Abstract
Iron deficiency chlorosis (IDC) is an abiotic stress in soybean that can cause significant biomass and yield reduction. IDC is characterized by stunted growth and yellowing and interveinal chlorosis of early trifoliate leaves. Scoring IDC severity in the field is conventionally done by visual assessment. The goal of this study was to investigate the usefulness of Red Green Blue (RGB) images of soybean plots captured under the field condition for IDC scoring. A total of 64 soybean lines with four replicates were planted in 6 fields over 2 years. Visual scoring (referred to as Field Score, or FS) was conducted at V3–V4 growth stage; and concurrently RGB images of the field plots were recorded with a high-throughput field phenotyping platform. A second set of IDC scores was done on the plot images (displayed on a computer screen) consistently by one person in the office (referred to as Office Score, or OS). Plot images were then processed to remove weeds and extract six color features, which were used to train computer-based IDC scoring models (referred to as Computer Score, or CS) using linear discriminant analysis (LDA) and support vector machine (SVM). The results showed that, in the fields where severe IDC symptoms were present, FS and OS were strongly positively correlated with each other, and both of them were strongly negatively correlated with yield. CS could satisfactorily predict IDC scores when evaluated using FS and OS as the reference (overall classification accuracy > 81%). SVM models appeared to outperform LDA models; and the SVM model trained to predict IDC OS gave the highest prediction accuracy. It was anticipated that coupling RGB imaging from the high-throughput field phenotyping platform with real-time image processing and IDC CS models would lead to a more rapid, cost-effective, and objective scoring pipeline for soybean IDC field screening and breeding.
Highlights
Iron deficiency chlorosis (IDC) is a serious abiotic stress in soybean characterized by stunted growth, yellowing and interveinal chlorosis of the early trifoliate leaves (Froechlich and Fehr, 1981)
The second group contained 43 entries, consisting of two commercial check cultivars, two parental lines of a recombinant inbred line (RIL) population developed for differing IDC responses, and 39 F6:8 experimental lines selected for extremes in IDC responses from a large RIL population developed by the University of Nebraska Soybean breeding program (Kocak, 2014)
IDC scoring was performed on the Red Green Blue (RGB) plot images displayed on a computer screen
Summary
Iron deficiency chlorosis (IDC) is a serious abiotic stress in soybean characterized by stunted growth, yellowing and interveinal chlorosis of the early trifoliate leaves (Froechlich and Fehr, 1981). Visual scoring is a key tool for assessing the variation of soybean plants in IDC tolerance (Niebur and Fehr, 1981; Inskeep and Bloom, 1987). The visual IDC symptoms of soybean plants are more pronounced in calcareous soils with higher pH (> 8.0) (Froechlich and Fehr, 1981; Jessen et al, 1988; Goos and Johnson, 2000; Hansen et al, 2004). A number of methods were investigated to reduce the economic impact of IDC, planting tolerant cultivars remains the most cost-effective approach to address the negative effect of IDC (Goos and Johnson, 2000). Visual scoring of IDC on soybean cultivars to be released is of great importance to producers, because of the high correlation of IDC symptoms to yield
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