水氮运筹对冬小麦籽粒GMP合成和面粉加工品质的影响

doi:10.3724/SP.J.1006.2025.51007

Abstract

Abstract:

To investigate the effects of delayed nitrogen application on the flour processing quality and glutenin formation in winter wheat under rain-fed and irrigated conditions, two wheat cultivars—Zhongmai 886 (ZM886, strong gluten) and Zhongmai 30 (ZM30, medium gluten)—were used as experimental materials. Under rain-fed (W) and irrigation (D) conditions, two nitrogen topdressing strategies were applied with a total nitrogen input of 210 kg hm^-²: conventional nitrogen application (N1: 50% as basal fertilizer + 50% at jointing stage) and delayed nitrogen application (N2: 50% basal + 30% at jointing + 20% at booting stage). The effects of delayed nitrogen application on glutenin macropolymer (GMP) formation and flour processing quality were evaluated under shallow-buried drip irrigation. Results showed that the highest grain yields for both cultivars occurred under the WN2 treatment. Compared with other treatments, ZM30 yield under WN2 increased by 12.36% (2021–2022) and 13.97% (2022–2023), while ZM886 yield increased by 9.85% and 18.31%, respectively. High molecular weight glutenin subunits (HMW-GS) and low molecular weight glutenin subunits (LMW-GS) were detected in grains 10 days after anthesis. The contents of HMW-GS, LMW-GS, free-SH, and -S-S-S- in ZM886 were highest under DN2, while ZM30 peaked under WN2. GMP formation was detected at 30 days after anthesis. Compared with other treatments, GMP content in ZM886 increased by 5.40%–33.90% under DN2, and in ZM30 by 2.50%–14.70% under WN2. Additionally, the volume and surface area percentages of large GMP particles increased under these treatments, contributing to improvements in flour processing quality. GMP content was positively correlated with HMW-GS and LMW-GS contents. In ZM886, GMP content showed a positive correlation with dough development and stability times, but a negative correlation with yield. In contrast, GMP content in ZM30 was significantly positively correlated with yield, but negatively correlated with water absorption. In conclusion, delayed nitrogen application enhanced GMP content and optimized its particle size distribution by regulating glutenin subunit synthesis. Based on yield performance, the suitable water-nitrogen strategy is: under irrigation, apply nitrogen as 50% basal + 30% jointing + 20% booting. In terms of quality, the suitable strategy varies by variety: for strong gluten wheat ZM886, the best result was achieved under rain-fed conditions with delayed nitrogen application, while for medium gluten wheat ZM30, the best quality was obtained under irrigation with delayed nitrogen application.

Key words: wheat, rain-fed conditions, irrigation conditions, nitrogen fertilizer postponing, GMP, processing quality

WANG Yao-Kuo, WANG Wen-Zheng, ZHANG Min, LIU Xi-Wei, YANG Min, LI Hao-Yu, ZHANG Ling-Xin, YAN Yan-Fei, CAI Rui-Guo. Effects of water and nitrogen treatments on GMP synthesis and flour processing quality of winter wheat grain[J].Acta Agronomica Sinica, 0, (): 0-.

References

[1] 姚春生, 任婕, 张震, 周晓楠, 王志敏, 张英华. 微喷水肥一体化氮肥管理对冬小麦产量、品质、氮素积累和利用的影响. 中国农业大学学报, 2023, 28(3): 25–37.

Yao C S, Ren J, Zhang Z, Zhou X N, Wang Z M, Zhang Y H. Effects of micro-spraying water and fertilizer integrated nitrogen management on yield, quality, nitrogen accumulation and utilization of winter wheat. J China Agric Univ, 2023, 28(3): 25–37 (in Chinese with English abstract).

[2] 聂浩亮, 黄少辉, 杨军芳, 张静, 杨云马, 卢萍萍, 岳增良, 贾良良. 氮肥管理及氮素形态对强筋冬小麦产量、品质及氮肥利用效率的影响. 麦类作物学报, 2024, 44: 1590–1598.

