• ISSN 1008-505X
  • CN 11-3996/S
于晟玥, 牛银星, 王泽平, 李福贵, 柴龙行, 冯彪, 韩燕来, 王祎. 黄腐酸添加量对低氮胁迫下小麦生长和根系形态的影响[J]. 植物营养与肥料学报, 2023, 29(2): 323-333. DOI: 10.11674/zwyf.2022259
引用本文: 于晟玥, 牛银星, 王泽平, 李福贵, 柴龙行, 冯彪, 韩燕来, 王祎. 黄腐酸添加量对低氮胁迫下小麦生长和根系形态的影响[J]. 植物营养与肥料学报, 2023, 29(2): 323-333. DOI: 10.11674/zwyf.2022259
YU Sheng-yue, NIU Yin-xing, WANG Ze-ping, LI Fu-gui, CHAI Long-hang, FENG Biao, HAN Yan-lai, WANG Yi. Effects of fulvic acid addition rate on wheat growth and root morphology under low nitrogen stress[J]. Journal of Plant Nutrition and Fertilizers, 2023, 29(2): 323-333. DOI: 10.11674/zwyf.2022259
Citation: YU Sheng-yue, NIU Yin-xing, WANG Ze-ping, LI Fu-gui, CHAI Long-hang, FENG Biao, HAN Yan-lai, WANG Yi. Effects of fulvic acid addition rate on wheat growth and root morphology under low nitrogen stress[J]. Journal of Plant Nutrition and Fertilizers, 2023, 29(2): 323-333. DOI: 10.11674/zwyf.2022259

黄腐酸添加量对低氮胁迫下小麦生长和根系形态的影响

Effects of fulvic acid addition rate on wheat growth and root morphology under low nitrogen stress

  • 摘要:
    目的 黄腐酸(FA)是腐植酸中分子量较小、活性最大的组分,作为一种生物刺激素,FA 可以促进植物生长,提高植株的抗逆性。研究黄腐酸不同添加量对低氮胁迫下小麦生长及根系形态的影响,为小麦减氮增效提供实践和理论参考。
    方法 以小麦品种‘鑫华麦818’为材料进行了水培试验。将营养液氮浓度调节为硝态氮0.1 mmol/L模拟低氮胁迫(LN),并分别设置FA添加量0、30、60、90、120 mg/L,即 LN-FA0、LN-FA30、LN-FA60、LN-FA90、LN-FA120,共5个处理;以正常供氮营养液(硝态氮4 mmol/L)为对照(NN)。分析了小麦根系形态、植株生物量、植株氮浓度、氮累积量、叶片氮代谢关键酶活性等指标。
    结果 与LN-FA0相比,LN-FA30、LN-FA60、LN-FA90和LN-FA120处理的地上部生物量分别提高了16.31%、23.18%、26.75%和35.16%,LN-FA120的地上部生物量与正常氮处理已无显著差异;LN-FA30、LN-FA60和LN-FA90总根长增加了35.00%~44.67%,根表面积增加了39.93%~95.42%,根体积增加了55.38%~144.61%,根尖数增加了62.88%~90.12%,主根长增加了26.29%~31.71% (P≤0.05)。将根系按照直径划分为4个等级,FA处理主要促进了小麦Ⅰ~Ⅲ级根系的生长。与LN-FA0相比,4个FA处理均显著提高了小麦地上部氮累积量、根系氮吸收效率和地上部氮分配比例,显著提高了小麦叶片谷氨酸合成酶(GOGAT)和谷氨酸脱氢酶(GDH)活性。上述全部指标,除地上部生物量外,FA的提升效果均随FA添加量增加至90 mg/L达到最高值,FA120则不同程度地降低了对各指标的提升效果。
    结论 低氮胁迫下,适宜黄腐酸添加量可显著促进小麦Ⅰ~Ⅲ级根系的生长,提高总根长、主根长、根表面积、根体积和根尖数,进而显著提高小麦根系氮吸收效率以及在地上部的氮分配率,并通过提高低氮叶片的GOGAT和GDH活性增强植株氮代谢,促进地上部生物量积累。黄腐酸添加量在30~90 mg/L范围内,效果随黄腐酸添加量的增加而增强,当添加量达到120 mg/L时,其对小麦根系各指标和氮代谢酶活性的作用减小,但却获得了最大的地上部生物量,其原因还需继续研究。

     

    Abstract:
    Objectives Fulvic acid (FA), the most active component of humic acid with low molecular weight, contains biostimulants that improve plant growth and stress tolerance. Here, we studied the effects of different FA addition rates on wheat root morphology under low nitrogen stress to provide practical and theoretical references for wheat nitrogen fertilizer reduction and improved efficiency.
    Methods Wheat cultivar Xinhuamai 818 was used in a hydroponic experiment. We set up low N stress by adjusting the N level in the nutrient solution to 0.1 mmol/L NO3(LN), and FA was added into the culture solution at the rate of 0, 30, 60, 90, and 120 mg/L, namely LN-FA0, LN-FA30, LN-FA60, LN-FA90 and LN-FA120, respectively. A normal culture solution (4 mmol/L NO3) was used as the control (NN). Wheat root morphology, plant biomass, plant N concentration, and the activities of key nitrogen metabolism enzymes in the leaf were analyzed.
    Results Compared with LN-FA0 treatment, LN-FA30, LN-FA60, LN-FA90, and LN-FA120 treatments increased shoot biomass by 16.31%, 23.18%, 26.75%, and 35.16%. There was no significant difference in the shoot biomass of FA120 and the control. Compared with LN-FA0 treatment, LN-FA30, LN-FA60 and LN-FA90 treatments significantly increased total root length by 35.00%–44.67%, root surface area by 39.93%–95.42%, root volume by 55.38%–144.61%, root tip number by 62.88%–90.12%, and primary root length by 26.29%–31.71%. Among the four diameter root classes, FA promoted wheat root growth of class Ⅰ–Ⅲ. Compared with LN-FA0, the four FA treatments (P<0.05) increased shoot N accumulation, root N uptake efficiency, and N distribution in shoots. Moreover, the four FA treatments significantly increased the activities of glutamate synthase (GOGAT) and glutamate dehydrogenase (GDH) in wheat leaves under low N stress. Except for the shoot biomass, the stimulant effect peaked when the FA addition rate reached 90 mg/L, and LN-FA120 offset the stimulant effects to a different extent.
    Conclusions Under low nitrogen stress, FA addition promoted wheat root growth of class Ⅰ–Ⅲ and the total root length, primary root length, root surface area, root volume, and root tip numbers. FA treatment also improved root nitrogen uptake efficiency, nitrogen distribution in the shoot, and the activities of enzymes related to leaf nitrogen metabolism. All the promotion effects peaked at the FA addition rate of 90 mg/L. The FA addition rate of 120 mg/L did not show the strongest effect on the measured indexes but achieved the highest shoot biomass, which merits further research.

     

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