Scientia Agricultura Sinica ›› 2016, Vol. 49 ›› Issue (14): 2737-2750.doi: 10.3864/j.issn.0578-1752.2016.14.008

• SOIL & FERTILIZER·WATER-SAVING IRRIGATION·AGROECOLOGY & ENVIRONMENT • Previous Articles     Next Articles

Effects of Partial Water and Nitrogen Resupplies on Maize Root Nitrogen Absorbing Capacity and Distribution

NIU Xiao-li, HU Tian-tian, ZHANG Fu-cang, WANG Li, LIU Jie, FENG Pu-yu, YANG Shuo-huan, SONG Xue   

  1. College of Water Resources and Architectural Engineering/Key Laboratory of Agricultural Soil and Water Engineering in Arid and Semiarid Areas of Ministry of Education/Institute of Water-saving Agriculture in Arid Areas of China, Northwest A&F University, Yangling 712100, Shaanxi
  • Received:2016-01-22 Online:2016-07-16 Published:2016-07-16

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Abstract: 【Objective】Water and nitrogen (N) resupplies can significantly enhance root absorbing capacity. Partial water and N supplies can stimulate the compensation effect of root absorbing capacity at the non-stressed sub-root zone. The objective of this study is to identify the dynamics and influencing factors of the compensation effect of maize roots (Zea mays L. hybrid cv. Aoyu No. 3007) N absorbing capacity under partial resupply after previous water and N stresses.【Method】With the split-root technology, a hydroponic experiment was conducted to analyze the root zone water and N stresses, where the water stress was stimulated by the osmotic potential of a nutrient solution (PEG 6000) and N stress was stimulated by different N levels. There were three water and N stress levels, i.e., mild, moderate, severe water and N stresses and a control treatment (CK, both sides of the root zone supplied with sufficient water and N). The root N inflow rate, N content and accumulation of each root zone were measured at 0, 1, 3, 5, 7 and 9 d of resupplying water and N in half of root-zone 6 d after water and N stresses.【Result】Compared with non-stressed sub-root, the root N inflow rate, N content and accumulation in stressed sub-root were significantly decreased under partial resupply after water and N stresses. During 1-3 days after treatment (DAT), the root N inflow rate in stressed sub-root reduced by 38.2% and 48.7%, respectively, and was 84.9% and 86.4% lower than that in non-stressed sub-root. For non-stressed sub-root, partial water and N resupplies significantly enhanced the root N inflow rate compared with previous water and N stresses during 0-1 DAT. When water and N stresses did not exceed moderate stress level, partial water and N resupplies significantly increased root N inflow rate compared with control treatment during 0-1 and 7-9 DAT. However, during 3-7 DAT, the root N inflow rate was similar to or lowers than control treatment. The root N content and accumulation in mild and moderate stress treatments returned to control level at 1 and 5 DAT, respectively, which resulted in similar plant N use efficiency to control treatment. Moreover, partial water and N resupplies significantly increased the percentage of 15N-fertilizer-N allocation in shoot compared with control treatment, and the increment reduced with the severity of water and N stresses. For non-stressed sub-root, the percentage of 15N-fertilizer-N allocation showed a reverse trend. For mild stress treatment, the percentage of 15N-fertilizer-N allocation of stressed sub-root had no significant difference compared with that of control treatment. The percentage of 15N-fertilizer-N allocation of stressed sub-root at moderate and severe stress treatments was significantly higher than that of control treatment, at 3-9 DAT, although there was no significant difference between moderate and severe stress treatments.【Conclusion】When previous water and N stresses did not exceed moderate stress level, the compensation effect of root N absorbing capacity in the non-stressed sub-root can be effectively stimulated by partial water and N resupplies. The compensation effect was affected by the severity and duration of the water and N stresses. Percentage of 15N-fertilizer-N allocation in different organs is closely related to the severity and duration of the water an N stresses. Thus, the above conclusion provides theoretical supports for regulating the interaction between plants and soil environment and making use of the potential plant response to soil water and nutrient stresses.

