Abstract
Plant height (PH) is a key factor in maize (Zea mays L.) yield, biomass, and plant architecture. We investigated the PH of diverse maize inbred lines (117 temperate lines, 135 tropical lines) at four growth stages using unmanned aerial vehicle high-throughput phenotypic platforms (UAV-HTPPs). We extracted PH data using an automated pipeline based on crop surface models and orthomosaic model. The correlation between UAV and manually measured PH data reached 0.95. Under temperate field conditions, temperate maize lines grew faster than tropical maize lines at early growth stages, but tropical lines grew faster at later growth stages and ultimately became taller than temperate lines. A genome-wide association study identified 68 unique quantitative trait loci (QTLs) for seven PH-related traits, and 35% of the QTLs coincided with those previously reported to control PH. Generally, different QTLs controlled PH at different growth stages, but eight QTLs simultaneously controlled PH and growth rate at multiple growth stages. Based on gene annotations and expression profiles, we identified candidate genes controlling PH. The PH data collected by the UAV-HTPPs were credible and the genetic mapping power was high. Therefore, UAV-HTPPs have great potential for use in studies on PH.
Highlights
Maize (Zea mays L.) was domesticated from Balsas teosinte (Zea mays subspecies parviglumis) in southwestern Mexico around 9,000 years ago[1]
With constant improvements in unmanned aerial vehicles (UAV) equipment, the continuous optimization of image processing methods, and the removal of extreme data, the correlation coefficients between plant height (PH) measured by UAV remote sensing (PHUAV) and PH measured with a ruler (PHR) have reached moderate to high values[25,27,28,29]
To better understand the dynamic PH mechanism, we investigated PH at four important growth periods with a UAV system for genetically diverse maize inbred lines that are widely used in maize genetic research[9,13,30]
Summary
Maize (Zea mays L.) was domesticated from Balsas teosinte (Zea mays subspecies parviglumis) in southwestern Mexico around 9,000 years ago[1]. To better understand the dynamic PH mechanism, we investigated PH at four important growth periods with a UAV system for genetically diverse maize inbred lines that are widely used in maize genetic research[9,13,30]. Through this design, we aimed to explore more PH characteristics with the aid of the high-throughput UAV and data processing procedures, and dissect the genetic basis of PH for different maize groups at different stages
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