Abstract
Increasing plant density is one of the main approaches of achieving higher yields for modern maize crop. However, there exists leaf redundancy for high-density maize, and leaves of the upper canopy shade more competent leaves at the middle strata. In a two-year field experiments, Jinhai5, a semi-compact corn cultivar, was grown at a density of 105,000 plants ha−1 grown until 3 days after silking (3DAS), when plants were subjected to removal of the uppermost two leaves (S2), four leaves (S4) or six leaves (S6), with no leaf removal as control (S0). We evaluated the effects of leaf removal on N remobilization, photosynthetic capacity of the remaining leaves for N uptake, and N accumulation in kernels. Our present results concluded that, under high plant density, excising the uppermost two leaves promoted N remobilization from vegetative organs to kernels and enhanced photosynthetic capacity for N uptake, leading to an increased N accumulation in kernels (19.6% higher than control). However, four or six uppermost leaves removal reduced N remobilization from stem and photosynthesis for poor N uptake, resulting in 37.5 and 50.2% significantly reduced N accumulation in kernels, respectively.
Highlights
Increasing plant density is one of the main approaches of achieving higher yields for modern maize crops[1,2,3,4], which enables plants to use solar radiation more efficiently[5,6]
Leaf removal resulted in different levels of reduction in total N accumulation compared with control
We found that N uptake from 4DAS to R6 and N uptake from 4DAS to R6 / N accumulation at R6 were significantly (P < 0.01) and linearly related (R2 = 0.83; R2 = 0.77; Fig. 3) to sum canopy apparent photosynthesis (CAP) during the same period
Summary
Increasing plant density is one of the main approaches of achieving higher yields for modern maize crops[1,2,3,4], which enables plants to use solar radiation more efficiently[5,6]. We hypothesized that at high plant density, optimum leaf removal above the ear leaf would (1) increase N remobilization from vegetative organs, (2) enhance canopy apparent photosynthesis for N uptake during grain filling, and (3) obtain higher N accumulation in kernels at physiological maturity. We tested this hypothesis by removing two, four or six uppermost leaves from top of a plant at three days after silking, with no-leaf removal as control, to understand whether higher N accumulation in kernels of maize at high density could be achieved through optimum leaf removal, to provide a theoretical basis for super-high-yield corn cultivation
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