Guo Song, Chen Yanhua, Chen Xiaochao, Chen Yanling, Yang Lan, Wang Lifeng, Qin Yusheng, Li Mingshun, Chen Fanjun, Mi Guohua, Gu Riliang, Yuan Lixing
Soil and Fertilizer Research Institute, Sichuan Academy of Agricultural Sciences, Chengdu, China.
College of Resources and Environmental Sciences, China Agricultural University, Beijing, China.
Front Plant Sci. 2020 Jan 14;10:1662. doi: 10.3389/fpls.2019.01662. eCollection 2019.
Evaluating changes in the accumulation of grain minerals, including nitrogen (N), copper (Cu), iron (Fe), potassium (K), magnesium (Mg), manganese (Mn), phosphorus (P), and zinc (Zn), across different genotypes can provide valuable information for the development of nutrient-enriched maize varieties. Meanwhile, N rates can affect maize yield and quality, but their effects on element accumulation remain to be elucidated. Here, field experiments were conducted at two locations in China over 2 years (2010 and 2011). Under a normal N application rate (240 kg N ha), 24 maize cultivars that had been bred and released between 1930 and 2010 were evaluated for the elemental concentrations in the grains. Cultivars Yedan 13 and Zhengdan 958, representing old- and new-era cultivars respectively, were selected to investigate grain element accumulation in response to different levels of N (0, 60, 120, 180, and 240 kg N ha). The results showed that element concentrations were significantly affected by year, genotype (G), N rates, and N × G interaction. Grain yield tended to increase with the year of cultivar released, while the concentrations of N, Cu, Mn, and Zn in the grain significantly declined in the new-era. The element concentrations of grains were mainly influenced by N rate or N × G interactions. As N levels increased, N, Cu, Fe, Mg, and Mn concentrations rose, while K, P, and Zn concentrations decreased. Compared with old-era cultivars, new-era cultivars showed an increase in grain yield of 25.39%; however, they demonstrated decreases in N, Cu, Fe, K, Mg, P, and Zn concentrations. In the new-era varieties, the reduction in Cu, Fe, K, and P concentrations were significantly exacerbated by high N rates, but this was not the case in the old-era varieties. The concentration of grain Cu, K, Mg, P, and Zn were higher under N-limited condition (N0), but grain yield was also lower. However, the optimal N rate (120-180 kg N ha) could increase N, Fe, Mg, and Mn concentrations without affecting grain yield in new-era varieties. It is concluded that maize breeding processes have improved grain yield, but reduced grain nutrient element concentrations. Enhanced concentrations of certain elements in maize grain could be achieved with optimal rates of N fertilizer being applied.
评估不同基因型玉米籽粒中矿物质(包括氮(N)、铜(Cu)、铁(Fe)、钾(K)、镁(Mg)、锰(Mn)、磷(P)和锌(Zn))积累量的变化,可为培育营养强化型玉米品种提供有价值的信息。同时,施氮量会影响玉米产量和品质,但其对元素积累的影响仍有待阐明。在此,于2010年和2011年在中国的两个地点进行了田间试验。在正常施氮量(240 kg N/ha)条件下,对1930年至2010年间培育并审定的24个玉米品种的籽粒元素浓度进行了评估。分别选取代表旧时代品种的掖单13和代表新时代品种的郑单958,研究不同施氮水平(0、60、120、180和240 kg N/ha)下籽粒元素的积累情况。结果表明,元素浓度受年份、基因型(G)、施氮量以及氮与基因型互作(N×G)的显著影响。籽粒产量随品种审定年份的增加而趋于上升,而新时代品种籽粒中的氮、铜、锰和锌浓度显著下降。籽粒元素浓度主要受施氮量或氮与基因型互作的影响。随着施氮水平的提高,氮、铜、铁、镁和锰的浓度升高,而钾、磷和锌的浓度降低。与旧时代品种相比,新时代品种的籽粒产量提高了25.39%;然而,它们的氮、铜、铁、钾、镁、磷和锌浓度却有所下降。在新时代品种中,高施氮量显著加剧了铜、铁、钾和磷浓度的降低,但旧时代品种并非如此。在氮素限制条件(N0)下,籽粒中铜、钾、镁、磷和锌的浓度较高,但籽粒产量也较低。然而,最佳施氮量(120 - 180 kg N/ha)可提高新时代品种中氮、铁、镁和锰的浓度,且不影响籽粒产量。研究得出结论,玉米育种过程提高了籽粒产量,但降低了籽粒营养元素浓度。通过施用最佳施氮量可提高玉米籽粒中某些元素的浓度。
