水稻(Oryza sativa L.)中由 ABC 转运体介导的农药苯达松的转运和代谢。

Yuxin Qiao, Yujue Wang, Yucheng Gu, Nan Zhang, Hong Yang, Jintong Liu
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引用次数: 0

摘要

简介苯达松(BNTZ)是一种选择性接触除草剂,广泛用于控制农作物生产中的田间杂草。过量使用 BNTZ 会导致其在土壤和作物中积累,成为一种环境污染物。因此,研究 BNTZ 在作物中的解毒和降解机制对于减少作物污染和确保食品安全至关重要:本研究旨在通过基因工程技术结合化学分析技术和代谢组学方法,建立表达水稻 ATP 结合盒(OSABC)转运体基因的转基因品系,从而阐明 BNTZ 复合物在水稻中的解毒和降解途径:方法:我们通过CRISPR-Cas9技术建立了过表达(OE)水稻OsABC转运体的水稻转基因品系及其基因敲除品系,以鉴定该基因的功能,并测定BNTZ残基在水稻中的积累。BNTZ的代谢物采用LC/Q-TOF-HRMS/MS(液相色谱/飞行时间-高分辨质谱)进行表征:结果:过表达OsABC可显著提高水稻的伸长率、干重和叶绿素含量,减少细胞膜损伤和BNTZ在水稻组织中的积累,从而赋予水稻对BNTZ毒性的抗性。六种不同的代谢物和十种共轭物的化学结构十分明确。OE 株系谷粒中 BNTZ 含量和降解产物的减少证明了 OsABC 基因功能的强大活性。利用 UPLC-Q-TOF/MS,我们进一步鉴定了累积的各种碳水化合物、氨基酸、激素和黄酮类化合物的基本代谢产物,发现这些参与 BNTZ 降解的代谢产物在 OE 株系中比在野生型(WT)水稻中增加得更多:我们的研究表明,OSABC 转运体在调控水稻中 BNTZ 的迁移和降解代谢中起着关键作用,从而揭示了水稻抗 BNTZ 毒性和适应环境胁迫的调控机制。
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An ABC transporter-mediated transport and metabolism of the pesticide bentazone in rice (Oryza sativa L.).

Introduction: Bentazon (BNTZ) is a selective contact herbicide widely used to control field weeds for crop production. Excessive use of BNTZ leads to its accumulation in soils and crops, becoming an environmental contaminant. Therefore, investigation of the mechanisms for BNTZ detoxification and degradation in crops is fundamentally important to reduce crop contamination and ensure food safety.

Objectives: This study aims to elucidate the mechanism of detoxification and degradation pathways of the BNTZ complex in rice by creating transgenic lines expressing a rice ATP-binding cassette (OsABC) transporter gene through genetic engineering techniques combined with chemical analytical techniques and metabolomics approaches.

Methods: We established the rice transgenic lines overexpressing (OE) a rice OsABC transporter and its knockout lines by CRISPR-Cas9 to characterize the gene function and measured the accumulation of BNTZ residues in rice. The metabolites of BNTZ were characterized by LC/Q-TOF-HRMS/MS (Liquid chromatography/time of flight-high resolution mass spectrometry).

Results: Overexpression of OsABC significantly conferred rice resistance to BNTZ toxicity by increasing plant elongation, dry weight, and chlorophyll content, and significantly reducing cell membrane damage and BNTZ accumulation in rice tissues. Six different metabolites and ten conjugates were well defined in chemical structures. The reduced BNTZ levels and degradation products in the grains of the OE lines supported the robust activity of the OsABC gene function. Using UPLC-Q-TOF/MS, we further identified accumulated basic metabolites of various carbohydrates, amino acids, hormones, and flavonoids, and found that these metabolites involved in BNTZ degradation were increased more in OE lines than in wild-type (WT) rice.

Conclusions: Our work demonstrates that the OsABC transporter plays a critical role in regulating the mobility and degradative metabolism of BNTZ in rice, thus revealing a regulatory mechanism underlying rice resistance to BNTZ toxicity and adaptation to the environmental stress.

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