Nie H L, Huang S H, Yang J F, Zhang J, Yang Y M, Lu P P, Yue Z L, Jia L L. Effects of nitrogen management and form on yield, processing quality and nitrogen use efficiency of strong gluten winter wheat. J Triticeae Crops, 2024, 44: 1590–1598 (in Chinese with English abstract).

[3] 丁文成, 宋大利, 周卫. 我国耕地质量主控因素及提升策略. 植物营养与肥料学报, 2024, 30: 1580–1594.

Ding W C, Song D L, Zhou W. Main controlling factors and improvement strategies of cultivated land quality in China. J Plant Nutr Fert, 2024, 30: 1580–1594 (in Chinese with English abstract).

[4] Shen Y, Han X, Feng H, Han Z, Wang M, Ma D, Jin J, Li S, Ma G, Zhang Y, Wang C. Wheat GSPs and processing quality are affected by irrigation and nitrogen through nitrogen remobilisation. Foods, 2023, 12: 4407.

[5] Don C, Lichtendonk W, Plijter J J, Hamer R J. Glutenin macropolymer: a gel formed by glutenin particles. J Cereal Sci, 2003, 37: 1–7.

[6] 曹丽. 追氮时期对小麦籽粒产量和谷蛋白积累的调控效应. 山东农业大学硕士学位论文, 山东泰安, 2012.

Cao L. Effect of Nitrogen Topdressing on Grain Yield and Glutenin Accumulation in Wheat. MS Thesis of Shandong Agricultural University, Tai’an, Shandong, China, 2012 (in Chinese with English abstract).

[7] 赵惠贤, 胡胜武, 吉万全, 薛秀庄, 郭蔼光, Daryl Mares. 小麦谷蛋白聚合体粒度分布与面粉揉面特性关系的研究. 中国农业科学, 2001, 34: 475–479.

Zhao H X, Hu S W, Ji W Q, Xue X Z, Guo A G, Mares D. Study on the relationship between the size distribution of glutenin polymeric protein and wheat flour mixing properties. Sci Agric Sin, 2001, 34: 475–479 (in Chinese with English abstract).

[8] Pirozi M R, Margiotta B, Lafiandra D, MacRitchie F. Composition of polymeric proteins and bread-making quality of wheat lines with allelic HMW-GS differing in number of cysteines. J Cereal Sci, 2008, 48: 117–122.

[9] Ohm J B, Ross A S, Peterson C J, Ong Y L. Relationships of high molecular weight glutenin subunit composition and molecular weight distribution of wheat flour protein with water absorption and color characteristics of noodle dough. Cereal Chem, 2008, 85: 123–131.

[10] Don C, Lichtendonk W J, Plijter J J, Hamer R J. Understanding the link between GMP and dough: from glutenin particles in flour towards developed dough. J Cereal Sci, 2003, 38: 157–165.

[11] Zhang X X, Shi Z Q, Jiang D, Högy P, Fangmeier A. Independent and combined effects of elevated CO₂ and post-anthesis heat stress on protein quantity and quality in spring wheat grains. Food Chem, 2019, 277: 524–530.

[12] 张雪艳, 刘敬科, 李朋亮, 赵巍, 张晓頔, 杨欢, 生庆海, 张爱霞. 食品组分对面筋网络及面团加工品质影响的研究进展. 食品工业科技, 2024, 45: 1–17.

Zhang X X, Liu J K, Li P L, Zhao W, Zhao X D,Yang H, Sheng Q H, Zhang A X. Research progress on the effects of food components on gluten network and dough processing quality. Sci Technol Food Ind, 2024, 45: 1–17 (in Chinese with English abstract).

[13] Gu X Y, Liu Y H, Paliwal J, Wen X X. Effects of foliar spraying of potassium fertilizer on the contents of microelement, phytic acid and HMW-GS in wheat flour. J Cereal Sci, 2023, 110: 103621.

