玉米转录因子ZmMYB12提高植物抗旱性和低磷耐受性的功能鉴定

doi:10.3724/SP.J.1006.2024.33007

摘要/Abstract

摘要：

玉米生长发育过程中会遭受干旱、高温、高盐及营养元素匮乏等多种非生物胁迫, 导致其产量和品质下降, 造成严重的农业减产。MYB类转录因子在植物中广泛分布, 参与植物生长发育和环境响应, 筛选及鉴定出具有抗逆功能的MYB类转录因子能为玉米抗逆遗传改良提供理论依据。本研究从玉米干旱处理的材料中克隆了一个R2R3-MYB家族转录因子基因ZmMYB12, 其响应自然干旱、ABA及PEG处理, 基因表达被诱导上调。病毒诱导沉默ZmMYB12后的玉米植株对干旱更加敏感, 活性氧积累更多, 根系更小; 复水后ZmMYB12沉默植株存活率更低, 表明ZmMYB12是干旱正调控因子。进一步构建ZmMYB12稳定过表达拟南芥, 干旱处理后ZmMYB12过表达株系活性氧积累更少, 侧根更多, 抗旱能力增强。同时, 发现ZmMYB12过表达拟南芥在低磷胁迫下侧根数量更多, 根系酸化程度增加, 叶绿素及花青素含量更多, 体内无机磷含量高于野生型, 表明ZmMYB12参与到低磷胁迫过程中, 并且提高了植株对磷元素的吸收及利用率。研究表明ZmMYB12调控干旱抗性并响应低磷胁迫, 为作物抗旱及耐低磷育种提供了一个良好的基因资源。

关键词: 玉米, MYB转录因子, 干旱胁迫, 低磷胁迫, 根系

Abstract:

Maize usually suffers from various abiotic stresses such as drought, high temperature, high salt, and deficiency of nutrient elements during growth and development period, which will eventually lead to the decline of yield and quality, resulting in serious agricultural yield reduction. MYB transcription factors are widely distributed in plants and involved in the whole process of plant growth and development and environmental response. Therefore, the screening and identification of MYB transcription factors conferring stress resistance can provide the theoretical basis and technical support for genetic improvement in maize. In this study, a R2R3-MYB family transcription factor gene, ZmMYB12, was cloned from maize materials under drought treatment. This gene showed inducible expression in response to drought, ABA, and PEG treatments. Maize plants with virus induced gene silencing (VIGS) of ZmMYB12 had higher sensitivity to drought and accumulated more reactive oxygen species (ROS), as well as smaller roots. The survival rate of ZmMYB12 silencing plants was lower after re-watering than the wild type plants (WT), indicating that ZmMYB12 was a positive regulator of drought response. Overexpression of ZmMYB12 in Arabidopsis thaliana resulted in less ROS accumulation and more lateral roots than WT, thus elevating drought resistance. After low phosphorus stress, ZmMYB12 overexpression Arabidopsis had more lateral roots and stronger root system, as well as higher contents of chlorophyll and anthocyanin. The content of inorganic phosphorus in ZmMYB12 overexpression Arabidopsis was also higher than WT. In conclusion, this study indicates that ZmMYB12 positively regulates drought response and increases the uptake and utilization of phosphorus in plants, providing an elite gene for maize breeding to increase abiotic resistance.

Key words: maize, MYB, drought stress, low phosphorus stress, root

王丽平, 王晓钰, 傅竞也, 王强. 玉米转录因子ZmMYB12提高植物抗旱性和低磷耐受性的功能鉴定[J]. 作物学报, 2024, 50(1): 76-88.

WANG Li-Ping, WANG Xiao-Yu, FU Jing-Ye, WANG Qiang. Functional identification of maize transcription factor ZmMYB12 to enhance drought resistance and low phosphorus tolerance in plants[J]. Acta Agronomica Sinica, 2024, 50(1): 76-88.

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引物名称 Primer name	引物序列 Primer sequence (5'-3')	引物用途 Primer usage
ZmMYB12-F	ATGGGGAGAGCTCCGTGCTG	基因克隆
ZmMYB12-R	CTAATTCATCCCAAGCTTTC	Gene cloning
MYB12-VIGS-F	TGTCCGAGTCTGAGGTACCAGTCGCGCAACAAGG	病毒诱导基因沉默
MYB12-VIGS-R	GAAGGGGAGGTTCTAGACAGCTCCTCCCAGCT	Virus induced gene silencing (VIGS)
p3301-ZmMYB12-F	AAACCATGG ATGGGGAGAGCTCCGTGCTG	植物表达载体构建
p3301-ZmMYB12-R	AAAAGATCT CTAATTCATCCCAAGCTTTC	Plant expression vector construction
ZmMYB12-qPCR-F	CTGCGACAAGGCTACTGTGA	qRT-PCR检测
ZmMYB12-qPCR-R	GTTTGGCCGGAGGTAGTTGA	qRT-PCR detection
ZmEf1a-qPCR-F	TGGTGTCATCAAGCCTGGTA	内参引物
ZmEf1a-qPCR-R	AACATTGTCACCCGGAAGAG	Control primer