Abstract 564: Structure-Function Studies of ApoA-I Mimetic Peptides for ABCA1-Dependent Cholesterol Efflux and HDL Formation

Abstract

To examine the mechanism of action of ApoA-I mimetics, we designed 4 peptides with a variable number of E, L, K and A residues and determined their ability to form HDL-like particle and promote ABCA1-dependent cholesterol efflux. They were named based on a unique physical property: N=ELK-neutral (EKLKELLEKLLEKLKELL), H=ELK-hydrophobic (EKLLELLKKLLELLKELL), P=ELK-positive (EKLKALLEKLKAKLKELL), Neg=ELK-negative (EELKEKLEELKEKLEEKL). CD-spectroscopy showed that H and P were mostly helical in an aqueous buffer (52% and 22%, respectively), and in a TFE-containing solvent, mimicking a lipid environment, all peptides showed greater than 40% helicity. In DMPC vesicle solubilization assay, we observed following order: P>N>H>>Neg. By non-denaturing gel electrophoresis, N, H, P formed approximately 8, 8, and 18 nm size lipid particles, respectively when combined with DMPC. However, Neg did not form any detectable particle. A mixture of natural lipids (PC:SM:LysoPC:PE:PS:PI; mol% 55:12:5:10:8:10), intended to simulate ABCA1 lipid membrane microdomain, yielded similar results . Using BHK-ABCA1 transfected cells, cholesterol efflux studies showed following results: H>N>>P, whereas Neg peptide was inactive. All-atom MD simulation of N carried out on a 12–nm disc containing POPC:cholest (200:20), 26 peptides, and initially placed in belt-like configuration as head-to-tail dimers, the starting structure was maintained for at least 3 μ-sec, indicated a strong preference for this configuration. However, when N was initially oriented in a picket-fence configuration, it distorted to a belt-like pattern within 1 μ-sec. For Neg, both starting configurations were much less stable with dimers losing their connectivity and monomers migrating to the top and bottom of the disc, leaving large hydrophobic patches of acyl chains exposed. Cross-linking studies were consistent with the ability of H and N to form dimers to stabilize the HDL structure, and thereby, were also consistent with simulation. Together, we show that a net neutral charge, a relatively large hydrophobic moment (0.78), and a broad hydrophobic face (180 degrees) are optimum features for an apoA-I mimetic peptide to promote cholesterol efflux and to stabilize a nascent discoidal HDL structure.