Key words:  partial water and nitrogen resupplies, stress severity, duration of partial resupply, root N inflow rate, root compensatory effect, maize

[1]    Cain M L, Subler S, Evans J P, Fortin M J. Sampling spatial and temporal variation in soil nitrogen availability. Oecologia, 1999, 118(4): 397-404.
[2]    Fransen B, Blijjenberg J, de kroon H. Root morphological and physiological plasticity of perennial grass species and the exploitation of spatial and temporal heterogeneous nutrient patches. Plant and Soil, 1999, 211(2): 179-189.
[3]    Prasolova N V, Xu Z H, Saffigna P G, Dieters M J. Spatial-temporal variability of soil moisture, nitrogen availability indices and other chemical properties in hoop pine (Araucaria cunninghamii) plantations of subtropical Australia. Forest Ecology and Management, 2000, 136(1/3): 1-10.
[4]    Cahill Jr JF, Mcnickle G G. The behavioral ecology of nutrient foraging by plants. Annual Review of Ecology, Evolution, and Systematics, 2011, 42: 289-311.
[5]    Wang L, Mou P P, Jones R H. Nutrient foraging via physiological and morphological plasticity in three plant species. Canadian Journal of Forest Research, 2006, 36(1): 164-173.
[6]    Mou P, Jones R, Tan Z, Bao Z, Chen H. Morphological and physiological plasticity of plant roots when nutrients are both spatially and temporally heterogeneous. Plant and Soil, 2013, 364(1/2): 373-384.
[7]    Hu T T, Kang S Z, Li F S, Zhang J H. Effects of partial root-zone irrigation on the nitrogen absorption and utilization of maize. Agricultural Water Management, 2009, 96(2): 208-214.
[8]    胡田田, 康绍忠. 局部灌水方式对玉米不同根区土根系统水分传导的影响. 农业工程学报, 2007, 23(2): 11-16.
Hu T T, Kang S Z. Effects of localized irrigation model on hydraulic conductivity in soil-root system for different root-zones of maize. Transactions of the Chinese Society of Agricultural Engineering, 2007, 23(2): 11-16. (in Chinese)
[9]    Hodge A. The plastic plant: root responses to heterogeneous supplies of nutrients. New Phytologist, 2004, 162(1): 9-24.
[10]   Robinson D. The responses of plants to non–uniform supplies of nutrients. New Phytologist, 1994, 127(4): 635-674.
[11]   Yano K, Kume T. Root morphological plasticity for heterogeneous phosphorus supply in Zea mays L. Plant Production Science, 2005, 8(4): 427-432.
[12]   Li H, Ma Q, Li H, Zhang F, Rengel Z, Shen J. Root morphological responses to localized nutrient supply differ among crop species with contrasting root traits. Plant and Soil, 2014, 376(1/2): 151-163.
[13]   Burns I G. Short- and long-term effects of a change in the spatial distribution of nitrate in the root zone on N uptake, growth and root development of young lettuce plants. Plant, cell & environment, 1991, 14(1): 21-33.
[14]   Van Vuuren M, Robinson D, Griffiths B. Nutrient inflow and root proliferation during the exploitation of a temporally and spatially discrete source of nitrogen in soil. Plant and Soil, 1996, 178(2): 185-192.
[15]   王庆成, 程云环. 土壤养分空间异质性与植物根系的觅食反应. 应用生态学报, 2004, 15(6): 1063-1068.
Wang Q C, Cheng Y H. Response of fine roots to soil nutrient spatial heterogeneity. Chinese Journal of Applied Ecology, 2004, 15(6): 1063-1068. (in Chinese)
[16]   Fitter A H. Architecture and biomass allocation as components of the plastic response of root systems to soil heterogeneity//Caldwell M M, Pearcy R W. Exploitation of environmental heterogeneity by plants. Academic, San Diego, 1994, 305-323.