[14] 岳鸿伟, 秦晓东, 戴廷波, 荆奇, 曹卫星, 姜东. 施氮量对小麦籽粒HMW-GS及GMP含量动态的影响. 作物学报, 2006, 32: 1678–1683.

Yue H W, Qin X D, Dai T B, Jing Q, Cao W X, Jiang D. Effects of nitrogen rate on accumulations of HMW-GS and GMP in wheat grain. Acta Agron Sin, 2006, 32: 1678–1683 (in Chinese with English abstract).

[15] 岳鸿伟, 谭维娜, 姜东, 戴廷波, 荆奇, 曹卫星. 花后干旱和渍水对小麦籽粒HMW-GS及GMP含量的影响. 作物学报, 2007, 33: 1845–1849.

Yue H W, Tan W N, Jiang D, Dai T B, Jing Q, Cao W X. Effects of post anthesis drought and waterlogging on contents of high molecular weight glutenin subunits and glutenin macropolymer. Acta Agron Sin, 2007, 33: 1845–1849 (in Chinese with English abstract).

[16] 赵佳佳, 马小飞, 郑兴卫, 郝建宇, 乔玲, 葛川, 王爱爱, 张树伟, 张晓军, 姬虎太, 等.不同水分条件下HMW-GS对小麦品质的影响. 作物学报, 2019, 45: 1682–1690.

Zhao J J, Ma X F, Zheng X W, Hao J Y, Qiao L, Ge C, Wang A A, Zhang S W, Zhang X J, Ji H T, et al. Effects of HMW-GS on wheat quality under different water conditions. Acta Agron Sin, 2019, 45: 1682–1690 (in Chinese with English abstract).

[17] 姚凤娟, 贺明荣, 贾殿勇, 代兴龙, 曹倩. 花后灌溉对小麦籽粒贮藏蛋白聚合程度和面团流变学特性的影响. 植物生态学报, 2010, 34: 271–278.

Yao F J, He M R, Jia D Y, Dai X L, Cao Q. Effects of post-anthesis irrigation on degree of polymerization of storage protein and rheological properties in wheat. J Plant Ecol, 2010, 34: 271–278 (in Chinese with English abstract).

[18] Flagella Z, Giuliani M M, Giuzio L, Volpi C, Masci S. Influence of water deficit on durum wheat storage protein composition and technological quality. Eur J Agron, 2010, 33: 197–207.

[19] Zhou J, Liu D, Deng X, Zhen S, Wang Z, Yan Y. Effects of water deficit on breadmaking quality and storage protein compositions in bread wheat (Triticum aestivum L.). J Sci Food Agric, 2018, 98: 4357–4368.

[20] Li Y, Yin Y P, Zhao Q, Wang Z L. Changes of glutenin subunits due to water-nitrogen interaction influence size and distribution of glutenin macropolymer particles and flour quality. Crop Sci, 2011, 51: 2809–2819.

[21] Song L, Li L, Zhao L, Liu Z, Li X. Effects of nitrogen application in the wheat booting stage on glutenin polymerization and structural-thermal properties of gluten with variations in HMW-GS at the Glu-D1 locus. Foods, 2020, 9: E353.

[22] 代新俊, 夏清, 杨珍平, 高志强. 氮肥后移对强筋小麦氮素积累转运及籽粒产量与品质的影响. 水土保持学报, 2018, 32: 289–294.

Dai X J, Xia Q, Yang Z P, Gao Z Q. Effects of postponing nitrogen application on accumulation and transport of nitrogen yield and quality of grain in strong-gluten wheat. J Soil Water Conserv, 2018, 32: 289–294 (in Chinese with English abstract).

[23] 付陈陈, 刘子晶, 蔡瑞国, 郭双双, 徐东娜, 史金平, 张敏. 施氮模式对强筋小麦氮素积累和籽粒蛋白质含量的影响. 麦类作物学报, 2022, 42: 1391–1397.

Fu C C, Liu Z J, Cai R G, Guo S S, Xu D N, Shi J P, Zhang M. Effects of nitrogen application mode on nitrogen accumulation and grain protein content in strong gluten wheat. J Triticeae Crops, 2022, 42: 1391–1397 (in Chinese with English abstract).

