Abstract
Previous studies have shown that zinc (Zn) accumulation in shoot and grain increased as applied nitrogen (N) rate increased only when Zn supply was not limiting, suggesting a synergistic effect of N on plant Zn accumulation. However, little information is available about the effects of different mineral N sources combined with the presence or absence of Zn on the growth of both shoot and root and nutrient uptake. Maize plants were grown under sand-cultured conditions at three N forms as follows: NO3– nutrition alone, mixture of NO3–/NH4+ with molar ratio of 1:1 (recorded as mixed-N), and NH4+ nutrition alone including zero N supply as the control. These treatments were applied together without or with Zn supply. Results showed that N forms, Zn supply, and their interactions exerted a significant effect on the growth of maize seedlings. Under Zn-sufficient conditions, the dry weight (DW) of shoot, root, and whole plant tended to increase in the order of NH4+ < NO3– < mixed-N nutrition. Compared with NH4+ nutrition alone, mixed-N supply resulted in a 27.4 and 28.1% increase in leaf photosynthetic rate and stomatal conductance, which further resulted in 35.7 and 33.5% of increase in shoot carbon (C) accumulation and shoot DW, respectively. Furthermore, mixed-N supply resulted in a 19.7% of higher shoot C/N ratio vs. NH4+ nutrition alone, which means a higher shoot biomass accumulation, because of a significant positive correlation between shoot C/N ratio and shoot DW (R2 = 0.682***). Additionally, mixed-N supply promoted the greatest root DW, total root length, and total root surface area and synchronously improved the root absorption capacity of N, iron, copper, manganese, magnesium, and calcium. However, the above nutrient uptake and the growth of maize seedlings supplied with NH4+ were superior to either NO3– or mixed-N nutrition under Zn-deficient conditions. These results suggested that combined applications of mixed-N nutrition and Zn fertilizer can maximize plant growth. This information may be useful for enabling integrated N management of Zn-deficient and Zn-sufficient soils and increasing plant and grain production in the future.
Highlights
Nitrogen (N) is the most abundant mineral nutrient element in plants and plays an essential role in plant growth and development
Under a Zn-deficient condition, plants grown with NH4+ nutrition produced significantly greater shoot dry weight (DW) than with mixed N nutrition, whereas NO3− produced an intermediate shoot DW (Table 1)
Zn efficiency (ZE) of both shoot and root was significantly higher with NH4+ nutrition compared with NO3− and mixed-N supply (Table 1)
Summary
Nitrogen (N) is the most abundant mineral nutrient element in plants and plays an essential role in plant growth and development. Some studies showed the enhanced growth of maize under NO3− nutrition compared with NH4+ nutrition (Cramer and Lewis, 1993; Schortemeyer et al, 1997). Others showed that NH4+ uptake may be an important strategy for maize plants to take up sufficient quantities of N for growth compared with NO3− nutrition A mixture of both NO3− and NH4+ is superior to either NO3− or NH4+ sources alone, possibly due to improved cytokinin transportation from root to shoot, stimulated leaf growth, maintained rhizosphere pH, and increased nutrient uptake rates, such as N, phosphorus (P), copper (Cu), and iron (Fe) (Gentry and Below, 1993; Marschner, 2011; Cao et al, 2018; Wang et al, 2019)
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