[17]   Hodge A, Robinson D, Griffiths B S, Fitter A H. Nitrogen capture by plants grown in N-rich organic patches of contrasting size and strength. Journal of Experimental Botany, 1999, 50(336): 1243-1252.
[18]   刘展鹏. 模拟干旱胁迫及复水条件下玉米生长补偿效应[D]. 南京: 河海大学, 2007.
Liu Z P. Research on compensatory effects of growth under simulated water stress and rewatering on maize[D]. Nanjing: Hohai University, 2007. (in Chinese)
[19]   牛晓丽, 胡田田, 刘亭亭, 吴雪, 冯璞玉, 刘杰, 李康, 张富仓. 适度局部水分胁迫提高玉米根系吸水能力. 农业工程学报, 2014, 30(22): 80-86.
Niu X L, Hu T T, Liu T T, Wu X, Feng P Y, Liu J, Zhang F C. Appropriate partial water stress improves maize root absorbing capacity. Transactions of the Chinese Society of Agricultural Engineering, 2014, 30(22): 80-86. (in Chinese)
[20]   Sampathkumar T, Pandian B J, Mahimairaja S. Soil moisture distribution and root characters as influenced by deficit irrigation through drip system in cotton–maize cropping sequence. Agricultural Water Management, 2012, 103(103): 43-53.
[21]   Barber S A, WALKER J M, VASEY E H. Mechanisms for the movement of plant nutrients from the soil & fertilizer to the plant root. Journal of Agricultural and Food Chemistry, 1963, 11(3): 204-207.
[22]   Gloser V, Zwieniecki M A, Orians C M, Holbrook N M. Dynamic changes in root hydraulic properties in response to nitrate availability. Journal of Experimental Botany, 2007, 58(10): 2409-2415.
[23]   Wijesinghe D, Hutchings M. The effects of spatial scale of environmental heterogeneity on the growth of a clonal plant: an experimental study with Glechoma hederacea. Journal of Ecology, 1997, 85(1): 17-28.
[24]   Jackson R B, Caldwell M M. Kinetic responses of Pseudoroegneria roots to localized soil enrichment. Plant and Soil, 1991, 138(2): 231-238.
[25]   Kembel S W, Kroon H D, Cahill J F, Mommer L. Improving the scale and precision of hypotheses to explain root foraging ability. Annals of Botany, 2008, 101(9): 1295-1301.
[26]   De la rocha C L, Terbrüggen A, Hohn S, Völker     C. Response to and recovery from nitrogen and silicon starvation  in Thalassiosira weissflogii: growth rates, nutrient uptake and C, Si and N content per cell. Marine Ecology Progress Series, 2010, 412: 57-68.
[27]   Niwa K, Harada K. Physiological responses to nitrogen deficiency and resupply in different blade portions of Pyropia yezoensis f. narawaensis (Bangiales, Rhodophyta). Journal of Experimental Marine Biology and Ecology, 2013, 439(439): 113-118.
[28]   李瑞, 胡田田, 牛晓丽, 代顺冬, 王旭东. 局部水分胁迫对玉米根系生长的影响. 中国生态农业学报, 2013, 21(11): 1371-1376.
Li R, Hu T T, Niu X L, Dai S D, Wang X D. Effect of partial root-zone drought stress on root growth of maize. Chinese Jounal of Eco-Agriculture, 2013, 21(11): 1371-1376. (in Chinese)
[29]   李瑞, 胡田田, 牛晓丽, 代顺冬, 王旭东. 局部水分胁迫对玉米根系导水率的影响. 西北农林科技大学学报: 自然科学版, 2014, 42(2): 61-64.
Li R, Hu T T, Niu X L, Dai S D, Wang X D. Effect of partial water stress on root hydraulic conductivity of maize. Journal of Northwest A&F University: Nature Science Edition, 2014, 42(2): 61-64. (in Chinese)
[30]   Niu X L, Hu T T, Zhang F C, Feng P Y. Severity and duration of osmotic stress on partial root system: effects on root hydraulic conductance and root growth. Plant Growth Regulation, 2016: 79(2): 177-186.
