小麦氮素利用效率的基因型差异及相关特性分析

doi:10.3864/j.issn.0578-1752.2017.14.002

摘要/Abstract

摘要： 【目的】对长江中下游麦区小麦种质进行氮素利用效率基因型差异分析，明确不同种质材料的氮素利用特性，为小麦氮素高效育种及相关分子机理研究奠定基础，同时探讨氮素利用效率与不同生育期性状的相关关系，为建立小麦氮素高效利用的评价指标提供参考。【方法】大田条件下，设置低氮（纯氮62.55 kg·hm^-2）和正常氮（纯氮187.5 kg·hm^-2）2种氮素水平，以主要来自于长江中下游麦区不同时期的小麦种质118份为材料进行氮素利用效率基因型差异分析，通过对苗期地上部干重、分蘖数、叶绿素含量；花期地上部干重、植株氮素浓度、氮素积累量；灌浆期旗叶叶绿素含量；成熟期籽粒产量、茎秆重、籽粒氮素浓度、茎秆氮素浓度、籽粒与茎秆氮素积累量、穗数、穗粒数、千粒重、收获指数和氮素收获指数等22个性状的测定与计算，研究氮素利用效率与不同性状之间的相关关系，并根据材料的氮素利用效率差异对不同种质材料进行划分。【结果】供试小麦材料在2种氮素水平下，各研究性状均存在较大的差异。相关性分析显示植株成熟期茎秆重、地上部生物学产量、收获指数、穗数、植株花期生物学产量、成熟期籽粒氮素积累量、茎秆氮素积累量、氮素收获指数和花期氮素积累量均与籽粒产量呈显著正相关关系；植株氮素生理利用率除了与氮素收获指数显著正相关外，与茎秆重、穗数、籽粒和茎秆氮素浓度及氮素积累量均显著负相关。根据2种氮素水平下产量，供试材料被划分为双高效型、双低效型、高氮高效型和低氮高效型。双高效型和高氮高效型材料对增施氮素反应更为敏感。低氮高效型材料灌浆期旗叶叶绿素含量显著高于其他3种类型，说明氮素胁迫条件下，旗叶持绿性有助于提高植株氮素利用效率。【结论】供试小麦材料氮素利用效率在不同氮素水平下差异显著。不同氮效类型小麦材料对氮素响应不同，高氮高效型对氮素反应敏感，适合于高氮种植；双高效型和低氮高效材料具有耐贫瘠的能力，是氮素高效育种的优质材料。在2种氮素水平下，除了植株成熟期及花期地上部干重、植株氮素积累量等常规指标外，植株穗数也可作为小麦氮素高效利用的评价指标。

