Terminal charges modulate the pore forming activity of cationic amphipathic helices.

KIA peptides are a series of designer-made cationic amphipathic α-helical antimicrobial peptides of different lengths, based on the repetitive sequence [KIAGKIA]. They can form toroidal pores in membranes, wherein the helices are aligned in a transmembrane orientation. Solid-state 15N NMR is used here to differentiate between the surface-bound and transmembrane states. We find that the pore-forming activity increases when the peptides carry a positive charge (Lys residue) at the N-terminus, compared to a hydrophobic Ile-Ala N-terminal motif. In contrast, a positive charge at the C-terminus gives a lower membrane activity compared to C-terminal Ile-Ala. For peptides with otherwise identical sequence, a more than ten-fold difference in vesicle leakage can be observed, depending on which terminus carries the charge. This difference is attributed to a shift in the equilibrium between peptide helices oriented on the membrane surface and those inserted into the membrane in a pore-forming state. We show that the 3D hydrophobic moment can be used to predict which peptide sequence is more prone to form pores and will thereby show a higher membranolytic activity.

Chiral supramolecular architecture of stable transmembrane pores formed by an α-helical antibiotic peptide in the presence of lyso-lipids.

The amphipathic α-helical antimicrobial peptide MSI-103 (aka KIA21) can form stable transmembrane pores when the bilayer takes on a positive spontaneous curvature, e.g. by the addition of lyso-lipids. Solid-state 31P- and 15N-NMR demonstrated an enrichment of lyso-lipids in these toroidal wormholes. Anionic lyso-lipids provided additional stabilization by electrostatic interactions with the cationic peptides. The remaining lipid matrix did not affect the nature of the pore, as peptides maintained the same orientation independent of lipid charge, and a change in membrane thickness did not considerably affect their tilt angle. Under optimized conditions (i.e. in the presence of lyso-lipids and appropriate bilayer thickness), stable and well-aligned pores could be obtained for solid-state 2H-NMR analysis. These data revealed for the first time the complete 3D alignment of this representative amphiphilic peptide in fluid membranes, which is compatible with either monomeric helices as constituents, or left-handed supercoiled dimers as building blocks from which the overall toroidal wormhole is assembled.