木质素
生物合成
生物
植物
盐度
盐(化学)
假单胞菌
作物
突变体
拟南芥
代谢途径
植物生理学
生物化学
化学
微生物
拟南芥
细菌
铁载体
殖民地化
植物种类
转基因作物
防御机制
非生物胁迫
植物对草食的防御
土壤盐分
作者
Yanfen Zheng,Youqiang Wang,Ziyan Wang,Z Y Li,Jonathan D. Todd,Chen Meng,Shutian Hua,Xiaona Sui,Qingchen Rui,Siqi Ma,Yiqiang Li,Jiwen Liu,Dong‐Lin Zhao,Chengsheng Zhang
出处
期刊:Science Advances
[American Association for the Advancement of Science]
日期:2026-06-24
卷期号:12 (26): eaed8447-eaed8447
标识
DOI:10.1126/sciadv.aed8447
摘要
Root-associated microbiota play a critical role in plant tolerance to salt stress. However, the conservation of beneficial interactions across diverse crops and soils and the underlying mechanisms remain unclear. Here, we show that pseudomonads were consistently enriched in salt-stressed plant roots across multiple soil types and most crop species. Comparative genomics revealed that these pseudomonads harbored unique genomic signatures associated with high salinity tolerance, such as Na + transporters. Pseudomonad isolates from salt-stressed plants robustly colonized soybean roots and significantly improved salt tolerance under both greenhouse and field conditions. Pseudomonads-dependent plant salt stress tolerance was mediated through plant lignin biosynthesis stimulation rather than the canonical mechanism of Na + homeostasis. Overexpression of the key plant lignin biosynthesis genes, including GmCAD , GmCOMT , and Gm4CL , significantly enhanced soybean growth under salt stress. Furthermore, mutant plants deficient in lignin biosynthesis no longer showed pseudomonads-induced salt tolerance. Collectively, our findings reveal a previously unrecognized microbial-mediated pathway that enhances plant resilience to salt stress.
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