Effects of inorganic N on the N accumulation and root morphology of a mining ecotype of Polygonum hydropiper

doi:10.11686/cyxb2019117

Abstract

Abstract: Excessive application of nitrogen (N) fertilizers increases the loss of N via runoff and leaching, resulting in a more serious eutrophication. In a previous study, we screened out a nitrogen-phosphorus enriched plant, the mining ecotype (ME) of Polygonum hydropiper. Studying the root morphology response to inorganic nitrogen addition could be expected to provide a theoretical basis for understanding the absorption and accumulation mechanism of nitrogen in the ME of P. hydropiper. Sand culture experiments were conducted to analyse the N accumulation and root morphology of the P. hydropiper ME supplied with different ammonium nitrogen (NH₄-N) concentrations (25, 50, 75 mg N·L^-1) and different nitrate nitrogen (NO₃-N) concentrations (25, 50, 75 mg N·L^-1). The P. hydropiper ME showed the greatest biomass and N accumulation at 50 mg N·L^-1. The biomass values of the P. hydropiper ME grown in 50 and 75 mg·L^-1 NO₃-N treatments were significantly higher than those in NH₄-N treatments; however, the P. hydropiper ME accumulated more N when grown in the NH₄-N than when grown in the NO₃-N treatments. The root growth of the P. hydropiper ME was greatly inhibited with increasing NH₄-N concentrations in solution. The root system of the P. hydropiper ME showed the greatest length, surface area, and volume when grown in 50 mg·L^-1 NO₃-N. The root growth of the P. hydropiper ME was greater in NH₄-N than in NO₃-N at 25 mg N·L^-1, but this difference was reversed at 50 and 75 mg N·L^-1. In summary, he appropriate NO₃-N concentration promoted the growth of the P. hydropiper ME and the development of lateral roots, resulting in enhanced absorption of N. High concentration of NH₄-N inhibited root growth, but did not reduce N accumulation in the plant.

Key words: Polygonum hydropiper, inorganic nitrogen, root morphology, nitrogen accumulation

QING Yue, LI Ting-xuan, YE Dai-hua. Effects of inorganic N on the N accumulation and root morphology of a mining ecotype of Polygonum hydropiper[J]. Acta Prataculturae Sinica, 2020, 29(1): 203-210.

