Dicer-mediated RNA silencing is the key regulatory mechanism in the biocontrol fungusClonostachys rosea-wheat interactions

AbstractThe intricate molecular interplay between beneficial fungi and plants is vital to plant growth promotion and induced defense response. This study explored the role of DCL-mediated RNA silencing in the interaction between the biocontrol fungusClonostachys roseaand wheat roots. We investigated the impact of DCL (Dicer-like) gene deletions inC. roseaon its root colonization ability. Our results revealed that the deletion ofdcl2significantly enhancedC. roseabiomass on wheat roots, indicating a pivotal role of DCL2 in root colonization. Transcriptome sequencing ofC. roseaand wheat during their interactions unveiled extensive gene expression changes. In wheat, genes related to stress responses were upregulated duringC. roseainteractions, while genes associated with plant cell wall modification and metabolic processes were downregulated, suggesting complex regulatory responses and a trade-off between defense mechanisms and growth promotion. Deletion ofC. rosea dcl1anddcl2altered the transcriptomic responses of wheat roots during interactions. Wheat genes associated with stress responses were downregulated during interactions with DCL deletion strains. In contrast, genes involved in metabolic processes and growth were upregulated, emphasizing the cross-kingdom regulatory role ofC. roseasmall RNAs (sRNAs). We identified 18 wheat miRNAs responsive toC. roseainteractions. Furthermore, we identified 24 endogenous and six cross-kingdom potential gene targets for seven and five differentially expressed miRNAs, supported by their inverse gene expression pattern. InC. rosea, we found a large transcriptional reprogramming of genes during interaction with wheat roots. The upregulated genes were associated with carbohydrate and polysaccharide catabolic processes, membrane transporters and effectors. Conversely, downregulated genes were mainly associated with transition metal ion transport and homeostasis processes. The deletion ofdcl1anddcl2had significant effects on gene expression. A higher number of genes upregulated in WT during the interaction were restored in DCL deletion mutants, suggesting DCL-mediated gene expression regulation. Furthermore, we identified 21 differentially expressed micro-RNA-like RNAs (milRNAs) inC. rosea; nine were DCL-dependent. They had putative gene targets inC. rosea, including transcription factors, effectors, transporters, and enzymes involved in specialized metabolite production. Cross-kingdom RNA silencing was also observed, with seven DCL-dependentC. roseamilRNAs potentially targeting 29 genes in wheat. These findings provide valuable insights into the molecular mechanisms underlying the beneficial interaction between fungi and plant roots. In addition, the study shed light on the role of sRNA-mediated gene regulation in theC. rosea-wheat interaction, with potential implications for sustainable agriculture and biocontrol strategies.