Abstract

Abstract Verticillium dahliae is a soil‐borne, phytopathogenic fungus that causes Verticillium wilt in cotton. Salt tolerance of cotton plants suffering from Verticillium wilt was significantly improved, but the mechanism is unknown. In this study, we built a symbiont named Cotton≡VD by immersing cotton plant roots into Verticillium dahliae liquid for four days. This resulted in a strong interaction between hyphae and the cotton roots. Under NaCl treatment for 24 h, the Cotton≡VD displayed less leaf wilting and improved root growth compared with the control. Biochemical tests of SOD, POD and CAT showed significant overexpression in Cotton≡VD compared with CK. RNA‐seq data analysis of Cotton≡VD indicated a novel ‘galactose metabolism pathway’ in the KEGG database, in which two key genes, GolS2 and RFS5 , were significantly differentially expressed. Symbiotic metabolites inositol galactosyl could be transformed into raffinose to scavenge free radicals and participate in plant osmotic regulation to alleviate salt stress in Cotton≡VD. Functional analysis indicated that silencing of the target gene GhRFS ( RFS5 ) led to a decrease of raffinose content and salt tolerance as compared with CK. Cotton≡VD can significantly improve cotton seedling salt tolerance through improving raffinose content, providing new insights into the salt tolerance mechanism and new salt‐tolerant material in the future.