[24] Weegels P L, van de Pijpekamp A M, Graveland A, Hamer R J, Schofield J D. Depolymerisation and re-polymerisation of wheat glutenin during dough processing. I. relationships between glutenin macropolymer content and quality parameters. J Cereal Sci, 1996, 23: 103–111.

[25] Sun H. Correlation between content of glutenin macropolymer (GMP) in wheat and baking quality. J Chin Cereals Oils Assoc, 1998, 13: 13–16.

[26] Don C, Lichtendonk W J, Plijter J J, van Vliet T, Hamer R J. The effect of mixing on glutenin particle properties: aggregation factors that affect gluten function in dough. J Cereal Sci, 2005, 41: 69–83.

[27] 梁荣奇, 张义荣, 尤明山, 毛善锋, 宋建民, 刘广田. 小麦谷蛋白聚合体的MS-SDS-PAGE及其与面包烘烤品质的关系. 作物学报, 2002, 28: 609–614.

Liang R Q, Zhang Y R, You M S, Mao S F, Song J M, Liu G T. Multi-stacking SDS-PAGE for wheat glutenin polymer and it’s relation to bread-making quality. Acta Agron Sin, 2002, 28: 609–614 (in Chinese with English abstract).

[28] 张来林, 黄文浩, 肖建文, 黄楠, 周杰生, 金文. 不同储藏条件对大豆、稻谷蛋白中巯基和二硫键的影响研究. 粮食加工, 2012, 37: 67–70.

Zhang L L, Huang W H, Xiao J W, Huang N, Zhou J S, Jin W. Study on the effects of different storage conditions on-SH and -S-S-from soybean and rice protein. Grain process, 2012, 37: 67–70 (in Chinese with English abstract).

[29] 柳腾飞, 马莉, 汪顺生, 刘宇龙, 王帝儒, 赵逸飞, 李凯旋. 不同灌溉方式下水氮供应对冬小麦水氮利用效率的影响. 灌溉排水学报, 2024, 43(7): 11–18.

Liu T F, Ma L, Wang S S, Liu Y L, Wang D R, Zhao Y F, Li K X. Effects of water-nitrogen coupling under different irrigation methods on water and nitrogen use efficiency of winter wheat. J Irrig Drain, 2024, 43(7): 11–18(in Chinese with English abstract).

[30] Pan F F, Li H, Li P P, Lei Q, Tan J F, Han Y L. Effects of supplemental irrigation based on testing soil moisture and nitrogen fertilization amount on the yield and nitrogen uptake of winter wheat. Agric Sci Technol, 2014, 15: 817–820.

[31] 黄玲, 杨文平, 胡喜巧, 陶烨, 姚素梅, 欧行奇. 水氮互作对冬小麦耗水特性和氮素利用的影响. 水土保持学报, 2016, 30(2): 168–174.

Huang L, Yang W P, Hu X Q, Tao Y, Yao S M, Ou X Q. Effects of irrigation and nitrogen interaction on water consumption characteristics and nitrogen utilization of winter wheat. J Soil Water Conserv, 2016, 30(2): 168–174 (in Chinese with English abstract).

[32] Zhang Z, Yu Z, Zhang Y, Shi Y. Optimized nitrogen fertilizer application strategies under supplementary irrigation improved winter wheat (Triticum aestivum L.) yield and grain protein yield. Peer J, 2021, 9: e11467.

[33] 王荣荣, 徐宁璐, 黄修利, 赵凯男, 黄明, 王贺正, 付国占, 吴金芝, 李友军. 一次灌溉和氮肥运筹对旱地小麦籽粒产量和品质的影响. 中国农业科学, 2025, 58: 43–57.

Wang R R, Xu N L, Huang X L, Zhao K N, Huang M, Wang H Z, Fu G Z, Wu J Z, Li Y J. Effects of one-time irrigation and nitrogen application on grain yield and quality of dryland wheat. Sci Agric Sin, 2025, 58: 43–57 (in Chinese with English abstract).

