Antimicrobial peptides (AMPs) are promising candidates in combating multidrug-resistant microorganisms because of their unique mode of action. Among these peptides, ultrashort AMPs (USAMPs) possess sequences containing less than 10 amino acids and have some advantages over traditional AMPs. However, one of the main limitations of designing novel and highly active USAMPs is that their mechanism of action at the molecular level is not well-known. In this article, we report the antimicrobial mechanism of the USAMP verine (RWV) with high antibacterial activity against . Here, by using well-tempered bias-exchange metadynamics simulations and long-time conventional molecular dynamics simulations, we evaluated whether verine exhibits the same antimicrobial mode of action as that of traditional AMPs. The single verine-membrane system exhibited a relatively flat surface with multiple shallow minima separated by very small energy barriers and adopted highly dynamic structural ensembles. Although the verine sequence is very short, it can still exist briefly in the center of the cell membrane in a transmembrane state. As the concentration of verine increased, the transmembrane conformation was relatively stabilized in the membrane center or proceeded toward the membrane bottom. The lipid bilayer membrane showed relatively large deformation, including the phospholipid head groups embedded inside the lipid hydrophobic center, accompanied by a flip-flop of some lipids. Simulation results indicated that verine has a specific mechanism of action different from that of traditional AMPs. Based on this antimicrobial mechanism of verine, we can design new high-potential USAMPs by enhancing the structural stability of the transmembrane state.
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