关键词: 小麦, 长江中下游, 氮素利用效率, 基因型差异, 相关性分析

Abstract: 【Objective】 The objective of this study was to explore the genetic difference of the nitrogen use efficiency (NUE) of different wheat lines from the middle and lower reaches of Yangtze River and screen out the lines with high NUE, which would provide useful germplasm for wheat high NUE breeding and lay a foundation for uncovering the underlying molecular mechanism. Meanwhile, correlation analysis between NUE and the related traits at different developmental stages of wheat would provide evidences for evaluating the high NUE wheat lines.【Method】The experiment was performed with 118 wheat cultivars mainly from the Yangtze River region in the field conditions by setting low (62.55 pure N kg·hm^-2) and normal (187.5 pure N kg·hm^-2) nitrogen inputs. The genetic variations and correlation analysis were further analyzed by characterizing the traits of dry above-ground mass, tiller number, chlorophyll content at the seedling stage; the dry above-ground mass, plant nitrogen concentration and accumulation at flowering stage; the chlorophyll content at the grain-filling stage; the yield, straw weight, kernel and straw nitrogen concentration and accumulation, spike number, spike length, kernel number per spike, and thousand kernel weight at harvesting stage with individual lines. Finally, classification of the wheat lines according to the respective NUE of each line was undertaken.【Result】The results showed significant genetic variations for most of the tested characters among different wheat lines. Correlation analysis indicated a positive correlation between yield and aboveground dry mass, straw weight, harvest index, spike number of the plant at harvesting stage, dry mass of the plant at the flowering stage as well as the nitrogen accumulation in the kernel and straw of the plant. Meanwhile, except the nitrogen harvest index, a negative correlation was observed between the plant physiological use efficiency and plant straw weight, spike number, kernel and straw nitrogen concentration and accumulation. In addition, according to the yield of the 118 wheat lines under the both nitrogen conditions, the selected wheat lines were categorized into four classes: Efficient-efficient (EE, yield higher than the mean yield of all the lines under both conditions), Inefficient-inefficient (II, yield lower than the mean yield of all the lines under both conditions), and Inefficient-efficient (IE, yield higher than the mean yield of all the lines only under high nitrogen conditions), Efficient-inefficient (EI, yield higher than the mean yield of all the lines only under low nitrogen conditions). The EE type of wheat lines was more sensitive to the nitrogen application. The EI type of wheat lines had significant higher chlorophyll content than the other lines at grain-filling stage, which indicated the critical role of stay-green character of the plant for nitrogen utilization under the low nitrogen conditions.【Conclusion】The selected wheat lines showed significant genotypic variations for their nitrogen use efficiencies under the two nitrogen input conditions. Meanwhile, the different types of wheat lines responded distinctively to the nitrogen application. Among them, the IE type of wheat lines was the most sensitive one to nitrogen application, and suitable for high nitrogen content field, whereas the EE and EI types were more tolerant to the nitrogen starvation, and could be the elite germplasm for high NUE wheat breeding. According to the correlation analysis of yield with different traits, it was found that except the routine characters such as the above-ground dry mass and plant nitrogen accumulation, the spike number could also be used as a trait to evaluate the high nitrogen use efficiency in wheat.

Key words: Wheat, the middle and lower reaches of Yangtze River, nitrogen use efficiency, genotypic variation, correlation analysis

徐晴，许甫超，董静，董建辉，秦丹丹，鲁梦莹，李梅芳. 小麦氮素利用效率的基因型差异及相关特性分析[J]. 中国农业科学, 2017, 50(14): 2647-2657.

XU Qing, XU FuChao, DONG Jing, DONG JianHui, QIN DanDan, LU MengYing, LI MeiFang. Genotypic Difference of Nitrogen Use Efficiency of Wheat and Correlation Analysis of the Related Characters[J]. Scientia Agricultura Sinica, 2017, 50(14): 2647-2657.

0
/ / 推荐

导出引用管理器 EndNote|Reference Manager|ProCite|BibTeX|RefWorks

链接本文: https://www.chinaagrisci.com/CN/10.3864/j.issn.0578-1752.2017.14.002

https://www.chinaagrisci.com/CN/Y2017/V50/I14/2647

参考文献

[1] 徐晴, 许甫超, 董静, 秦丹丹, 李梅芳. 小麦氮素高效育种研究进展. 麦类作物学报, 2016(1): 44-50.

XU Q, XU F C, DONG J, QIN, D D, LI M F. Research advances on nitrogen use efficiency (NUE) in Wheat breeding. Journal of Traticeae Crops, 2016(1): 44-50. (in Chinese)

[2] Huang J, Huang Z, Jia X, HU R, XIANG C. Long-term reduction of nitrogen fertilizer use through knowledge training in rice production in China. Agricultural Systems, 2015, 135: 105-111.

[3] Raun W R, Johnson G V. Improving nitrogen use efficiency for cereal production. Agronomy Journal, 1999, 91: 357-363.

[4] Cui Z, Wang G, Yue S, Wu L, Zhang W, Zhang F, Chen X. Closing the N-use efficiency gap to achieve food and environmental security. Environmental Science & Technology, 2014, 48: 5780-5787.

[5] Garnett T, Plett D, Conn V, Conn S, Rabie H, Rafalski J A, Dhugga K, Tester M A, Kaiser B N. Variation for N uptake system in maize: Genotypic response to N supply. Frontier in Plant Science, 2015, 6: 936.

[6] Barraclough P B, Howarth J R, Jones J, Lopez- Bellido R, Parmar S, Shepherd C E, Hawkesford M J. Nitrogen efficiency of wheat: Genotypic and environmental variation and prospects for improvement. European Journal of Agronomy, 2010, 33: 1-11.

