Co-application of fungal metabolites and nanoparticles control bacterial wilt disease by regulating rhizosphere soil microbial communities

Abstract

Numerous techniques have been adopted to promote crop growth and improve the effectiveness of biological control. One of these strategies includes the utilization of antimicrobial metabolites from biocontrol agents combined with other strategies. Nanotechnology is a novel and emerging trend in controlling plant diseases. The present study aimed to improve the understanding through an assessment of the mechanism of how the co-application of nanoparticles (SiNPS) and fungal metabolites prevent tomato bacterial wilt infection and explore how the applied treatments regulate the soil microbial community structures present in the rhizosphere of tomato plants. It was demonstrated under in-vitro conditions that the silicon nanoparticles and metabolites of fungi restricted the growth of Ralstonia solanacearum, the causal agent of bacterial wilt. The combined application of nanoparticles and fungal metabolites during planta investigation significantly reduced the disease severity and improved plant growth. These treatments caused significant changes in rhizosphere microbial communities and enhanced the abundance of plant-beneficial microbes. The results of the current study hence advocate the application of fungal metabolites and SiNPS as an effective and environment-friendly strategy for controlling the wilt disease of bacteria in tomato plants and various other host crops.