Surface acoustic wave biosensors are a powerful tool for the study of biomolecular interactions. The modulation of a surface-confined acoustic wave is utilized here for the analysis of surface binding. Phase and amplitude of the wave correspond roughly to mass loading and viscoelastic properties of the surface, respectively. We established a procedure to reconstitute phospholipid and lipopolysaccharide bilayers on the surface of a modified gold sensor chip to study the mode of action of membrane-active peptides. The procedure included the formation of a self-assembled monolayer of 11-mercaptoundecanol, covalent coupling of carboxymethyl-dextran, and subsequent coating with a poly- l-lysine layer. The lipid coverage of the surface is highly reproducible and homogeneous as demonstrated in atomic force micrographs. Ethanol/triton treatment removed the lipids completely, which provided the basis for continuous sequences of independent experiments. The setup was applied to investigate the binding of human cathelicidin-derived peptide LL32, as an example for antimicrobial peptides, to immobilized phosphatidylserine membranes. The peptide-membrane interaction results in a positive phase shift and an increase in amplitude, indicating a mass increase along with a loss in viscosity. This suggests that the bilayer becomes more rigid upon interaction with LL32.
Defensins represent a major component of innate host defense against bacteria, fungi, and enveloped viruses. One potent defensin found, e.g., in epithelia, is the polycationic human beta-defensin-3 (hBD3). We investigated the role of the lipid matrix composition, and in particular the presence of negatively charged lipopolysaccharides (LPS) from sensitive (Escherichia coli, Salmonella enterica serovar Minnesota) or resistant (Proteus mirabilis) Gram-negative bacteria or of the zwitterionic phospholipids of human cells, in determining the action of polycationic hBD3 on the different membranes, and related to their biological activity. The main focus was directed on data derived from electrical measurements on a reconstitution system of the OM as a planar asymmetric bilayer composed on one side of LPS and on the other of a phospholipid mixture. Our results demonstrate that the antimicrobial activity and the absence of cytotoxicity can be explained by the lipid-specificity of the peptide. A clear correlation between these aspects of the biological activity of hBD3 and its interaction with lipid matrices could be found. In particular, hBD3 could only induce lesions in those membranes resembling the lipid composition of the OM of sensitive bacterial strains. The permeation through the membrane is a decisive first step for the biological activity of many antimicrobial peptides. Therefore, we propose that the lipid-specificity of hBD3 as well as some other membrane-active antimicrobial peptides is important for their activity against bacteria or mammalian cells.
The architecture of the lipid matrix of the outer membrane of Gram-negative bacteria is extremely asymmetric: Whereas the inner leaflet is composed of a phospholipid mixture, the outer leaflet is built up by glycolipids. For most Gram-negative species, these glycolipids are lipopolysaccharides (LPS), for a few species, however, glycosphingolipids. We demonstrate experimental approaches for the reconstitution of these asymmetric membranes as (i) solid supported membranes prepared by the Langmuir-Blodgett technique, (ii) planar lipid bilayers prepared by the Montal-Mueller technique, and (iii) giant unilamellar vesicles (GUVs) prepared by the phase transfer method. The asymmetric GUVs (aGUVs) composed of LPS on one leaflet are shown for the first time. They are characterized with respect to their phase behavior, flipflop of lipids and their usability to investigate the interaction with membrane active peptides or proteins. For the antimicrobial peptide LL-32 and for the bacterial porin OmpF the specificity of the interaction with asymmetric membranes is shown. The three reconstitution systems are compared with respect to their usability to investigate domain formation and interactions with peptides and proteins.
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