cycle and develop stress tolerant and high yielding hybrids that meet farmers’ needs, hybrids are tested under both well-watered (WW) and water-stress (WS) conditions in the preliminary screening stages. Each stage is characterized by the number of locations and the number of testers These factors influence selection accuracy in the different testing stages

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Conclusion