Nitrogen deficiency tolerance conferred by introgression of a QTL derived from wild emmer into bread wheat.

IF 4.4 1区 农林科学 Q1 AGRONOMY Theoretical and Applied Genetics Pub Date : 2024-07-17 DOI:10.1007/s00122-024-04692-z
Nikolai Govta, Andrii Fatiukha, Liubov Govta, Curtis Pozniak, Assaf Distelfeld, Tzion Fahima, Diane M Beckles, Tamar Krugman
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Abstract

Key message: Genetic dissection of a QTL from wild emmer wheat, QGpc.huj.uh-5B.2, introgressed into bread wheat, identified candidate genes associated with tolerance to nitrogen deficiency, and potentially useful for improving nitrogen-use efficiency. Nitrogen (N) is an important macronutrient critical to wheat growth and development; its deficiency is one of the main factors causing reductions in grain yield and quality. N availability is significantly affected by drought or flooding, that are dependent on additional factors including soil type or duration and severity of stress. In a previous study, we identified a high grain protein content QTL (QGpc.huj.uh-5B.2) derived from the 5B chromosome of wild emmer wheat, that showed a higher proportion of explained variation under water-stress conditions. We hypothesized that this QTL is associated with tolerance to N deficiency as a possible mechanism underlying the higher effect under stress. To validate this hypothesis, we introgressed the QTL into the elite bread wheat var. Ruta, and showed that under N-deficient field conditions the introgression IL99 had a 33% increase in GPC (p < 0.05) compared to the recipient parent. Furthermore, evaluation of IL99 response to severe N deficiency (10% N) for 14 days, applied using a semi-hydroponic system under controlled conditions, confirmed its tolerance to N deficiency. Fine-mapping of the QTL resulted in 26 homozygous near-isogenic lines (BC4F5) segregating to N-deficiency tolerance. The QTL was delimited from - 28.28 to - 1.29 Mb and included 13 candidate genes, most associated with N-stress response, N transport, and abiotic stress responses. These genes may improve N-use efficiency under severely N-deficient environments. Our study demonstrates the importance of WEW as a source of novel candidate genes for sustainable improvement in tolerance to N deficiency in wheat.

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将源自野生小麦的 QTL 基因导入面包小麦,赋予小麦耐缺氮性。
关键信息:对野生小麦QGpc.huj.uh-5B.2的一个QTL进行遗传分析,发现了与耐氮缺乏有关的候选基因,这些基因可能有助于提高氮的利用效率。氮(N)是对小麦生长发育至关重要的重要宏量营养元素;缺氮是导致谷物产量和质量下降的主要因素之一。氮的可用性受干旱或洪水的影响很大,而干旱或洪水又取决于其他因素,包括土壤类型或胁迫的持续时间和严重程度。在之前的一项研究中,我们从野生小麦的 5B 染色体中发现了一个高籽粒蛋白含量 QTL(QGpc.huj.uh-5B.2),该 QTL 在水胁迫条件下的解释变异比例较高。我们假设该 QTL 与对氮缺乏的耐受性有关,这可能是胁迫条件下较高效应的一种机制。为了验证这一假设,我们将该 QTL 引种到精英面包小麦变种 Ruta 中,结果表明在缺氮的田间条件下,引种 IL99 的 GPC(p 4F5)增加了 33%,并分离出对缺氮的耐受性。该 QTL 的范围为 - 28.28 到 - 1.29 Mb,包括 13 个候选基因,其中大部分与氮胁迫响应、氮转运和非生物胁迫响应有关。这些基因可能会提高严重缺氮环境下的氮利用效率。我们的研究表明,WEW 是新型候选基因的重要来源,可持续提高小麦对氮缺乏的耐受性。
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来源期刊
CiteScore
9.60
自引率
7.40%
发文量
241
审稿时长
2.3 months
期刊介绍: Theoretical and Applied Genetics publishes original research and review articles in all key areas of modern plant genetics, plant genomics and plant biotechnology. All work needs to have a clear genetic component and significant impact on plant breeding. Theoretical considerations are only accepted in combination with new experimental data and/or if they indicate a relevant application in plant genetics or breeding. Emphasizing the practical, the journal focuses on research into leading crop plants and articles presenting innovative approaches.
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