共生
生物合成
生物
基因敲除
不规则嗜根菌
植物
丛枝菌根真菌
脂肪酸
生物化学
丛枝菌根
细胞生物学
基因
脂肪酸去饱和酶
营养物
殖民地化
代谢途径
突变体
计算生物学
菌根真菌
拟南芥
拟南芥
新陈代谢
陆生植物
寄主(生物学)
调节器
转录组
植物代谢
植物发育
功能(生物学)
作者
Liqun He,Shibei Ge,Lan Li,Yuhong Mei,Ruicheng Liu,Rui Lin,Lingyu Wang,Huijia Kang,Jingquan Yu,Hannah Rae Thomas,Yanhong Zhou
摘要
Arbuscular mycorrhizal symbiosis (AMS) is a ubiquitous mutualistic interaction between many terrestrial plants and fungi, with lipids playing a pivotal role in nutrient exchange. However, few genetic regulators of AMS have been functionally validated in tomato. To investigate candidate genes, we employed CRISPR-Cas9 and VIGS to generate knockout and knockdown lines. A comprehensive suite of molecular biology techniques, including yeast-1/2-hybridization, BiFC, ChIP-qPCR, and RNA-sequencing, was used to elucidate the regulatory roles of SlWRI5a, SlHY5, and SlFatM in fatty acid (FA) biosynthesis and AMS in tomato. FA composition was analyzed using gas chromatography. In this study, we validated SlWRI5a and SlFatM as key regulators of 16-carbon FA biosynthesis during AMS in tomato and demonstrated physical interactions between SlWRI5a and SlHY5. SlHY5 expression was induced by AMS and promoted root FA biosynthesis. Finally, we demonstrated that SlWRI5a and SlHY5 can co-regulate SlFatM-mediated FA accumulation, thereby influencing AMF colonization efficiency in tomato. Our findings reveal the SlWRI5a/SlHY5-SlFatM regulatory module, offering new insights into lipid-mediated AMS in tomato. This work also highlights a novel role for HY5 during fungal symbiosis, underscoring its broader significance in plant-microbe interactions.
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