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作物学报 ›› 2010, Vol. 36 ›› Issue (2): 321-326.doi: 10.3724/SP.J.1006.2010.00321

• 耕作栽培·生理生化 • 上一篇    下一篇

油菜生育期氮肥素的吸收、分配及转运特性

张振华1,宋海星1,*,刘强1,荣湘民1,谢桂先1,彭建伟1,张玉平1,官春云2,陈社员2   

  1. 1 湖南农业大学资源环境学院,湖南长沙 410128;2 国家油料改良中心湖南分中心,湖南长沙 410128
  • 收稿日期:2009-04-01 修回日期:2009-10-01 出版日期:2010-02-10 网络出版日期:2009-12-21
  • 通讯作者: 宋海星, E-mail: haixingsong@yahoo.com.cn
  • 基金资助:
    本研究由国家自然科学基金项目(30971860),湖南省自然科学基金重点项目(07JJ3074),国家油菜产业技术体系建设项目(00509)和国家高技术研究发展计划(863计划)项目(2006BAD21B030资助。

Absorption, Distribution, and Translocation of Nitrogen at Growth Stages in Oilseed Rape

ZHANG Zhen-Hua1, SONG Hai-Xing1,*, LIU Qiang1, RONG Xiang-Min1, XIE Gui-Xian1,PENG Jian-Wei1,ZHANG Yu-Ping1,GUAN Chun-Yun2,CHEN She-Yuan2
  

  1. 1 College of Resource and Environment, Hunan Agricultural University, Changsha 410128, China; 2 National Center of Oilseed Crops Improvement, Hunan Branch, Changsha 410128, China
  • Received:2009-04-01 Revised:2009-10-01 Published:2010-02-10 Published online:2009-12-21
  • Contact: SONG Hai-Xing, E-mail: haixingsong@yahoo.com.cn

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1992

被引次数

15

摘要:

Hoagland完全营养液的砂培条件下,采用15N示踪方法,研究了两个冬油菜品种不同生育期吸收的氮素在体内的分配、转运及损失情况。结果表明(两个品种平均值)83.5%苗期吸收的氮素和67.3%蕾薹期吸收的氮素分布在叶片中;79.1%开花期吸收的氮素分布在叶片和茎中,其中叶片中分布的氮占42.8%;而角果发育期吸收的氮素有42.4%直接分配到角果中,此时角果已成为氮素直接分配的比例最大的器官。苗期、蕾薹期、开花期和角果发育期吸收的氮素从营养器官向生殖器官的转运比例分别为34.4%44.3%41.2%31.7%,单株转运量分别为203.2325.8218.082.0 mg。在籽粒全氮中转运氮占65.1%,其中蕾薹期吸收后转运的氮素所占比例最大,为25.8%,其次是开花期和苗期,分别为16.9%15.9%,角果发育期比例最小,为6.4%。以上4个生育期吸收的氮素损失比例分别为24.0%10.5%11.7%7.3%,单株损失量分别为141.679.243.216.2 mg

关键词: 油菜, 氮素吸收, 氮素分配, 氮素转运

Abstract:

The differences of concentration and distribution of nitrogen in crop depend on organs and growth stages, and nitrogen redistribution in different organs will be occurred at different stages; these differences are related to the transfer of growth center. Consequently, the high crop yield depends not only on the high amount of nitrogen absorption, but also on the high efficiency of nitrogen redistribution. The objective of this study was to reveal the law of nitrogen absorption, distribution, and translocation in oilseed rape at different growth stages using two winter oilseed rape cultivars with the 15N labeling method in sand culture under Hoagland complete nutrient solution conditions. The results (average value from the two cultivars) indicated that 83.5% of nitrogen absorbed at the seedling stage, and 67.3% of nitrogen absorbed at the stem elongation stage, were distributed to leaves; 79.1% of the nitrogen absorbed at flowering stage was contained in leaves and stems, with 42.8% of it in the leaves. However, 42% of the nitrogen absorbed at siliquing stage was distributed to siliquae which is just the organ directly distributed the highest proportion of nitrogen absorbed at this stage. The nitrogen absorbed at four growth stages [seedling, stem elongation, flowering, and siliquing] translocated from the vegetative to the reproductive organs at 34.4%, 44.3%, 41.2%, and 31.7%, i.e. 203.2, 325.8, 218.0, and 82.0 mg plant-1, respectively. The translocated nitrogen from vegetative organs to the total nitrogen in seed accounted for 65.1%; among with 25.8% absorbed at the stem elongation stage, 16.9% absorbed at flowering stage, 15.9% absorbed at seedling stage, and 6.4% absorbed at siliquing stage, respectively. The proportion of nitrogen lost, after being absorbed at the four growth stages, was 24.0%, 10.5%, 11.7%, and 7.3 %, i.e. 141.6, 79.2, 43.2, and 16.2 mg plant-1, respectively. To sum up, nitrogen absorbed by roots at the earlier growth stages in oilseed rape was mainly translocated to leaves first, and then to the reproductive organ at the later growth stages.

