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

摘要/Abstract

摘要：

为探究雨养和灌溉条件下氮肥后移对冬小麦面粉加工品质的影响及其谷蛋白形成机制，本研究选用强筋小麦品种中麦886 (ZM886)和中筋小麦品种中麦30 (ZM30)为试验材料，在雨养处理(W)和灌溉处理(D)条件下，总施氮量为210 kg hm^-²的基础上设置2个追氮处理：常规氮肥处理(N1：底肥50%+拔节肥50%)和氮肥后移处理(N2：底肥50%+拔节肥30%+孕穗肥20%)，研究其对冬小麦籽粒谷蛋白大聚合体(GMP)形成和面粉加工品质的影响。试验结果表明，2小麦品种产量最大值均出现在WN2处理，其中ZM30在WN2处理下产量较其他处理平均提高12.36% (2021—2022年)和13.97% (2022—2023年)，ZM886同期分别提高9.85%和18.31%。在花后10 d检测到籽粒中高分子量谷蛋白亚基(HMW-GS)和低分子量谷蛋白亚基(LMW-GS)，ZM886在DN2处理下HMW-GS、LMW-GS、free-SH、-S-S-含量最高，ZM30则在WN2处理达到峰值。花后30 d检测到2小麦品种籽粒GMP的存在，ZM886在DN2下较其他处理增高5.40%~33.90%，ZM30在WN2下增高2.50%~14.70%，同时分别在2处理下增加了GMP大颗粒体积和表面积百分比，从而不同程度地提高面粉加工品质。小麦籽粒GMP含量与HMW-GS含量和LMW-GS含量呈正相关，ZM886籽粒GMP含量与面团形成时间和稳定时间呈正相关，但与产量呈负相关；ZM30籽粒GMP含量与产量呈极显著正相关，但与吸水率呈负相关。综上，本试验条件下，氮肥后移通过调控谷蛋白亚基合成，提升GMP含量，优化GMP粒径分布。因小麦产量而言，适宜的水氮配置为：灌溉处理下，氮肥施用底肥50%+拔节肥30%+孕穗肥20%；因小麦品质而言，适宜的水氮配置因品种类型而异：强筋小麦中麦886为在雨养处理下，氮肥施用底肥50%+拔节肥30%+孕穗肥20%，中筋小麦中麦30为在灌溉处理下，氮肥施用底肥50%+拔节肥30%+孕穗肥20%。

关键词: 小麦, 雨养条件, 灌溉条件, 氮肥后移, GMP, 加工品质

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

王曜阔, 王文政, 张敏, 刘希伟, 杨敏, 李昊昱, 张灵鑫, 闫彦菲, 蔡瑞国. 水氮运筹对冬小麦籽粒GMP合成和面粉加工品质的影响[J]. 作物学报, 0, (): 0-.

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-.

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