References

[1] Cameron K C, Di H J, Moir J L.Nitrogen losses from the soil/plant system: A review. Annals of Applied Biology, 2013, 162(2): 145-173.
[2] Davis M.Nitrogen leaching losses from forests in New Zealand. New Zealand Journal of Forestry Science, 2014, 44(1): 2-14.
[3] Temponeras M, Kristiansen J, Moustaka-Gouni M.Seasonal variation in phytoplankton composition and physical-chemical features of the shallow lake Diorama, Macedonia, Greece. Hydrobiology, 2010, 424(1/2/3): 109-122.
[4] Pan Y C, Sun C, Liu Y, et al. Carrying capacity of livestock and poultry breeding based on feces disposal volume of land. Transactions of the Chinese Society of Agricultural Engineering, 2015, 31(4): 232-239.
潘瑜春, 孙超, 刘玉, 等. 基于土地消纳粪便能力的畜禽养殖承载力. 农业工程学报, 2015, 31(4): 232-239.
[5] Zhao X, Zhou Y, Min J, et al. Nitrogen runoff dominates water nitrogen pollution from rice-wheat rotation in the Taihu Lake region of China. Agriculture, Ecosystems and Environment, 2012, 156(4): 1-11.
[6] Li J, Yang X, Wang Z, et al. Comparison of four aquatic plant treatment systems for nutrient removal from eutrophied water. Bioresource Technology, 2015, 179: 1-7.
[7] Villamagna A M, Murphy B R.Ecological and socio-economic impacts of invasive water hyacinth (Eichhornia crassipe): A review. Freshwater Biology, 2010, 55(2): 282-298.
[8] Gao L F, Zhang L.Analysis of eutrophic condition of some reservoir in Shandong. Environmental Science & Technology, 2010, (S1): 221-224, 276.
高林峰, 张雷. 山东某水库水体富营养化状况分析. 环境科学与技术, 2010, (S1): 221-224, 276.
[9] Chen G Y, Gan L Y.Effects of different concentrations of $NH_4^+$ on the antioxidant system of Iris pseudacorus L. Environmental Science and Technology, 2014, (4): 6-9.
陈国元, 甘丽云. 不同浓度$NH_4^+$对黄菖蒲抗氧化酶系统的影响. 环境科技, 2014, (4): 6-9.
[10] Meng Z L, Yang Y G, Qin Z D, et al. Isotopic tracing for nitrate pollution process of water body in the lower reaches of Fenhe River. China Environmental Science, 2017, 37(3): 1066-1072.
孟志龙, 杨永刚, 秦作栋, 等. 汾河下游流域水体硝酸盐污染过程同位素示踪. 中国环境科学, 2017, 37(3): 1066-1072.
[11] Feng X J, Zheng Z C, Li T X.Characteristics of runoff and nitrogen loss in sloping cropland of purple soil during corn growing season. Journal of Soil and Water Conservation, 2017, 31(1): 43-48.
冯小杰, 郑子成, 李廷轩. 紫色土区坡耕地玉米季地表径流及其氮素流失特征. 水土保持学报, 2017, 31(1): 43-48.
[12] Wang J Y, Wang H Q, Liang X D, et al. Response of root morphology and N absorption to nitrate nitrogen supply in hydroponic oats. Journal of Plant Nutrition and Fertilizer, 2016, 22(4): 1049-1055.
王俊英, 王华青, 梁晓东, 等. 水培燕麦根系形态和氮吸收流量对硝态氮供应浓度的响应. 植物营养与肥料学报, 2016, 22(4): 1049-1055.
[13] Xiong S P, Wu K Y, Wang X C, et al. Analysis of root absorption characteristics and nitrogen utilization of wheat genotypes with different N efficiency. Scientia Agricultura Sinica, 2016, 49(12): 2267-2279.
熊淑萍, 吴克远, 王小纯, 等. 不同氮效率基因型小麦根系吸收特性与氮素利用差异的分析. 中国农业科学, 2016, 49(12): 2267-2279.
[14] Cheng Y, Wang H Z, Liu P, et al. Effect of different maize varieties and nitrogen supply on root characteristics and nitrogen uptake and utilization efficiency. Scientia Agricultura Sinica, 2017, 50(12): 2259-2269.
程乙, 王洪章, 刘鹏, 等. 品种和氮素供应对玉米根系特征及氮素吸收利用的影响. 中国农业科学, 2017, 50(12): 2259-2269.
[15] Chen C, Gong H Q, Zhang J Z, et al. Correlation between root morphology and nitrogen uptake of rice. Journal of Plant Nutrition and Fertilizer, 2017, 23(2): 333-341.
陈晨, 龚海青, 张敬智, 等. 水稻根系形态与氮素吸收累积的相关性分析. 植物营养与肥料学报, 2017, 23(2): 333-341.
[16] Wang Y, Zhang X, Chen J, et al. Reducing basal nitrogen rate to improve maize seedling growth, water and nitrogen use efficiencies under drought stress by optimizing root morphology and distribution. Agricultural Water Management, 2019, 212(1): 328-337.
[17] Othman Y A, Leskovar D.Nitrogen management influenced root length intensity of young olive trees. Scientia Horticulturae, 2019, 246(27): 726-733.
[18] Liu S B, Ran B, Zeng G J, et al. Physiological characteristics and nitrogen and phosphorus uptake of Myriophyllum aquaticum under high ammonium conditions. Environmental Science, 2017, 38(9): 3731-3737.
刘少博, 冉彬, 曾冠军, 等. 高铵条件下绿狐尾藻的生理与氮磷吸收特征. 环境科学, 2017, 38(9): 3731-3737.
[19] Guo Y H, Yu Y Y, Wen L Z, et al. Molecular basis of the effects of nitrate signal on root morphological structure changes of Chrysanthemum. Scientia Agricultura Sinica, 2017, 50(9): 1684-1693.
郭芸珲, 于媛媛, 温立柱, 等. 硝态氮影响菊花根系形态结构变化的分子基础. 中国农业科学, 2017, 50(9): 1684-1693.
[20] Xing Y, Sun Z D, Chen L, et al. Effect of nitrogen form on root growth and C and N accumulation of flue-cured tobacco seedlings. Chinese Tobacco Science, 2015, 36(5): 13-18.
邢瑶, 孙泽东, 陈乐, 等. 氮素形态对烟苗根系生长及碳、氮积累的影响. 中国烟草科学, 2015, 36(5): 13-18.