[34] 马瑞琦, 陶志强, 王德梅, 王艳杰, 杨玉双, 朱英杰, 赵凯男, 李俊志, 王玉娇, 常旭虹, 等. 追氮量对强筋和中筋小麦产量与品质的影响. 植物营养与肥料学报, 2019, 25: 1799–1807.

Ma R Q, Tao Z Q, Wang D M, Wang Y J, Yang Y S, Zhu Y J, Zhao K N, Li J Z, Wang Y J, Chang X H, et al. Effects of nitrogen topdressing amount on yield and quality of strong gluten and medium gluten wheat. J Plant Nutr Fert, 2019, 25: 1799–1807 (in Chinese with English abstract).

[35] 乔玉强, 马传喜, 黄正来, 司红起, 蔡华, 夏云祥. 小麦品质性状的基因型和环境及其互作效应分析. 核农学报, 2008, 22: 706–711.

Qiao Y Q, Ma C X, Huang Z L, Si H Q, Cai H, Xia Y X. The effects of genotype, environment and their interaction on wheat quality. J Nucl Agric Sci, 2008, 22: 706–711 (in Chinese with English abstract).

[36] 赵广才, 常旭虹, 刘利华, 杨玉双, 李振华, 周双月, 郭庆侠, 刘月洁. 不同灌水处理对强筋小麦籽粒产量和蛋白质组分含量的影响. 作物学报, 2007, 33: 1828–1833.

Zhao G C, Chang X H, Liu L H, Yang Y S, Li Z H, Zhou S Y, Guo Q X, Liu Y J. Grain Yield and Protein Components Responses to Irrigation in Strong Gluten Wheat. Acta Agron Sin, 2007, 33: 1828–1833 (in Chinese with English abstract).

[37] 董志强, 吕丽华, 姚艳荣, 张经廷, 张丽华, 姚海坡, 申海平, 贾秀领. 水氮互作下强筋小麦师栾02-1产量和品质. 作物学报, 2023, 49: 1942–1953.

Dong Z Q, Lyu L H, Yao Y R, Zhang J T, Zhang L H, Yao H P, Shen H P, Jia X L. Yield and quality of strong gluten wheat Shiluan 02-1 under water and nitrogen interaction. Acta Agron Sin, 2023, 49: 1942–1953 (in Chinese with English abstract).

[38] Liu J X, Zhang J W, Zhu G R, Zhu D, Yan Y M. Effects of water deficit and high N fertilization on wheat storage protein synthesis, gluten secondary structure, and breadmaking quality. Crop J, 2022, 10: 216–223.

[39] 董飞, 李峰, 贾亚琴, 杨峰, 闫秋艳, 鲁晋秀, 申艳婷. 追氮量对黑小麦品种(系)籽粒产量和品质的影响. 核农学报, 2022, 36: 435–444.

Dong F, Li F, Jia Y Q, Yang F, Yan Q Y, Lu J X, Shen Y T. Effect of nitrogen topdressing rate on yield and quality of black-grained wheat varieties (strains). J Nucl Agric Sci, 2022, 36: 435–444 (in Chinese with English abstract).

[40] 王晓英, 贺明荣. 追氮时期和基追比例对强筋小麦产量和品质的调控效应. 麦类作物学报, 2013, 33: 711–715.

Wang X Y, He M. Regulatory Effect of Topdressing Stage and Ratio of Base and Topdressing of Nitrogen Fertilizer on Grain Yield Regulatory Effect of Topdressing Stage and Ratio of Base and Topdressing of Nitrogen Fertilizer on Grain Yield. J Triticeae Crops, 2013, 33: 711–715 (in Chinese with English abstract).

[41] Rossmann A, Pitann B, Mühling K H. Splitting nitrogen applications improves wheat storage protein composition under low N supply. J Plant Nutr Soil Sci, 2019, 182: 347–355.

