Abstract
BackgroundWith environmental deterioration, natural resource scarcity, and rapid population growth, mankind is facing severe global food security problems. To meet future needs, it is necessary to accelerate progress in breeding for new varieties with high yield and strong resistance. However, the traditional phenotypic screening methods have some disadvantages, such as destructive, inefficient, low-dimensional, labor-intensive and cumbersome, which seriously hinder the development of field breeding. Breeders urgently need a high-throughput technique for acquiring and evaluating phenotypic data that can efficiently screen out excellent phenotypic traits from large-scale genotype populations.ResultsIn the present study, we used an unmanned aerial vehicle (UAV) high-throughput phenotyping (HTP) platform to collect RGB and multispectral images for a breeding program and acquired multiple phenotypic components (or traits), such as plant height, normalized difference vegetation index, biomass accumulation, plant-height growth rate, lodging, and leaf color. By implementing self-organizing maps and principal components analysis biplots to establish phenotypic map and similarity, we proposed an UAV-assisted HTP framework for preselecting maize (Zee mays L.) phenotypic components (or traits).ConclusionsThis framework gives breeders additional information to allow them to quickly identify and preselect plants that have genotypes conferring desirable phenotypic components out of thousands of field plots. The present study also demonstrates that remote sensing is a powerful tool with which to acquire abundant phenotypic components. By using these rich phenotypic components, breeders should be able to more effectively identify and select superior genotypes.
Highlights
IntroductionNatural resource scarcity, and rapid population growth, mankind is facing severe global food security problems
With environmental deterioration, natural resource scarcity, and rapid population growth, mankind is facing severe global food security problems
Phenotypic components from high‐throughput phenotyping images The phenotypic components evaluated in this study included plant height, fresh biomass, flowering, lodging, leaf color, genetic background, normalized difference vegetation index (NDVI), Average growth rate of plant height (AGRPH) and BIOVP
Summary
Natural resource scarcity, and rapid population growth, mankind is facing severe global food security problems. The traditional phenotypic screening methods have some disadvantages, such as destructive, inefficient, low-dimensional, labor-intensive and cumbersome, which seriously hinder the development of field breeding. Breeders urgently need a high-throughput technique for acquiring and evaluating phenotypic data that can efficiently screen out excellent phenotypic traits from large-scale genotype populations. With the imminent threat of environmental deterioration, natural resource scarcity, and rapid population growth, mankind is facing an unprecedented challenge of producing sufficient food to ensure global food security in the coming decades [1, 2]. With increasing demand for rapid phenotyping of large numbers of lines and to accelerate progress in breeding for novel traits, phenotyping is often considered the bottleneck of crop breeding [6]
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