Key words: Oilseed rape, Nitrogen absorption, Nitrogen distribution, Nitrogen translocation

[1] 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 Physiol, 2003, 133: 1959–1967

[2] Gallais A, Floriot M, Pommel B, Prioul J L, Hirel B, Andrieu B, Coque M, Quilleré I. Carbon and nitrogen allocation and grain filling in three maize hybrids differing in leaf senescence. Eur J Agron, 2006, 24: 203–211

[3] Dong G-C(董桂春), Wang Y-L(王余龙), Zhou J(周娟), Zhang B(张彪), Zhang C-S(张传胜), Zhang Y-F(张岳芳), Yang L-X(杨连新), Huang J-H(黄建晔). Difference of nitrogen accumulation and translocation in conventional indica rice cultivars with different nitrogen use efficiency for grain output. Acta Agron Sin (作物学报), 2009, 35(1): 149–155 (in Chinese with English abstract)

[4] Zhang Y-L(张永丽), Yu Z-W(于振文). Effects of irrigation amount on nitrogen uptake, distribution, use, and grain yield and quality in wheat. Acta Agron Sin (作物学报), 2008, 34(5): 870–878 (in Chinese with English abstract)

[5] Peoples M B, Dalling M J. The Interplay between Protelysis and Amino Acid Metabolism during Senescence and Nitrogen Reallocation. In: Nooden L D, Leopold A C eds. Senescence Aging in Plant. San Diego: Academic Press, 1988. pp 181–217

[6] Thomas H. Enzymes of nitrogen mobilization in detached leaves of Lolium temulentum during senescence. Planta, 1978, 142: 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. Ann Bot, 2005, 95: 853–861

[8] Zhang Y-H(张耀鸿), Wu J(吴洁), Zhang Y-L(张亚丽), Wang D-S(王东升), Shen Q-R(沈其荣). Genotypic variation of nitrogen accumulation and translocation in japonica rice (Oryza sativa L.)cultivars with different height. J Nanjing Agric Univ (南京农业大学学报), 2006, 29(2): 71–74 (in Chinese with English abstract)

[9] Zhang Y-H(张耀鸿), Zhang Y-L(张亚丽), Huang Q-W(黄启为), Xu Y-C(徐阳春), Shen Q-R(沈其荣). Effects of different nitrogen application rates on grain yields and nitrogen uptake and utilization by different rice cultivars. Plant Nutr Fert Sci (植物营养与肥料学报), 2006, 12(5): 616–621 (in Chinese with English abstract)

[10] 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. Can J Plant Sci, 2003, 83(4): 699–707

[11] Gao J-F(高俊凤). Experimental Technique of Plant Physiology (植物生理学实验技术). Xi’an: World Publishing Company, 2000. pp 86–88 (in Chinese)

[12] Liu H-L(刘后利). Practical Cultivation in Oilseed Rape(实用油菜栽培学). Shanghai: Shanghai Scientific and Technical Publishers, 1987. pp 128-143, 236–237 (in Chinese)

[13] Séverine S, Nathalie M J, Christian J, Judith B, Christophe S. Dynamics of exogenous nitrogen partitioning and nitrogen remobilization from vegetative organs in pea revealed by 15N in vivo labeling throughout. Plant Physiol, 2005, 137: 1463–1473

[14] 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. Aust J Agric Res, 1995, 46: 507–518

[15] 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 Res, 2007, 102: 22–32

[16] Rossato L, Le Dantec C, Laine P, Ourry A. Nitrogen storage and remobilization in Brassica napus L. during the growth cycle: identification, characterization and immunolocalization of a putative taproot storage glycoprotein. J Exp Bot, 2002, 53: 265–275
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