[42] 曹丽, 王振林, 戴忠民, 尹燕枰, 翟学旭, 倪英丽, 蔡铁, 李勇, 王平, 陈二影, 等. 施氮时期对小麦籽粒HMW-GS积累及GMP粒度分布的影响. 作物学报, 2011, 37: 2241–2250.

Cao L, Wang Z L, Dai Z M, Yin Y P, Zhai X X, Ni Y L, Cai T, Li Y, Wang P, Chen E Y, et al. Effect of nitrogen fertilization timing on HMW-GS accumulation and GMP size distribution in wheat grains. Acta Agron Sin, 2011, 37: 2241–2250 (in Chinese with English abstract).

[43] 周晓燕, 贾殿勇, 代兴龙, 贺明荣. 不同灌水处理对强筋小麦谷蛋白大聚合体粒度分布和品质的影响. 应用生态学报, 2013, 24: 2557–2563.

Zhou X Y, Jia D Y, Dai X L, He M R. Effects of irrigation scheme on the grain glutenin macropolymer’s size distribution and the grain quality of winter wheat with strong gluten. Chin J Appl Ecol, 2013, 24: 2557–2563 (in Chinese with English abstract).

[44] Wrigley C, Békés F, Bushuk W. Gliadin and glutenin: the unique balance of wheat quality. Am Cereal Chem, 2006, 213–240.

[45] Don C, Lookhart G, Naeem H, MacRitchie F, Hamer R J. Heat stress and genotype affect the glutenin particles of the glutenin macropolymer-gel fraction. J Cereal Sci, 2005, 42: 69–80.

[46] Hui S. Correlation between content of glutenin macropolymer (GMP) in wheat and baking quality. J Chin Cereals Oils Assoc, 1998, 13: 13–16.

[47] 孙允超, 冀传允, 张新, 李海斌, 王璐莹, 冯盛烨, 程倩倩, 赵杨, 熊永星. 氮硫配施对强筋小麦品质、产量及构成要素的影响. 中国农学通报, 2024, 40: 7–12.

Sun Y C, Ji C Y, Zhang X, Li H B, Wang L Y, Feng S Y, Cheng Q Q, Zhao Y, Xiong Y X. Effects of combined application of nitrogen and sulfur on quality, yield and components of strong gluten wheat. Chin Agric Sci Bull, 2024, 40: 7–12 (in Chinese with English abstract).

[48] 赵琦, 李勇, 李文阳, 王平, 陈晓光, 尹燕枰, 王振林. 水氮互作对不同基因型小麦HMW-GS含量及GMP粒度分布的影响. 中国农业科学, 2011, 44: 1571–1584.

Zhao Q, Li Y, Li W Y, Wang P, Chen X G, Yin Y P, Wang Z L. Effects of water-nitrogen interaction on content of high molecular weight glutenin subunits and GMP size distribution in wheat cultivars of different genotypes. Sci Agric Sin, 2011, 44: 1571–1584 (in Chinese with English abstract).

[49] Tóth B, van Biljon A, Moloi M J, Labuschagne M. Effects of different fertilization levels on the concentration of high molecular weight glutenin subunits of two spring, hard red bread wheat cultivars. Cereal Chem, 2019, 96: 1004–1010.

[50] Rhazi L, Cazalis R, Aussenac T. Sulfhydryl-disulfide changes in storage proteins of developing wheat grain: influence on the SDS-unextractable glutenin polymer formation. J Cereal Sci, 2003, 38: 3–13.

[51] 李文阳, 闫素辉, 刘明明, 虞子强, 许峰, 张从宇, 邵庆勤. 氮硫配施对小麦籽粒巯基、二硫键含量与蛋白质品质的影响. 麦类作物学报, 2016, 36: 93–97.

Li W Y, Yan S H, Liu M M, Yu Z Q, Xu F, Zhang C Y, Shao Q Q. Effect of nitrogen and sulfur applications on sulfhydryl group, disulfide bond and protein quality in wheat grain. J Triticeae Crops, 2016, 36: 93–97 (in Chinese with English abstract).

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