氮高效利用基因型大麦氮素转移及氮形态组分特征

doi:10.3864/j.issn.0578-1752.2015.06.11

Abstract

Abstract: 【Objective】Nitrogen plays important roles in promoting plant growth and development. The objective of this study is to clarify the characteristics of distribution and transportation for barley nitrogen efficiency genotype, and to provide a theoretical basis for efficient nitrogen management and high-yield cultivation of good varieties.【Method】In this study, a soil culture pot experiment was conducted with barley genotype of high nitrogen utilization efficiency (DH61, DH121+) and low nitrogen utilization efficiency (DH80). Four nitrogen treatments were designed, including no nitrogen, low nitrogen (125 mgN·kg^-1 soil), normal nitrogen (250 mgN·kg^-1 soil) and high nitrogen (375 mgN·kg^-1 soil), respectively. The purpose was analysis grain yield, aboveground biomass , the characteristics of nitrogen transportation and fractions in different organs of barley with high nitrogen utilization efficiency (NUE) at late growth stage.【Result】When applied nitrogen reduced, the amount of aboveground biomass and grain yield were decreased among all tested cultivars. Under the same nitrogen application level, the amounts of biomass and grain yield of high NUE genotype were higher than that of low NUE genotype. The grain yield of high NUE genotype was, respectively, 1.96 times and 2.03 times, 2.10 times and 2.37 times higher than that of low NUE genotype in no nitrogen and low nitrogen treatments. Nitrogen concentration of high and low NUE genotype had no significant difference in no nitrogen and low nitrogen treatments at flowering and grain filling stages. High NUE genotype had a strong ability in dry matter forming. The amount of nitrogen accumulation of high NUE genotype was higher than that of low NUE genotype. And the ratio of nitrogen accumulation during the whole growth period of high NUE genotype was higher than that of low NUE genotype before flowering stage. Nitrogen accumulation of high NUE genotype was 1.48 times, 1.36 times and 1.37 times higher than that of low NUE in low nitrogen (125 mgN·kg^-1 soil), normal nitrogen (250 mgN·kg^-1 soil), and high nitrogen (375 mgN·kg^-1 soil) treatments. Adequate nitrogen accumulation of high NUE before flowering had laid a foundation for early filling of seeds. When applied nitrogen reduced, nitrogen translocation showed a single peak curve, nitrogen transfer rate and the amount of nitrogen transported to grain contribution rate gradually declined, over fertilization of nitrogen fertilizer is not conducive to grain transport. For high NUE genotype(DH61,DH121+), nitrogen in grain mainly relied on nitrogen translocation from vegetative organs, which accounted for 35.06%, 40.06% and 76.37%, 81.72% in no nitrogen and low nitrogen treatments, respectively; but for low NUE genotype(DH80), nitrogen in grain mainly relied on nitrogen uptake by root at reproductive stage which accounted for 68.20% and 34.84%. Higher transfer efficiency associated with different forms of nitrogen in plant composition and change. In different nitrogen treatments, assimilable nitrogen content in stalk and leaf increased, functional nitrogen content changes smoothly and structural nitrogen content was reduced from flowering to filling, while assimilable nitrogen content increased, and structural nitrogen content slowly declined in grain. High NUE showed a strong decline and nitrogen transport capacity of the structural nitrogen content. The structural nitrogen content of high NUE in stem and leaf decreased by 49.65% and 62.54% in low nitrogen treatment from flowering to filling, and it decreased by 66.54% and 28.17% from heading to maturity.【Conclusion】Grain nitrogen content of high NUE in stems and leaves is decided by the structural nitrogen content decomposition and transformation after flowering, and structural nitrogen recycling in vegetative organs conducive to nitrogen use efficiency.

Key words: barley, high nitrogen utilization efficiency genotype, nitrogen transportation, fractions

HUANG Yi, LI Ting-xuan, ZHANG Xi-zhou, JI Lin, WU Yi-po. Characteristics of Nitrogen Transportation and Fractions in Different Organs of Barley Genotype with High Nitrogen Utilization Efficiency[J].Scientia Agricultura Sinica, 2015, 48(6): 1151-1161.

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References

[1] Schiltz S, Munier J N, Jeudy C, Burstin J, Salon C. Dynamics of exogenous nitrogen partitioning and nitrogen remobilization from vegetative organs in pea revealed by ¹⁵N in vivo labeling throughout seed filling. Plant Physiology, 2005, 137(4): 1463-1473.

[2] Martre P, Porter J R, Jamieson P D, Triboï E. Modeling grain nitrogen accumulation and protein composition to understand the sink/source regulations of nitrogen remobilization for wheat. Plant Physiology, 2003, 133(4): 1959-1967.

[3] Pommel B, Gallais A, Coque M, Quilleré I, Hirel B, Prioul J L, Andrieu B, Floriot M. Carbon and nitrogen allocation and grain filling in three maize hybrids differing in leaf senescence. European Journal of Agronomy, 2006, 24(3): 203-211.

