Optimizing ethephon‐mediated sucrose allocation to increase kernel number in maize

Delaying the application of plant growth retardants, such as ethephon, can increase kernel number in maize (Zea mays L.), primarily due to the enhanced assimilate allocation to the ear. However, the underlying physiological and molecular mechanisms remain unclear. To clarify this, we investigated the effects of ethephon application from the 8- to 15-leaf stages (E8-E15) on the physiological mechanisms of kernel development, including internode elongation, dry matter accumulation and partitioning, fertilization, and kernel set. RNA-seq analysis was further performed on E14-treated and control (water spraying) plants at the silking stage and 8 days after silking to elucidate the molecular mechanisms underlying the ethephon-mediated kernel number increase. Delaying ethephon application at E14-E15 significantly shortened internodes below (-26.3% to -23.5%), at (-33.9% to -41.2%), and above (-22.9% to -52.5%) the ear. Average whole-plant dry matter increased by 8.1% at E14-E15 compared with the control. While ear dry matter increased by 32.4% at E14, it remained unchanged at E15. Optimizing the timing of ethephon application at E14-E15 did not negatively affect spikelet number formation but allocated more assimilates to the ear by retarding stem growth, resulting in increased kernel number (+8.3%) and grain yield (+7.4%). In E14, elevated sucrose allocation to the ear at silking resulted in increased trehalose-6-phosphate (T6P) accumulation, which subsequently enhanced assimilate import and improved carbohydrate utilization after flowering. Consequently, ear sucrose levels at silking were significantly higher than those in the control, consistent with the enhanced sink capacity. This enhancement was related to the suppression of sucrose-non-fermenting1-related protein kinase (SnRK1) activity. In contrast, post-flowering sucrose content was lower in E14 due to the upregulation of T6P-SnRK1 interaction genes during the kernel differentiation stage, which promoted sucrose utilization. Taken together, delayed ethephon application increased maize kernel number by optimizing pre-flowering sucrose partitioning to the ear and promoting post-flowering sucrose utilization.