[7] Habash D, Bernard S, Schondelmaier J, Weyen J, Quarrie S. The genetics of nitrogen use in hexaploid wheat: N utilisation, development and yield. Theoretical and Applied Genetics, 2007, 114: 403-419.

[8] Krapp A. Plant nitrogen assimilation and its regulation: a complex puzzle with missing pieces. Current Opinion in Plant Biology, 2015, 25: 115-122.

[9] MOLL R H, KAMPRATH E J, JACKSON W A. Analysis and interpretation of factors which contribute to efficiency to nitrogen utilization. Agronomy Journal, 1982, 74: 562-564.

[10] 童依平, 李继云, 李振声. 不同小麦品种吸收利用氮素效率的差异及有关机理研究. 西北植物学报, 1999, 19(2): 270-277.

TONG Y P, LI J Y, LI Z S. Genotypic variations for nitrogen use efficiency in winter wheat. Acta Botanical Boreali-OccidentaliaSinica, 1999, 19(2): 270-277. (in Chinese)

[11] Good A G, Shrawat A K, Muench D G. Can less yield more? Is reducing nutrient input into the environment compatible with maintaining crop production? Trends in Plant Science, 2004, 9: 597-605.

[12] Gorny A G, Garczynski S, Banaszak Z, Lugowska B. Genetic variation in the efficiency of nitrogen utilization and photosynthetic activity of flag leaves among the old and modern germplasm of winter wheat. Journal of Applied Genetics, 2006, 47: 231-237.

[13] 马汉云, 王青林, 祁玉良, 扶定, 霍二伟, 沈光辉, 郭桂英. 水稻氮素利用基因型鉴定筛选及其响应机制. 广东农业科学, 2011(21): 31-46.

MA H Y, WANG Q L, QI Y L, Fu D, HUO E W, SHEN G H, GUO G Y. Identification and response mechanism of different rice genotypes. Guangdong Agricultural Sciences, 2011(21): 31-46. (in Chinese)

[14] 黄永兰, 黎毛毛, 芦明, 万建林, 龙起樟, 王会民, 唐秀英, 范志洁. 氮高效水稻种质资源筛选及相关特性分析. 植物遗传资源学报, 2015, 16(1): 87-93.

HUANG Y L, LI M M, LU M, WAN J L, LONG Q Z, WANG H M, TANG X Y, FAN Z J. Selection of rice germplasm with high nitrogen utilization efficiency and its analysis of the related characters. Journal of Plant Genetic Resources, 2015, 16(1): 87-93. (in Chinese)

[15] 朴钟泽, 韩龙植, 高熙宗. 水稻不同基因型氮素利用效率差异. 中国水稻科学, 2003, 17(3): 233-238.

PU Z Z, HAN L Z, GAO X Z. Genotypic differences of nitrogen use efficiency in rice. Chinese Journal of Rice Science, 2003, 17(3): 233-238. (in Chinese)

[16] 陈二影, 杨延兵, 秦岭, 张华文, 刘宾, 王海莲, 陈桂玲, 于淑婷, 管延安. 谷子苗期氮高效品种筛选及相关特性分析. 中国农业科学, 2016, 49(17): 3287-3297.

CHEN E Y, YANG Y B, QIN L, ZHANG H W, LIU B, WANG H L, CHEN G L, YU S T, GUAN Y A. Evaluation of nitrogen efficient cultivars of Foxtail millet and analysis of the related characters at seedling stage. Scientia Agricultura Sinica, 2016, 49(17): 3287-3297. (in Chinese)

[17] 王永华, 胡卫丽, 李刘霞, 段剑钊, 郭天财. 不同基因型小麦产量和氮利用效率的差异及其相互关系. 麦类作物学报, 2013, 33(2): 301-308.

WANG Y H, HU W L, LI L X, DUAN J Z, GUO T C. Differences in grain yield, nitrogen efficiency of different genotypes of winter wheat and their correlations. Journal of Triticeae Crops, 2013, 33(2): 301-308. (in Chinese)

[18] 张锡洲, 阳显斌, 李廷轩, 余海英. 小麦氮素利用效率的基因型差异. 应用生态学报 2011, 22(2): 369-375.