[4] 董桂春, 王余龙, 周娟, 张彪, 张传胜, 张岳芳, 杨连新, 黄建晔. 不同氮素籽粒生产效率类型籼稻品种氮素分配与运转的差异. 作物学报, 2009, 35(1): 149-155.

Dong G C, Wang Y L, Zhou J, Zhang B, Zhang C S, Zhang Y F, Yang L X, Huang J Y. Difference of nitrogen accumulation and translocation in conventional Indica rice cultivars with different nitrogen use efficiency for grain output. Acta Agronomica Sinica, 2009, 35(1): 149-155. (in Chinese)

[5] 张永丽, 于振文. 灌水量对小麦氮素吸收、分配、利用及产量与品质的影响. 作物学报, 2008, 34(5): 870-878.

Zhang Y L, Yu Z W. Effects of irrigation amount on nitrogen uptake, distribution, use, and grain yield and quality in wheat. Acta Agronomica Sinica, 2008, 34(5): 870-878. (in Chinese)

[6] Thomas H. Enzymes of nitrogen mobilization in detached leaves of Lolium temulentum during senescence. Planta, 1978, 142(2): 161-169.

[7] Malagoli P, Laine P, Rossato L, Ourry A. Dynamics of nitrogen uptake and mobilization in field-grown winter oilseed rape(Brassica napus) from stem extension to harvest. Annals of Botany, 2005, 95: 853-861.

[8] 霍中洋, 杨雄, 张洪程, 葛梦婕, 马群, 李敏, 戴其根, 许轲, 魏海燕, 李国业, 朱聪聪, 王亚江, 颜希亭. 不同氮肥群体最高生产力水稻品种各器官的干物质和氮素的积累与转运. 植物营养与肥料学报, 2012, 18(5): 1035-1045.

Huo Z Y, Yang X, Zhang H C, Ge M J, Ma Q, Li M, Dai Q G, Xu K, Wei H Y, Li G Y, Zhu C C, Wang Y J, Yan X T. Accumulation and translocation of dry matter and nitrogen nutrition in organs of rice cultivars with different productivity levels. Plant Nutrition and Fertilizer Science, 2012, 18(5): 1035-1045. (in Chinese)

[9] Wang H, McCaig T N, Depauw R M, Clerke F R, Clerke J M. Physiological characteristics of recent Canada western red spring wheat cultivars: Components of grain nitrogen yield. Canadian Journal of Plant Science, 2003, 83(4): 699-707.

[10] 杨铁钢, 戴廷波, 姜东, 荆奇, 曹卫星. 不同施氮水平下两种品质类型小麦植株氮素形态的变化特征. 作物学报, 2007, 33(11): 1763-1770.

Yang T G, Dai T B, Jiang D, Jing Q, Cao W X. Characterizing nitrogen form variations in different organs of two wheat genotypes under three nitrogen rates. Acta Agronomica Sinica, 2007, 33(11): 1763-1770. (in Chinese)

[11] Claver I P, Zhou H M. Enzymatic hydrolysis of defatted wheat germ by proteases and the effect on the functional properties of resulting protein hydrolysates. Journal of Food Biochemistry, 2005, 29(1): 13-26.

[12] Rhodes D I, Stone B A. Proteins in walls of wheat aleurone cells. Journal of Cereal Science, 2002, 36(1): 83-101.

[13] 王月福, 于振文, 李尚霞, 余松烈. 不同施肥水平对不同品种小麦籽粒蛋白质和地上器官游离氨基酸含量的影响. 西北植物学报, 2003, 23(3): 417-421.

Wang Y F, Yu Z W, Li S X, Yu S L. The effects of different fertilization level on grain protein and free amino acid content of organs above ground of different wheat variety. Acta Botanica Boreal-Occidentalia Sinica, 2003, 23(3): 417-421. (in Chinese)

[14] 刚爽, 赵宏伟, 王敬国, 刘化龙, 臧家祥, 高扬. 不同氮肥水平下寒地粳稻器官不同形态氮含量变化特征研究. 植物营养与肥料学报, 2011, 17(2): 276-282.

Gang S, Zhao H W, Wang J G, Liu H L, Zang J X, Gao Y. Effect of nitrogen fertilization rates on the variation characteristic of different nitrogen forms contents in Japonica rice under the cold region. Plant Nutrition and Fertilizer Science, 2011, 17(2): 276-282. (in Chinese)

[15] 鲍士旦. 土壤农化分析. 北京: 中国农业出版社, 2008.

Bao S D. Agricultural Soil Analysis. Beijing: China Agriculture Press, 2008. (in Chinese)

[16] 汤章城. 现代植物生理学实验指南. 北京: 科学出版社, 2004.

Tang Z C. Modern Plant Physiology Laboratory Manual. Beijing: Science Press, 2004. (in Chinese)

[17] 柴彦君, 熊又升, 黄丽, 袁家富, 徐祥玉, 刘晔. 施氮对不同品种冬小麦氮素累积和运转的影响. 西北植物学报, 2010(10): 2040-2046.

