Integrating genomic-enabled prediction and high-throughput phenotyping in breeding for climate-resilient bread wheat

Philomin Juliana,Velu Govindan,Jesse Poland,Suchismita Mondal,Lorena González Pérez,Ravi P Singh,Susanne Dreisigacker,Julio Huerta-Espino,Francisco Pinto Espinosa,Osval A Montesinos-López,Paulino Pérez-Rodríguez,José Crossa,Sandesh Shrestha,Leonardo Crespo-Herrera

doi:10.1007/s00122-018-3206-3

Abstract

Genomic selection and high-throughput phenotyping (HTP) are promising tools to accelerate breeding gains for high-yielding and climate-resilient wheat varieties. Hence, our objective was to evaluate them for predicting grain yield (GY) in drought-stressed (DS) and late-sown heat-stressed (HS) environments of the International maize and wheat improvement center’s elite yield trial nurseries. We observed that the average genomic prediction accuracies using fivefold cross-validations were 0.50 and 0.51 in the DS and HS environments, respectively. However, when a different nursery/year was used to predict another nursery/year, the average genomic prediction accuracies in the DS and HS environments decreased to 0.18 and 0.23, respectively. While genomic predictions clearly outperformed pedigree-based predictions across nurseries, they were similar to pedigree-based predictions within nurseries due to small family sizes. In populations with some full-sibs in the training population, the genomic and pedigree-based prediction accuracies were on average 0.27 and 0.35 higher than the accuracies in populations with only one progeny per cross, indicating the importance of genetic relatedness between the training and validation populations for good predictions. We also evaluated the item-based collaborative filtering approach for multivariate prediction of GY using the green normalized difference vegetation index from HTP. This approach proved to be the best strategy for across-nursery predictions, with average accuracies of 0.56 and 0.62 in the DS and HS environments, respectively. We conclude that GY is a challenging trait for across-year predictions, but GS and HTP can be integrated in increasing the size of populations screened and evaluating unphenotyped large nurseries for stress–resilience within years.

Highlights

In the face of global food security and climate change, breeding bread wheat (Triticum aestivum L.) with highyield potential and improved resilience to stressed environments is crucial (Curtis and Halford 2014; Reynolds et al 2016)
Conventional breeding has led to substantial improvements in wheat grain yield (GY), breeders are constantly challenged with extreme weather conditions and increasing drought and heat-stressed environments (Trnka et al 2014; Tack et al 2015; Mäkinen et al 2017; Zampieri et al 2017)
Multivariate prediction of grain yield using the green normalized difference vegetation index and relationships We evaluated the ability of green NDVI (GNDVI) combined with relationships to predict GY (Table 4)

Summary

Introduction

In the face of global food security and climate change, breeding bread wheat (Triticum aestivum L.) with highyield potential and improved resilience to stressed environments is crucial (Curtis and Halford 2014; Reynolds et al 2016). Conventional breeding has led to substantial improvements in wheat grain yield (GY), breeders are constantly challenged with extreme weather conditions and increasing drought and heat-stressed environments (Trnka et al 2014; Tack et al 2015; Mäkinen et al 2017; Zampieri et al 2017). Continuous heat stress is a severe constraint in one of CIMMYT’s mega-environments. Theoretical and Applied Genetics (2019) 132:177–194 including south and central India (Cossani and Reynolds 2012), and it is expected that 51% of the Indo-Gangetic plains might be reclassified as a heat-stressed mega-environment by 2050 (Ortiz et al 2008). It was predicted that global wheat production would decrease between 4.1 and 6.4%, for every °C rise in temperature (Liu et al 2016)

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Discussion

Conclusion