ZHANG X Z, YANG X B, LI T X, YU H Y. Genotype difference in nitrogen utilization efficiency of wheat. Chinese journal of applied ecology, 2011, 22(2): 369-375. (in Chinese)

[19] 何文寿, 陈素生, 康建宏. 宁夏春小麦氮素利用效率的基因型差异研究. 土壤, 2003, 35(6): 500-505.

HE W S, CHEN S S, KANG J H. Genotype difference in nitrogen utilization efficiency of wheat in NingXia Province. Soil, 2003, 35(6): 500-505. (in Chinese)

[20] 董召娣, 张明伟, 易媛, 郭明明, 朱新开, 封超年, 郭文善, 彭永欣. 部分春性和半冬性小麦品种氮效率差异分析. 麦类作物学报, 2014, 34(9): 1267-1273.

DONG Z D, ZHANG M W, YI Y, GUO M M, ZHU X K, FENG C N, GUO W S, PENG Y X. Aanlysis on the difference in nitrogen efficiency of semi-winter and spring wheat varieties. Journal of Triticeae Crops, 2014, 34(9): 1267-1273. (in chinese)

[21] 杜保见, 郜红建, 常江, 章力干. 小麦苗期氮素吸收利用效率差异及聚类分析. 植物营养与肥料学报, 2014, 20(6): 1349-1357.

DU B J, HAO H J, CHANG J, ZHANG L G. Screening and cluster analysis of nitrogen use efficiency of different wheat cultivars at seedling stage. Journal of plant nutrition and fertilizer, 2014, 20(6): 1349-1357. (in Chinese)

[22] 朱新开, 郭文善, 朱冬梅, 朱波风, 封超年, 彭永欣. 不同基因型小麦氮素吸收积累差异研究. 扬州大学学报, 2005, 6(3): 52-57.

ZHU X K, GUO W S, ZHU D M, ZHU P F, FENG C N, PENG Y X. Studies on differences of accumulated N amount in different genotypes of winter wheat. Journal of Yangzhou University (Agricultural and Life Science Edition), 2005, 6(3): 52-57. (in Chinese)

[23] 李艳, 董中东, 郝西, 崔党群. 小麦不同品种的氮素利用效率差异研究. 中国农业科学, 2007, 40(3): 472-477.

LI Y, DONG Z D, HAO X, CUI D Q. The studies on genotypic difference of nitrogen utilization efficiency in winter wheat. Scientia Agricultura Sinica, 2007, 40(3): 472-477. (in Chinese)

[24] 张亚丽, 樊剑波, 段英华, 王东升, 叶利庭, 沈其荣. 不同基因型水稻氮利用效率的差异及评价. 土壤学报, 2008, 4(2): 267-272.

ZHANG Y L, FAN J B, DUAN Y H, WANG D S, YE L T, SHEN Q R. The differences and evaluation of the nitrogen unilization efficiency of different rice genotypes. Acta Pedologica sinica, 2008, 45(2): 267-272. (in Chinese)

[25] Ladha J K, Kirk G J D, Bennett J, Peng S, Reddy C K, Reddy P M, Singh U. Opportunities for increased nitrogen-use efficiency from improved lowland rice germplasm. Field Crops Research, 1998, 56: 41-71.

[26] Zhao D, Derkx A P, Liu D C, Buchner P, Hawkesford M J. Over-expression of a NAC transcription factor delays leaf senescence and increases grain nitrogen concentration in wheat. Plant Biology (Stuttg), 2014, 17: 904-913.

[27] Kusaba M, Tanaka A, Tanaka R. Stay-green plants: what do they tell us about the molecular mechanism of leaf senescence. Photosynthesis Research, 2013, 117: 221-234.

[28] Spano G, Di Fonzo N, Perrotta C, Platani C, Ronga G, Lawlor D W, Napier J A, Shewry P R. Physiological characterization of 'stay green' mutants in durum wheat. Journal of Experimental Botany, 2003, 54: 1415-1420.