Leaf to panicle ratio (LPR): a new physiological trait indicative of source and sink relation in japonica rice based on deep learning

• Published in: Plant methods Vol. 16; no. 1; p. 117
• Main Authors: Yang, Zongfeng, Gao, Shang, Xiao, Feng, Li, Ganghua, Ding, Yangfeng, Guo, Qinghua, Paul, Matthew J, Liu, Zhenghui
• Format: Journal Article
• Language: English
• Published: England BioMed Central Ltd 26.08.2020; BioMed Central; BMC
• Subjects: Agricultural production; Agronomy; Cameras; Canopies; Computer networks; Crop growth; Crop production; Crops; Cultivars; Data analysis; Datasets; Deep learning; Electronic data processing; Experiments; Fertilization; Field tests; Genomes; Genotype & phenotype; Genotypes; Grain; Growth regulators; Image processing; Japonica rice; Leaf and panicle detection; Leaf to panicle ratio (LPR); Leaves; Machine learning; Model accuracy; Physiological aspects; Physiological trait; Physiology; Plant breeding; Plant growth; Plant phenotyping; Production management; Rice; Rice fields; Spatial analysis; Spraying; Steel pipes; Temporal variations; China; Deep learning; Japonica rice; Leaf and panicle detection; Plant phenotyping; Leaf to panicle ratio (LPR); Physiological trait
• ISSN: 1746-4811; 1746-4811
• DOI: 10.1186/s13007-020-00660-y

Identification and characterization of new traits with sound physiological foundation is essential for crop breeding and production management. Deep learning has been widely used in image data analysis to explore spatial and temporal information on crop growth and development, thus strengthening the power of identification of physiological traits. Taking the advantage of deep learning, this study aims to develop a novel trait of canopy structure that integrate source and sink in japonica rice. We applied a deep learning approach to accurately segment leaf and panicle, and subsequently developed the procedure of GvCrop to calculate the leaf to panicle ratio (LPR) of rice canopy during grain filling stage. Images of training dataset were captured in the field experiments, with large variations in camera shooting angle, the elevation and the azimuth angles of the sun, rice genotype, and plant phenological stages. Accurately labeled by manually annotating the panicle and leaf regions, the resulting dataset were used to train FPN-Mask (Feature Pyramid Network Mask) models, consisting of a backbone network and a task-specific sub-network. The model with the highest accuracy was then selected to check the variations in LPR among 192 rice germplasms and among agronomical practices. Despite the challenging field conditions, FPN-Mask models achieved a high detection accuracy, with Pixel Accuracy being 0.99 for panicles and 0.98 for leaves. The calculated LPR displayed large spatial and temporal variations as well as genotypic differences. In addition, it was responsive to agronomical practices such as nitrogen fertilization and spraying of plant growth regulators. Deep learning technique can achieve high accuracy in simultaneous detection of panicle and leaf data from complex rice field images. The proposed FPN-Mask model is applicable to detect and quantify crop performance under field conditions. The newly identified trait of LPR should provide a high throughput protocol for breeders to select superior rice cultivars as well as for agronomists to precisely manage field crops that have a good balance of source and sink.