Apple replant disease (ARD) is a worldwide problem that threatens the industry. However, the genetic mechanism underlying plant disease resistance against ARD remains unclear. In this study, a negative regulatory microRNA in Malus domestica, mdm-miR397b \, and its direct target MdLAC7b (Laccase) was selected for examination based on our previous small RNA and degradome sequencing results.

 

Overexpressing the mdm-miR397b-MdLAC7b module altered the lignin deposition and JA contents in apple roots, which also led to increased resistance to Fusarium solani. Additionally, Y1H library screening using mdm-miR397b promoter recombinants identified a transcription factor, MdERF61, that represses mdm-miR397b transcriptional activity by directly binding to two GCC-boxes in the mdm-miR397b promoter.

 

In summary, our results suggest that the MdERF61-mdm-miR397b-MdLAC7b module plays a crucial role in apple resistance to F. solani and offers insights for enhancing plant resistance to soilborne diseases in apple.