Abstract
BackgroundDeeper roots help plants take up available resources in deep soil ensuring better growth and higher yields under conditions of drought. A large-scale semi-field root phenotyping facility was developed to allow a water availability gradient and detect potential interaction of genotype by water availability gradient. Genotyped winter wheat lines were grown as rows in four beds of this facility, where indirect genetic effects from neighbors could be important to trait variation. The objective was to explore the possibility of genomic prediction for grain-related traits and deep root traits collected via images taken in a minirhizotron tube under each row of winter wheat measured.ResultsThe analysis comprised four grain-related traits: grain yield, thousand-kernel weight, protein concentration, and total nitrogen content measured on each half row that were harvested separately. Two root traits, total root length between 1.2 and 2 m depth and root length in four intervals on each tube were also analyzed. Two sets of models with or without the effects of neighbors from both sides of each row were applied. No interaction between genotypes and changing water availability were detected for any trait. Estimated genomic heritabilities ranged from 0.263 to 0.680 for grain-related traits and from 0.030 to 0.055 for root traits. The coefficients of genetic variation were similar for grain-related and root traits. The prediction accuracy of breeding values ranged from 0.440 to 0.598 for grain-related traits and from 0.264 to 0.334 for root traits. Including neighbor effects in the model generally increased the estimated genomic heritabilities and accuracy of predicted breeding values for grain yield and nitrogen content.ConclusionsSimilar relative amounts of additive genetic variance were found for both yield traits and root traits but no interaction between genotypes and water availability were detected. It is possible to obtain accurate genomic prediction of breeding values for grain-related traits and reasonably accurate predicted breeding values for deep root traits using records from the semi-field facility. Including neighbor effects increased the estimated additive genetic variance of grain-related traits and accuracy of predicting breeding values. High prediction accuracy can be obtained although heritability is low.
Highlights
Deeper roots help plants take up available resources in deep soil ensuring better growth and higher yields under conditions of drought
The objectives of this study were to (1) investigate genetic variation in grain-related and deep root traits in winter wheat; (2) study genomic by water availability interaction; (3) quantify neighbor effects when lines were grown in adjacent rows; and (4) analyze the possibilities of predicting breeding values of new wheat lines based on genomic prediction from the semi-field root phenotyping facility
Based on the grain-related and root data collected from a semi-field phenotyping system, variance components (VCs) for each trait were estimated and the accuracy in genomic prediction of breeding values (ACC) were assessed by cross-validation
Summary
Deeper roots help plants take up available resources in deep soil ensuring better growth and higher yields under conditions of drought. To investigate the deep root system in a non-laboratory condition as well as to obtain direct and stable measurements, a semi-field root phenotyping facility has been constructed recently [6]. This facility has a capacity of 150 rows (Fig. 1b) in each of eight experimental beds so that relatively large plant populations could be sown and studied. The facility is designed for both direct phenotyping of root traits through minirhizotrons and allow testing different of genotypes based along a water stress gradient
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