Chai Y J, Xiong Y S, Huang L, Yuan J F, Xu X Y, Liu Y. Effects of nitrogen application on nitrogen accumulation, distribution and translocation of different winter wheat varieties. Acta Botanica Boreal-Occidentalia Sinica, 2010(10): 2040-2046. (in Chinese)

[18] 晏娟, 沈其荣, 尹斌. 施氮量对氮高效水稻种质4007的氮素吸收、转运和利用的影响. 土壤学报, 2010, 47(1): 107-114.

Yan J, Shen Q R, Yin B. Effects of nitrogen application tare on uptake, translocation and use of nitrogen by rice germ plasm 4007 high in nitrogen use efficiency. Acta Pedologica Sinica, 2010, 47(1): 107-114. (in Chinese)

[19] 李文娟, 何萍, 高强, 金继运, 侯云鹏, 尹彩霞, 张国辉. 不同氮效率玉米干物质形成及氮素营养特性差异研究. 植物营养与肥料学报, 2010, 16(1): 51-57.

Li W J, He P, Gao Q, Jin J Y, Hou Y P, Yin C X, Zhang G H. Dry matter formation and nitrogen uptake in two maize cultivars differing in nitrogen use efficiency. Plant Nutrition and Fertilizer Science, 2010, 16(1): 51-57. (in Chinese)

[20] Przulj N, Momcilovic V. Genetic variation for dry matter and nitrogen accumulation and translocation in two-rowed spring barley I. Dry matter translocation. European Journal of Agronomy, 2001, 15(4): 241-254.

[21] Xu Z Z, Yu Z W, Wang D, Zhang Y L. Nitrogen accumulation and translocation for winter wheat under different irrigation regimes. Journal of Agronomy and Crop Science, 2005, 191(6): 439-449.

[22] Despo K P, Gagianas A A. Nitrogen and dry matter accumulation, remobilization, and losses for Mediterranean wheat during grain filling. Agronomy Journal, 1991, 83(5): 864-870.

[23] Thomas K, Bertrand H, Emmanuel H, Frédéric D, Jacques L G. In winter wheat (Triticum aestivum L.), post-anthesis nitrogen uptake and remobilization to the grain correlates with agronomic traits and nitrogen physiological markers. Field Crops Research, 2007, 102: 22-32.

[24] Palta J A, Fillery I R P. N application increases pre-anthesis contribution of dry matter to grain yield in wheat grown on a duplex soil. Australian Journal of Agricultural Research, 1995, 46(3): 507-518.

[25] 同延安, 赵营, 赵护兵, 樊红柱. 施氮量对冬小麦氮素吸收、转运及产量的影响. 植物营养与肥料学报, 2007, 13(1): 64-69.

Tong Y A, Zhao Y, Zhao H B, Fan H Z. Effect of nitrogen rates on nitrogen uptake, transformation and the yield of winter wheat. Plant Nutrition and Fertilizer Science, 2007, 13(1): 64-69. (in Chinese)

[26] 莫润秀, 江立庚, 郭立, 胡均铭, 刘开强, 周佳民, 梁天锋, 曾可, 丁成泉. 氮肥运筹对水稻植株不同形态氮素含量的影响. 中国水稻科学, 2010, 24(1): 49-54.

Mo R X, Jiang L G, Guo L, Hu J M, Liu K Q, Zhou J M, Liang T F, Zeng K, Ding C Q. Effects of nitrogen fertilizer management on nitrogen contents in different forms in rice plants. Chinese Journal Rice Science, 2010, 24(1): 49-54. (in Chinese)

[27] 柴彦君, 袁家富, 熊又升, 黄丽, 赵书军, 彭成林, 徐祥玉, 刘晔. 不同冬小麦品种氮效率及其生理差异的研究. 中国土壤与肥料, 2011(1): 21-25.

Chai Y J, Yuan J F, Xiong Y S, Huang L, Zhao S J, Peng C L, Xu X Y, Liu Y. Study on differences of nitrogen efficiency and physiologic of different winter wheat varities. Soils and Fertilizers Sciences in China, 2011(1): 21-25. (in Chinese)

[28] 戢林. 氮高效利用基因型水稻(Oryza sativa)氮素吸收分配特性研究[D]. 成都: 四川农业大学, 2013.

Ji L. Nitrogen absorption and distribution characteristics of rice genotype (Oryza sativa) with high nitrogen utilization efficiency[D]. Chengdu: Sichuan Agricultural University, 2013. (in Chinese)

[29] McNally S F, Hirel B, Gadal P, Mann A F, Stewart G R. Glutamine synthetase of higher plants: Evidence for a specific isoform content related to their possible physiological role and their compartmentation within the leaf. Plant Physiology, 1983, 72(1): 22-25.

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Characteristics of Nitrogen Transportation and Fractions in Different Organs of Barley Genotype with High Nitrogen Utilization Efficiency

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