[31]   Carvajal M, Cooke D T, Clarkson D T. Responses of wheat plants to nutrient deprivation may involve the regulation of water-channel function. Planta, 1996, 199(3): 372-381.
[32]   Li H B, Zhang F S, Shen J B. Contribution of root proliferation in nutrient-rich soil patches to nutrient uptake and growth of maize. Pedosphere, 2012, 22(6): 776-784.
[33]   Hooymans J. The influence of the transpiration rate on uptake and transport of potassium ions in barley plants. Planta, 1969, 88(4): 369-371.
[34]   Greenway H, Klepper B. Phosphorus transport to the xylem and its regulation by water flow. Planta, 1968, 83(2): 119-136.
[35]   胡田田, 康绍忠, 李志军, 张富仓. 局部湿润方式下玉米对不同根区氮素的吸收与分配. 植物营养与肥料学报, 2009(1): 105-113.
Hu T T, Kang S Z, Li Z J, Zhang F C. Uptake and allocation of nitrogen from different root zones of maize under local irrigation. Plant nutrition and Fertilizer Science, 2009(1): 105-113. (in Chinese)
[36]   梁爱华, 马富裕, 梁宗锁, 慕自新. 旱后复水激发玉米根系功能补偿效应的生理学机制研究. 西北农林科技大学学报: 自然科学版, 2008, 36(4): 58-64.
Liang A H, Ma F Y, Liang Z S, Mu Z X. Studies on the physiological mechanism of functional compensation effect in maize root system induced by rewatering after draught stress. Journal of Northwest A&F University: Nature Science Edition, 2008, 36(4): 58-64. (in Chinese)
[37]   Young E B, Berges J A, Dring M J. Physiological responses of intertidal marine brown algae to nitrogen deprivation and resupply of nitrate and ammonium. Plant Physiology, 2009, 135(4): 400-411.
[38]   Richard-molard C, Krapp A, Brun F, Ney B, Daniel- vedele F, Chaillou S. Plant response to nitrate starvation is determined by N storage capacity matched by nitrate uptake capacity in two Arabidopsis genotypes. Journal of Experimental Botany, 2008, 59(4): 779-791.
[39]   Asseng S, Ritchie J, Smucker A, Robertson M. Root growth and water uptake during water deficit and recovering in wheat. Plant and Soil, 1998, 201(2): 265-273.
[40]   Siemens J A, Zwiazek J J. Effects of water deficit stress and recovery on the root water relations of trembling aspen (Populus tremuloides) seedlings. Plant Science, 2003, 165(1): 113-120.
[41]   Poni S, Tagliavini M, Neri D, Scudellari D, Toselli M. Influence of root pruning and water stress on growth and physiological factors of potted apple, grape, peach and pear trees. Scientia Horticulturae, 1992, 52(3): 223-236.
[42]   Fernandes A M, Soratto R P, Gonsales J R. Root morphology and phosphorus uptake by potato cultivars grown under deficient and sufficient phosphorus supply. Scientia Horticulturae, 2014, 180: 190-198.
[43]   Bassirirad H, Caldwell M M, Bilbrough C. Effects of soil temperature and nitrogen status on kinetics of 15NO3- uptake by roots of field-grown Agropyron desertorum (Fisch. ex Link) Schult. New Phytologist, 1993, 123(3): 485-489.
[44]   Grossman J D, Rice K J. Evolution of root plasticity responses to variation in soil nutrient distribution and concentration. Evolutionary Applications, 2012, 5(8): 850-857.
[45]   Lainé P, Ourry A, Boucaud J. Shoot control of nitrate uptake rates by roots of Brassica napus L.: Effects of localized nitrate supply. Planta, 1995, 196(1): 77-83.
[46]   Agrell D, Oscarson P, Larsson C M. Translocation of N to and from barley roots: its dependence on local nitrate supply in split-root culture. Physiologia Plantarum, 1994, (3): 467-474.
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