[21] Zheng Z C, Li T X, Zeng F F, et al. Accumulation characteristics of and removal of nitrogen and phosphorus from livestock wastewater by Polygonum hydropiper. Agricultural Water Management, 2013, 117: 19-25.
[22] Zuo H J.Study on N accumulation and physiological characteristics of mining ecotype of Polygonum hydropiper at different N treatment. Chengdu: Sichuan Agricultural University, 2016.
左洪菊. 不同氮处理下矿山生态型水蓼氮积累与生理特性研究. 成都: 四川农业大学, 2016.
[23] Lu R K.Analytical methods of soil and agrochemistry. Beijing: Chinese Agricultural Science and Technology Press, 2000.
鲁如坤, 农业化学分析. 北京: 中国农业科学出版社, 2000.
[24] Luo J, Zhou J J.Growth performance, photosynthesis, and root characteristics are associated with nitrogen use efficiency in six poplar species. Environmental and Experimental Botany, 2019, 164: 40-51.
[25] Cui H Y, Hu F L, Fang Z S, et al. Effect of different nitrogen level on root morphology and utilization of oil flax. Chinese Journal of Oil Crop Sciences, 2015, 37(5): 694-701.
崔红艳, 胡发龙, 方子森, 等. 不同施氮水平对胡麻根系形态和氮素利用的影响. 中国油料作物学报, 2015, 37(5): 694-701.
[26] Xu G W, Lu D K, Wang H Z, et al. Morphological and physiological traits of rice roots and their relationships to yield and nitrogen utilization as influenced by irrigation regime and nitrogen rate. Agricultural Water Management, 2018, 203(30): 385-394.
[27] Song Y Z, Yang M J, Qin B Q.Physiological response of Vallisneria natans to nitrogen and phosphorus contents in eutrophic waterbody. Environmental Science, 2011, 32(9): 2569-2575.
宋玉芝, 杨美玖, 秦伯强. 苦草对富营养化水体中氮磷营养盐的生理响应. 环境科学, 2011, 32(9): 2569-2575.
[28] Liu X D, Li J, Gong Y F, et al. Purification of eutrophic water by five aqua-cultured plants. Chinese Journal of Environmental Engineering, 2013, 7(7): 2607-2612.
刘晓丹, 李军, 龚一富, 等. 5种水培植物对富营养化水体的净化能力. 环境工程学报, 2013, 7(7): 2607-2612.
[29] Wang Q B, Zhang J F, Chen G C, et al. Nitrogen absorption/distribution and physiological characteristics of Salix matsudana seedlings grown in hydroponic treatment. Acta Ecologica Sinica, 2015, 35(16): 5364-5373.
汪庆兵, 张建锋, 陈光才, 等. 不同氮处理下速生柳对水体氮的吸收、分配及生理响应. 生态学报, 2015, 35(16): 5364-5373.
[30] Wang J, Wang X L.Effects of leaf cytokinin induced by root nitrate absorption on the continuous regrowth of defoliated ryegrass. Pratacultural Science, 2013, 30(3): 409-417.
王佳, 王晓凌. 硝态氮对去叶多花黑麦草再生性的影响及其调控机制. 草业科学, 2013, 30(3): 409-417.
[31] Zhang S Y, Chu G X, Liang Y C.Effects of enhancing ammonium nutrition on the nitrogenous metabolisms of cotton seedlings grown hydroponically under low-temperature stress. Journal of Plant Nutrition and Fertilizer, 2017, 23(4): 983-990.
张淑英, 褚贵新, 梁永超. 增铵营养对低温胁迫下棉花幼苗氮代谢的影响. 植物营养与肥料学报, 2017, 23(4): 983-990.
[32] Cao X C, Li X Y, Zhu L F,et al. Effects of different ratios of exogenous glycine, nitrate and ammonium on growth and quality of pakchoi(Brassica chinensis L.). Journal of Agro-Environment Science, 2015, 34(10): 1846-1852.
曹小闯, 李晓艳, 朱练峰,等. 外源甘氨酸态氮、硝态氮和铵态氮的浓度配比对小白菜生长和品质的影响. 农业环境科学学报, 2015, 34(10): 1846-1852.
[33] Yu J L, Zhang Z H, Song H X, et al. Progress research on physiological mechanism of nitrogen utilization in plants. Chinese Agricultural Science Bulletin, 2014, 30(12): 19-23.
余佳玲, 张振华, 宋海星, 等. 作物氮素利用生理机制研究进展. 中国农学通报, 2014, 30(12): 19-23.
[34] Jiang L L, Han L S, Han X R, et al. Effects of nitrogen on growth, root morphological traits, nitrogen uptake and utilization efficiency of maize seedlings. Journal of Plant Nutrition and Fertilizer, 2011, 17(1): 247-253.
姜琳琳, 韩立思, 韩晓日, 等. 氮素对玉米幼苗生长、根系形态及氮素吸收利用效率的影响. 植物营养与肥料学报, 2011, 17(1): 247-253.
[35] Li Q, Li B H, Kronzucker H J, et al. Root growth inhibition by $N_4^+$ efflux and GMPase activity. Plant Cell & Environment, 2010, 33(9): 1529-1542.
[36] Zhou Q Y.Ammonium nitrogen tolerance research on submerged plant-Myriophyllum aguaticum. Zhengzhou: Zhengzhou University, 2017.
周清扬. 绿狐尾藻耐铵态氮性能的研究. 郑州: 郑州大学, 2017.
[37] Liang Y, Zhao X Y, Jones A M, et al. G proteins sculp root architecture in response to nitrogen in rice and Arabidopsis. Plant Science, 2018, 274: 129-136.
[38] Xing Y, Ma X H.Effect of different nitrogen forms on tobacco seedling root growth and nitrogen utilization. Acta Tobacaria Sinica, 2016, 22(4): 52-61.
邢瑶, 马兴华. 氮素形态对烟苗根系生长及氮素利用的影响. 中国烟草学报, 2016, 22(4): 52-61.
[39] Walch-Liu P, Forde B G.Nitrate signalling mediated by the NRT1.1 nitrate transporter antagonises L-glutamate-induced changes in root architecture. Plant Journal, 2008, 54(5): 820-828.
[40] Piwpuan N, Jampeetong A, Brix H.Ammonium tolerance and toxicity of Actinoscirpus grossus-a candidate species for use in tropical constructed wetland systems. Ecotoxicology & Environmental Safety, 2014, 107(9): 319-328.