Ya-Zhou Zhang, Jie Man, Lan Wen, Si-Qi Tan, Shun-Li Liu, Ying-Hui Li, Peng-Fei Qi, Qian-Tao Jiang, Yu-Ming Wei
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引用次数: 0
摘要
ATP 结合盒(ABC)转运体通过水解 ATP 来转运各种底物。以前的研究表明,ABC 转运体负责转运植物激素和重金属,从而促进植物免疫。在此,我们发现了一种小麦 G 型 ABC 转运体 TaABCG2-5B,它能对水杨酸(SA)处理做出反应,并能被禾谷镰刀菌诱导,禾谷镰刀菌是导致镰刀菌头枯病(FHB)的主要病原体。TaABCG2-5B 的功能缺失突变(ΔTaabcg2-5B)减少了 SA 的积累,增加了对禾谷镰刀菌的敏感性。相反,过表达 TaABCG2-5B(OE-TaABCG2-5B)则会产生相反的效果。对 ΔTaabcg2-5B 和 OE-TaABCG2-5B 原生质体中细胞内 SA 的定量分析显示,TaABCG2-5B 起着进口商的作用,促进 SA 向细胞质的运输。在小麦根中进行的 Cd2+ 吸收实验进一步证实了这一作用,表明 TaABCG2-5B 也参与了 Cd2+ 的运输。因此,TaABCG2-5B 作为一个输入器,对多种底物的转运至关重要。值得注意的是,同源基因 TaABCG2-5A 也能促进小麦根系对 Cd2+ 的吸收,但对 SA 积累和 FHB 抗性没有显著影响。因此,TaABCG2 可能是增强小麦对 Cd2+ 的耐受性和提高 FHB 抗性的一个有价值的靶标。
ATP-binding cassette transporter TaABCG2 contributes to Fusarium head blight resistance by mediating salicylic acid transport in wheat.
ATP-binding cassette (ABC) transporters hydrolyse ATP to transport various substrates. Previous studies have shown that ABC transporters are responsible for transporting plant hormones and heavy metals, thus contributing to plant immunity. Herein, we identified a wheat G-type ABC transporter, TaABCG2-5B, that responds to salicylic acid (SA) treatment and is induced by Fusarium graminearum, the primary pathogen causing Fusarium head blight (FHB). The loss-of-function mutation of TaABCG2-5B (ΔTaabcg2-5B) reduced SA accumulation and increased susceptibility to F. graminearum. Conversely, overexpression of TaABCG2-5B (OE-TaABCG2-5B) exerted the opposite effect. Quantification of intracellular SA in ΔTaabcg2-5B and OE-TaABCG2-5B protoplasts revealed that TaABCG2-5B acts as an importer, facilitating the transport of SA into the cytoplasm. This role was further confirmed by Cd2+ absorption experiments in wheat roots, indicating that TaABCG2-5B also participates in Cd2+ transport. Thus, TaABCG2-5B acts as an importer and is crucial for transporting multiple substrates. Notably, the homologous gene TaABCG2-5A also facilitated Cd2+ uptake in wheat roots but did not significantly influence SA accumulation or FHB resistance. Therefore, TaABCG2 could be a valuable target for enhancing wheat tolerance to Cd2+ and improving FHB resistance.
期刊介绍:
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