Colonization of Mollisia sp. Su100, a novel root endophytic fungus, promoted Catalpa bungei growth under nitrogen deficiency by accumulating melatonin and remodeling fatty acid metabolism

Nitrogen is one of the essential nutrients for plant growth and development. The utilization of beneficial rhizosphere microorganisms is one of the effective ways to increase the nitrogen use efficiency, which is critical to achieving high yields in agricultural and forestry crops. Mollisia sp. Su100 is a novel endophytic fungus previously reported. However, colonization effects and molecular mechanisms of Su100 on the host plants remains unexplored. In this study, we found that Su100 efficiently colonized within the roots of Catalpa bungei seedlings and the inoculated group significantly outperformed the control group in terms of both growth and physiological indicators under nitrogen deficiency. The roots of the inoculated group exhibited lower ROS levels, higher AsA content, and stronger APX activity than those of the control, suggesting that Su100 enhanced the ROS scavenging capacity of the key non-enzymatic antioxidant AsA. Compared to the control group, the inoculated group had higher levels of AMT and NRT expression, as well as higher NO3- and NH4+ content and NR and GS enzyme activities. These results suggested that Su100 improved the nitrogen uptake and assimilation capacity of C. bungei seedlings under nitrogen deficiency. Furthermore, the melatonin (MT) content in the roots of the inoculated group increased, as did the expression levels of genes associated with auxin and BR signaling. Another significant effect of Su100 on C. bungei roots is the alteration of fatty acid (FA) metabolism, which is primarily manifested by promoting very-long-chain fatty acids (VLCFAs) synthesis, wax and suberin accumulation, and remodeling of phosphoglyceride (PG) metabolic pathways. In particular, the contents of phosphatidylcholine (PC) and phosphatidylethanolamine (PE) as well as their molar ratio were altered by Su100 colonization. To our knowledge, this is the first report that root endophytic fungi enhance host plant tolerance to nitrogen deficiency stress by MT enrichment and FA metabolism remodeling.