Elevated ozone concentration reduces grain protein accumulation in wheat by decreasing nitrogen accumulation and nitrogen metabolism enzyme activities

IF 3.5 2区农林科学 Q1 AGRICULTURE, MULTIDISCIPLINARY Journal of the Science of Food and Agriculture Pub Date : 2025-04-05 DOI:10.1002/jsfa.14271

Yinsen Qian, Xiaoyi Jiang, Zhiwen Zhang, Min Zhu, Chunyan Li, Jinfeng Ding, Wenshan Guo, Xinkai Zhu

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Abstract

BACKGROUND

Ozone (O₃), a widespread air pollutant, significantly impairs crop growth and development, with wheat, the second largest crop by planting area of the world, being especially vulnerable. This study, conducted under Free Air Concentration Enrichment (FACE) conditions, focused on four wheat cultivars from the middle and lower reaches of the Yangtze River, investigating the effects of elevated O₃ on wheat growth, physiology and quality.

RESULTS

Elevated O₃ levels impaired assimilate accumulation and mobilization in wheat grains, reducing pre-anthesis nitrogen accumulation and causing an 8.21% decline in post-anthesis nitrogen translocation amount (NT), while increasing post-anthesis nitrogen translocation efficiency (NTE) by 3.83% and nitrogen harvest index (NHI) by 3.43%. Over 2 years, elevated O₃ raised grain protein content by 6.6–6.7% but significantly reduced protein accumulation by 10.4–10.7%, driven by declines in gliadin and glutenin. Total free amino acids and key nitrogen metabolizing enzymes also decreased. Among the four cultivars, YN19 was the most sensitive, showing the largest protein accumulation reductions.

CONCLUSION

This study demonstrates that elevated O₃ disrupts wheat nitrogen accumulation and protein synthesis by reducing pre-anthesis nitrogen accumulation, accelerating post-anthesis senescence, and suppressing nitrogen translocation due to rapid leaf area index (LAI) decline. The decline in nitrogen accumulation and nitrogen metabolizing enzyme activity is a critical factor contributing to reduced grain protein accumulation. Notably, YN19 exhibited the highest O₃ sensitivity, underscoring the need to develop O₃-resilient wheat cultivars to sustain grain quality under rising O₃ levels. © 2025 Society of Chemical Industry.

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臭氧浓度升高通过降低氮素积累和氮素代谢酶活性来降低小麦籽粒蛋白质积累。

背景：臭氧（O3）是一种广泛存在的空气污染物，严重损害作物的生长和发育，小麦是世界上种植面积第二大的作物，尤其容易受到影响。本研究在FACE （Free Air Concentration Enrichment）条件下，以长江中下游4个小麦品种为研究对象，研究了高浓度O3对小麦生长、生理和品质的影响。结果：O3水平升高损害了小麦籽粒同化物的积累和动员，减少了花前氮素积累，导致花后氮素转运量（NT）下降8.21%，而使花后氮素转运效率（NTE）提高3.83%，氮素收获指数（NHI）提高3.43%。在2年的时间里，O3升高使籽粒蛋白质含量提高了6.6-6.7%，但由于麦胶蛋白和谷蛋白的下降，蛋白质积累显著降低了10.4-10.7%。总游离氨基酸和关键氮代谢酶也减少。4个品种中，YN19最为敏感，蛋白质积累减少幅度最大。结论：O3升高通过减少小麦花前氮素积累、加速花后衰老、抑制叶面积指数（LAI）快速下降导致的氮素转运等途径，扰乱小麦氮素积累和蛋白质合成。氮素积累和氮素代谢酶活性下降是导致籽粒蛋白质积累减少的关键因素。值得注意的是，YN19表现出最高的O3敏感性，这强调了在O3水平上升的情况下，开发抗O3小麦品种以维持粮食品质的必要性。©2025化学工业协会。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of the Science of Food and Agriculture 工程技术-农业综合

CiteScore

8.10

自引率

4.90%

发文量

634

审稿时长

3.1 months

期刊介绍： The Journal of the Science of Food and Agriculture publishes peer-reviewed original research, reviews, mini-reviews, perspectives and spotlights in these areas, with particular emphasis on interdisciplinary studies at the agriculture/ food interface. Published for SCI by John Wiley & Sons Ltd. SCI (Society of Chemical Industry) is a unique international forum where science meets business on independent, impartial ground. Anyone can join and current Members include consumers, business people, environmentalists, industrialists, farmers, and researchers. The Society offers a chance to share information between sectors as diverse as food and agriculture, pharmaceuticals, biotechnology, materials, chemicals, environmental science and safety. As well as organising educational events, SCI awards a number of prestigious honours and scholarships each year, publishes peer-reviewed journals, and provides Members with news from their sectors in the respected magazine, Chemistry & Industry . Originally established in London in 1881 and in New York in 1894, SCI is a registered charity with Members in over 70 countries.