Unlocking the potential of wild progenitors to enhance water deficit stress tolerance in maize

IF 1.6 4区 农林科学 Q2 AGRONOMY
Gagandeep Kaur, Surinder Sandhu, Harjot Kaur, Nida Yousuf, Gagandeep Singh
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Abstract

The global challenge of water deficit stress (WDS) in maize (Zea mays L.) production, particularly in rainfed agriculture, necessitates a holistic understanding of root traits’ role in responding to this stress. While previous research has primarily focused on molecular mechanisms, acknowledging the significance of root architectural traits is essential. This study explores the development of the BC2F1 generation by crossing Zea diploperennis (donor) with maize inbred line LM13 (recurrent parent) to transfer water deficit tolerance attributes to maize. Efforts to develop backcross generations with Z. nicaraguensis were unsuccessful. The study investigates the response of wild maize relatives (Z. diploperennis and Z. nicaraguensis) and maize inbred line LM13 to WDS induced by osmolytes. Root trait modifications were analyzed using a root scanner, including parameters such as root projection area, length, tips, forks, segments, average root diameter, total root volume, number of metaxylem vessels, and xylem diameter. BC2F1 individuals, Z. diploperennis, and Z. nicaraguensis exhibited increased root projection area, total root length, and total root volume under WDS, while LM13 showed a decrease in most parameters. Scanning electron microscopy revealed increased metaxylem number in Z. diploperennis and BC2F1 under WDS, indicating drought tolerance. Z. nicaraguensis also displayed WDS tolerance. This study highlights the potential of wild maize relatives in conferring WDS tolerance and the feasibility of introgressing their root plasticity traits into cultivated maize for enhanced climatic resilience.

Abstract Image

挖掘野生祖先的潜力,提高玉米对缺水胁迫的耐受性
玉米(Zea mays L.)生产中的缺水胁迫(WDS)是一项全球性挑战,尤其是在雨水灌溉农业中,因此有必要全面了解根系特征在应对这种胁迫中的作用。虽然以往的研究主要集中在分子机制方面,但承认根系结构特征的重要性也是至关重要的。本研究通过将玉米近交系LM13(复交亲本)与Zea diploperennis(供体)杂交,探索BC2F1代的开发,从而将耐缺水特性转移到玉米上。与 Z. nicaraguensis 进行回交的努力没有成功。本研究调查了野生玉米近缘种(Z. diploperennis 和 Z. nicaraguensis)和玉米近交系 LM13 对渗透溶质诱导的 WDS 的反应。利用根扫描仪分析了根的性状变化,包括根的投影面积、长度、尖端、分叉、节、平均根径、根的总体积、中木质部血管数和木质部直径等参数。在 WDS 条件下,BC2F1、Z. diploperennis 和 Z. nicaraguensis 的根投影面积、根总长度和根总体积都有所增加,而 LM13 的大部分参数都有所下降。扫描电子显微镜显示,在 WDS 条件下,Z. diploperennis 和 BC2F1 的中木质部数量增加,这表明它们具有耐旱性。Z. nicaraguensis也表现出耐旱性。这项研究强调了玉米野生近缘种在赋予WDS耐受性方面的潜力,以及将其根系可塑性特征引入栽培玉米以增强气候适应性的可行性。
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来源期刊
CiteScore
3.40
自引率
6.20%
发文量
92
审稿时长
6-12 weeks
期刊介绍: This journal publishes original papers presenting new scientific results on breeding, genetics, physiology, pathology and production of primarily wheat, rye, barley, oats and maize.
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