Interaction of Model Class A1, Class A2, and Class Y Amphipathic Helical Peptides with Membranes

Abstract

To test the hypothesis that differences in the lipid affinity of exchangeable apolipoproteins are due to the presence of different classes of amphipathic α-helical motifs which differ primarily in the distribution of charged amino acid residues, we designed and synthesized model peptides mimicking class A₁, class A₂, and class Y amphipathic helices present in these apolipoproteins. Both class A₁ and class A₂ helices have positive residues at the polar−nonpolar interface and negative residues at the center of the polar face. However, clustering of positive and negative residues is less exact in class A₁ compared to class A₂ helices. The class Y helices have two negative residue clusters on the polar face separating the two arms and the base of the Y motif formed by three positive residue clusters. The lipid affinities of three 18 residue model peptides representing these classes, Ac-18A₁-NH₂ (Ac-ELLEKWAEKLAALKEALK-NH₂), Ac-18A₂-NH₂ (Ac-ELLEKWKEALAALAEKLK-NH₂), and Ac-18Y-NH₂ (Ac-ELLKAWKEALEALKEKLA-NH₂), were determined by right-angle light scattering, circular dichroism spectroscopy, differential scanning calorimetry, and fluorescence spectroscopy. The observed rank order of lipid affinity of these three peptides is: Ac-18A₂-NH₂ > Ac-18Y-NH₂ > Ac-18A₁-NH₂. This order is consistent with the known lipid affinity of exchangeable apolipoproteins containing class A₁, class A₂, and class Y helices (class A₂ > class Y > class A₁). Results of this study illustrate the important role of interfacial lysine residues in modulating the lipid affinity of amphipathic helices and suggest that the effect of interfacial lysine residues in increasing lipid affinity is additive. We propose that interfacial lysine residues, in addition to widening the hydrophobic face because of snorkeling, also help anchor the amphipathic helix in the lipid bilayer.