Abstract
High throughput phenotyping technologies are lagging behind modern marker technology impairing the use of secondary traits to increase genetic gains in plant breeding. We aimed to assess whether the combined use of hyperspectral data with modern marker technology could be used to improve across location pre-harvest yield predictions using different statistical models. A maize bi-parental doubled haploid (DH) population derived from F1, which consisted of 97 lines was evaluated in testcross combination under heat stress as well as combined heat and drought stress during the 2014 and 2016 summer season in Ciudad Obregon, Sonora, Mexico (27°20” N, 109°54” W, 38 m asl). Full hyperspectral data, indicative of crop physiological processes at the canopy level, was repeatedly measured throughout the grain filling period and related to grain yield. Partial least squares regression (PLSR), random forest (RF), ridge regression (RR) and Bayesian ridge regression (BayesB) were used to assess prediction accuracies on grain yield within (two-fold cross-validation) and across environments (leave-one-environment-out-cross-validation) using molecular markers (M), hyperspectral data (H) and the combination of both (HM). Highest prediction accuracy for grain yield averaged across within and across location predictions (rGP) were obtained for BayesB followed by RR, RF and PLSR. The combined use of hyperspectral and molecular marker data as input factor on average had higher predictions for grain yield than hyperspectral data or molecular marker data alone. The highest prediction accuracy for grain yield across environments was measured for BayesB when molecular marker data and hyperspectral data were used as input factors, while the highest within environment prediction was obtained when BayesB was used in combination with hyperspectral data. It is discussed how the combined use of hyperspectral data with molecular marker technology could be used to introduce physiological genomic estimated breeding values (PGEBV) as a pre-harvest decision support tool to select genetically superior lines.
Highlights
To meet the future demand of food, feed, fiber, and fuel, crop production must double by 2050 [1]
After filtering with minor allele frequency (MAF) greater than 0.05 and missing rates less than 20%, the total number of single nucleotide polymorphisms (SNPs) decreased to 47203
The average MAF was 0.42 and 79.74% of the SNPs concentrated to the MAF ranging from 0.40 to 0.50
Summary
To meet the future demand of food, feed, fiber, and fuel, crop production must double by 2050 [1]. Crop yields are limited inherently by biotic and abiotic stresses, whereas plant researchers try to protect yield from plant stress losses by incorporating alleles that confer resistance to diseases and improving resistance to abiotic stresses resulting from changes in climate [2]. It was shown [1, 3] that each accumulated degree-day above 30 ̊C reduced harvestable grain yield by 1% under optimal rain-fed conditions. Current phenotyping technologies are still lagging behind and limiting the use of modern marker technology
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