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GmTDN1 通过诱导小麦对干旱和低氮胁迫的双重耐受来提高小麦产量。

GmTDN1 improves wheat yields by inducing dual tolerance to both drought and low-N stress.

机构信息

Institute of Crop Sciences (ICS), Chinese Academy of Agricultural Sciences (CAAS)/National Key Facility for Crop Gene Resources and Genetic Improvement, Key Laboratory of Biology and Genetic Improvement of Triticeae Crops, Ministry of Agriculture, Beijing, China.

Shijiazhuang Academy of Agricultural and Forestry Sciences, Research Center of Wheat Engineering Technology of Hebei, Shijiazhuang, China.

出版信息

Plant Biotechnol J. 2022 Aug;20(8):1606-1621. doi: 10.1111/pbi.13836. Epub 2022 May 25.

DOI:10.1111/pbi.13836
PMID:35514029
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9342622/
Abstract

Genetically enhancing drought tolerance and nutrient use efficacy enables sustainable and stable wheat production in drought-prone areas exposed to water shortages and low soil fertility, due to global warming and declining natural resources. In this study, wheat plants, exhibiting improved drought tolerance and N-use efficacy, were developed by introducing GmTDN1, a gene encoding a DREB-like transcription factor, into two modern winter wheat varieties, cv Shi4185 and Jimai22. Overexpressing GmTDN1 in wheat resulted in significantly improved drought and low-N tolerance under drought and N-deficient conditions in the greenhouse. Field trials conducted at three different locations over a period of 2-3 consecutive years showed that both Shi4185 and Jimai22 GmTDN1 transgenic lines were agronomically superior to wild-type plants, and produced significantly higher yields under both drought and N-deficient conditions. No yield penalties were observed in these transgenic lines under normal well irrigation conditions. Overexpressing GmTDN1 enhanced photosynthetic and osmotic adjustment capacity, antioxidant metabolism, and root mass of wheat plants, compared to those of wild-type plants, by orchestrating the expression of a set of drought stress-related genes as well as the nitrate transporter, NRT2.5. Furthermore, transgenic wheat with overexpressed NRT2.5 can improve drought tolerance and nitrogen (N) absorption, suggesting that improving N absorption in GmTDN1 transgenic wheat may contribute to drought tolerance. These findings may lead to the development of new methodologies with the capacity to simultaneously improve drought tolerance and N-use efficacy in cereal crops to ensure sustainable agriculture and global food security.

摘要

由于全球变暖以及自然资源的减少,在易受干旱和土壤肥力低下影响的缺水地区,提高耐旱性和养分利用效率可实现可持续且稳定的小麦生产。本研究通过将编码 DREB 样转录因子的 GmTDN1 基因导入两个现代冬小麦品种 Shi4185 和 Jimai22,培育出耐旱性和氮利用效率提高的小麦植株。在温室中,过表达 GmTDN1 可显著提高小麦在干旱和氮缺乏条件下的耐旱性和耐低氮性。在 2-3 年内连续进行的三个不同地点的田间试验表明,Shi4185 和 Jimai22 的 GmTDN1 转基因株系在农艺方面优于野生型植株,在干旱和氮缺乏条件下的产量显著提高。在这些转基因株系中,在正常的充分灌溉条件下,没有观察到产量下降。与野生型植株相比,过表达 GmTDN1 增强了小麦植株的光合作用和渗透调节能力、抗氧化代谢和根质量,通过协调一组与干旱胁迫相关的基因以及硝酸盐转运体 NRT2.5 的表达。此外,过表达 NRT2.5 的转基因小麦可以提高耐旱性和氮(N)吸收,这表明提高 GmTDN1 转基因小麦中的氮吸收可能有助于提高耐旱性。这些发现可能会为同时提高谷物作物耐旱性和氮利用效率的新方法的开发提供依据,以确保可持续农业和全球粮食安全。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/d616/11382958/35577a9afa18/PBI-20-1606-g005.jpg
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