Modes of action and in planta antifungal activity of Olea europaea defensin OefDef1.1-derived peptide variant

Peptide-based biopesticides represent a promising strategy for sustainable disease control in agriculture. Synthetic antifungal peptides incorporating the {gamma}-core motif of plant defensins offer multiple modes of action (MoA) and potential as biofungicides. We investigated a synthetic variant of the olive defensin OefDef1.1 for antifungal activity, structure-function relationships, and MoA against Botrytis cinerea, the necrotrophic pathogen causing gray mold. A disulfide-bridged peptide, GMAOe1C_V1*, derived from OefDef1.1 (G32-Y53) and modified with hydrophobic amino acid substitutions, inhibited B. cinerea growth in vitro and reduced lesion formation in detached leaves. Foliar application of GMAOe1C_V1* suppressed disease symptoms in pepper plants. Mechanistically, GMAOe1C_V1* rapidly permeabilized fungal plasma membranes and accumulated in vacuoles, triggering vacuolar expansion and cell death. It also inhibited protein synthesis in vitro and in vivo, suggesting a role as a translation inhibitor. Alanine scanning mutagenesis of the non-disulfide bridged variant identified the 7RHSKH11 motif as essential for antifungal activity. Circular dichroism revealed an unstructured conformation with minimal secondary structure. Transcriptomic analysis of GMAOe1C_V1* treated B. cinerea germlings showed downregulation of genes involved in mitochondrial function and amino acid biosynthesis. These findings demonstrate the potential of an olive defensin-derived peptide as a bio-inspired antifungal agent with multifaceted MoA, supporting its development for crop protection.