Qi Zexin, Sun Wenzheng, Luo Chun, Zhang Qiang, Osman Feisal Mohamed, Guan Chenglong, Wang Ye, Zhang Mengru, Zhang Xiaotong, Ding Jiale, Zhang Yuankai, Ling Fenglou, Liu Xiaolong, Zhang Zhian, Xu Chen
Agronomy College, Jilin Agricultural University, Changchun 130118, China.
College of Life Science and Resources and Environment, Yichun University, Yichun 336000, China.
Plants (Basel). 2025 Aug 8;14(16):2467. doi: 10.3390/plants14162467.
Nitrogen (N) availability significantly influences plant metabolism and productivity. The aim of this study was to assess the effects of low N stress and subsequent N supplementation on key enzymes of nitrogen metabolism, nitrogen metabolism-related substances, and chlorophyll a fluorescence kinetic parameters in rice genotypes with different nitrogen utilization efficiencies. We used the Jijing 88 (low-N tolerant) and Xinong 999 (low-N sensitive) as test materials. During the seedling, tillering, and booting stages, the 1/2N and 1/4N treatments were restored to the 1N treatment level. Nine treatments were used in this experiment: CK (1N), A1 (1/2N), A2 (1/2N restored to 1N during the seedling stage), A3 (1/2N restored to 1N during the tillering stage), A4 (1/2N restored to 1N during the booting stage), B1 (1/4N), B2 (1/4N restored to 1N during the seedling stage), B3 (1/4N restored to 1N during the tillering stage), and B4 (1/4N restored to 1N during the booting stage). Key physiological responses, nitrogen compounds, enzymes activities, and chlorophyll a fluorescence kinetics were analyzed. Under low nitrogen conditions, the growth and nitrogen assimilation of rice were inhibited. Compared to XN 999, JJ 88 maintains higher levels of dry matter, nitrate reductase activity (NR), glutamine synthetase activity (GS), glutamate oxaloacetate transaminase activity (GOT), glutamate pyruvate transaminase activity (GPT), as well as nitrate (NO) and ammonium (NH) nitrogen contents. After N supplementation during the early growth stage, both JJ 88 and XN 999 exhibit recovery capabilities. However, in the late growth stage, JJ 88 demonstrates superior recovery capabilities. In addition to enhancing nitrogen metabolism levels, there is also an increase in the content of osmotic regulation substances such as soluble sugars, free amino acids, and proline, along with responses in chlorophyll fluorescence kinetic parameters. This was primarily manifested in the enhancement of performance index (PI, PI), and quantum yield (φ, φ, ψ), which maintain photosynthetic performance and electron transport efficiency. The research findings indicated that reducing N supply during the early growth stage and restoring N levels in the later stage are beneficial for the recovery of low-nitrogen-tolerant rice varieties. Therefore, in the context of sustainable agricultural production, the breeding of low-nitrogen-tolerant rice varieties and the optimization of N fertilizer management are crucial.
氮(N)的有效性显著影响植物的新陈代谢和生产力。本研究的目的是评估低氮胁迫及随后的氮素补充对不同氮利用效率水稻基因型中氮代谢关键酶、氮代谢相关物质以及叶绿素a荧光动力学参数的影响。我们选用吉粳88(耐低氮)和西农999(低氮敏感)作为试验材料。在幼苗期、分蘖期和孕穗期,将1/2N和1/4N处理恢复到1N处理水平。本试验采用了9种处理:CK(1N)、A1(1/2N)、A2(幼苗期1/2N恢复到1N)、A3(分蘖期1/2N恢复到1N)、A4(孕穗期1/2N恢复到1N)、B1(1/4N)、B2(幼苗期1/4N恢复到1N)、B3(分蘖期1/4N恢复到1N)和B4(孕穗期1/4N恢复到1N)。分析了关键生理响应、含氮化合物酶活性和叶绿素a荧光动力学。在低氮条件下,水稻的生长和氮同化受到抑制。与西农999相比,吉粳88保持较高水平的干物质、硝酸还原酶活性(NR)、谷氨酰胺合成酶活性(GS)、谷氨酸草酰乙酸转氨酶活性(GOT)、谷氨酸丙酮酸转氨酶活性(GPT)以及硝酸盐(NO)和铵(NH)氮含量。在生长早期补充氮素后,吉粳88和西农999均表现出恢复能力。然而,在生长后期,吉粳88表现出更强的恢复能力。除了提高氮代谢水平外,渗透调节物质如可溶性糖、游离氨基酸和脯氨酸的含量也增加,同时叶绿素荧光动力学参数也有响应。这主要表现为性能指数(PI、PI)和量子产额(φ、φ、ψ)的提高,维持了光合性能和电子传递效率。研究结果表明,生长早期减少氮供应,后期恢复氮水平有利于耐低氮水稻品种的恢复。因此,在可持续农业生产背景下,培育耐低氮水稻品种和优化氮肥管理至关重要。
