Structure–activity relations of parasin I, a histone H2A-derived antimicrobial peptide

The structure–activity relations and mechanism of action of parasin I, a 19-amino acid histone H2A-derived antimicrobial peptide, were investigated. Parasin I formed an amphipathic α-helical structure (residues 9–17) flanked by two random coil regions (residues 1–8 and 18–19) in helix-promoting environments. Deletion of the lysine residue at the N-terminal [Pa(2–19)] resulted in loss of antimicrobial activity, but did not affect the α-helical content of the peptide. The antimicrobial activity was recovered when the lysine residue was substituted with another basic residue, arginine ([R1]Pa), but not with polar, neutral, or acidic residues. Progressive deletions from the C-terminal [Pa(1–17), Pa(1–15)] slightly increased the antimicrobial activity (1–4 μg/ml) without affecting the α-helical content of the peptide. However, further deletion [Pa(1–14)] resulted in nearly complete loss of antimicrobial activity and α-helical structure. Confocal microscopic analysis and membrane permeabilization assays showed that parasin I and its analogs with comparable antimicrobial activities localized to the cell membrane and subsequently permeabilized the outer and cytoplasmic membranes. Pa(1–14) also localized to the cell membrane, but lost membrane-permeabilizing activity, whereas Pa(2–19) showed poor membrane-binding and -permeabilizing activities. The results indicate that the basic residue at the N-terminal is essential for the membrane-binding activity of parasin I, and among the membrane-binding parasin I analogs, the α-helical structure is necessary for the membrane-permeabilizing activity.