Structural dynamics influences the antibacterial activity of a cell-penetrating peptide (KFF)3K

Given the widespread demand for novel Antibacterial agents, we modified a cell-penetrating peptide (KFF)₃K to transform it into an Antibacterial peptide. Namely, we inserted a hydrocarbon staple into the (KFF)₃K sequence to induce and stabilize its membrane-active secondary structure. The staples were introduced at two positions, (KFF)₃K[5-9] and (KFF)₃K[2-6], to retain the initial amphipathic character of the unstapled peptide. The stapled analogues are Protease resistant contrary to (KFF)₃K; 90% of the stapled (KFF)₃K[5-9] peptide remained undigested after incubation in chymotrypsin solution. The stapled Peptides showed Antibacterial activity (with minimal inhibitory concentrations in the range of 2-16 µM) against various Gram-positive and Gram-negative strains, contrary to unmodified (KFF)₃K, which had no Antibacterial effect against any strain at concentrations up to 32 µM. Also, both stapled Peptides adopted an α-helical structure in the buffer and micellar environment, contrary to a mostly undefined structure of the unstapled (KFF)₃K in the buffer. We found that the Antibacterial activity of (KFF)₃K analogues is related to their disruptive effect on cell membranes and we showed that by stapling this cell-penetrating peptide, we can induce its Antibacterial character.