Summary
Antimicrobial proteins are ancient and widespread molecules that contribute to survival across all domains of life. We previously showed that fungal plant pathogens secrete antimicrobial proteins to suppress antagonistic members of the host microbiota and thereby promote host colonization. The soil-borne plant pathogen Verticillium dahliae employs the bactericidal protein VdAve1 for this purpose. Here, we elucidate the mode of action of VdAve1 and define its mechanism as a distinct type of antimicrobial activity. Nuclear magnetic resonance (NMR) analysis revealed that VdAve1 adopts a jelly-roll barrel-like fold. Functionally, VdAve1 disrupts bacterial plasma membranes, and synthetic peptides derived from its positively charged regions retain antimicrobial activity, indicating that these regions contribute to its function. We further show that the bacterial model system Bacillus subtilis responds to VdAve1 by modifying teichoic acids, and that loss of these modifications increases bacterial sensitivity. Consistent with this, VdAve1 binds lipoteichoic acid (LTA), a major component of the Gram-positive cell wall. Together, our findings support a model in which VdAve1 binds LTA to localize at the bacterial surface, where it perturbs the plasma membrane, leading to membrane collapse and cell death. SIGNIFICANCE STATEMENTPlant-pathogenic microbes secrete effector proteins to promote host colonization. While these proteins are typically studied for their roles in host manipulation, some affect host-associated microbial communities by exhibiting antimicrobial activity. However, their modes of action remain largely unexplored. The fungal plant pathogen Verticillium dahliae secretes the antimicrobial effector VdAve1 to inhibit bacterial antagonists in the host microbiota. Here, we characterize the mode of action of VdAve1. We show that VdAve1 binds lipoteichoic acid, a major component of the cell wall of Gram-positive bacteria. This promotes VdAve1 accumulation close to the plasma membrane, and through electrostatic interactions it disrupts the plasma membrane. We further determine VdAve1 structure by NMR, revealing VdAve1 adopts a {beta}-barrel-like fold. Together, our findings show the mechanism by which a fungal effector inhibits bacterial growth and thereby how it may influence host-associated bacterial communities.
Outcomes reported
Antimicrobial proteins are ancient and widespread molecules that contribute to survival across all domains of life. We previously showed that fungal plant pathogens secrete antimicrobial proteins to suppress antagonistic members of the host microbiota and thereby promote host colonization. The soil-borne plant pathogen Verticillium dahliae employs the bactericidal protein VdAve1 for this purpose. Here, we elucidate the mode of action of VdAve1 and define its mechanism as a distinct type of antimicrobial activity. Nuclear magnetic resonance (NMR) analysis revealed that VdAve1 adopts a jelly-roll barrel-like fold. Functionally, VdAve1 disrupts bacterial plasma membranes, and synthetic peptides derived from its positively charged regions retain antimicrobial activity, indicating that these regions contribute to its function. We further show that the bacterial model system Bacillus subtilis responds to VdAve1 by modifying teichoic acids, and that loss of these modifications increases bacterial sensitivity. Consistent with this, VdAve1 binds lipoteichoic acid (LTA), a major component of the Gram-positive cell wall. Together, our findings support a model in which VdAve1 binds LTA to localize at the bacterial surface, where it perturbs the plasma membrane, leading to membrane collapse and cell death. SIGNIFICANCE STATEMENTPlant-pathogenic microbes secrete effector proteins to promote host colonization. While these proteins are typically studied for their roles in host manipulation, some affect host-associated microbial communities by exhibiting antimicrobial activity. However, their modes of action remain largely unexplored. The fungal plant pathogen Verticillium dahliae secretes the antimicrobial effector VdAve1 to inhibit bacterial antagonists in the host microbiota. Here, we characterize the mode of action of VdAve1. We show that VdAve1 binds lipoteichoic acid, a major component of the cell wall of Gram-positive bacteria. This promotes VdAve1 accumulation close to the plasma membrane, and through electrostatic interactions it disrupts the plasma membrane. We further determine VdAve1 structure by NMR, revealing VdAve1 adopts a {beta}-barrel-like fold. Together, our findings show the mechanism by which a fungal effector inhibits bacterial growth and thereby how it may influence host-associated bacterial communities.
Topic tags
Dig deeper with Pulse AI.
Pulse AI has read the whole catalogue. Ask about this record, its theme, or how the findings apply to UK farming and policy — every answer cites the underlying studies.