Effects of Amphipathic Polypeptides on Membrane Organization Inferred from Studies Using Bicellar Lipid Mixtures

Fragmentation of DMPC Membranes by a Wedge-Shaped Amphiphilic Cyclodextrin into Bicellar-like Aggregates

Small bilayer lipid aggregates such as bicelles provide useful isotropic or anisotropic membrane mimetics for structural studies of biological membranes. We have shown previously by deuterium NMR that a wedge-shaped amphiphilic derivative of trimethyl βcyclodextrin anchored in deuterated DMPC-d27 bilayers through a lauryl acyl chain (TrimβMLC) is able to induce magnetic orientation and fragmentation of the multilamellar membranes. The fragmentation process fully detailed in the present paper is observed with 20% cyclodextrin derivative below 37 °C, where pure TrimβMLC self-assembles in water into large giant micellar structures. After deconvolution of a broad composite ²H NMR isotropic component, we propose a model where the DMPC membranes are progressively disrupted by TrimβMLC into small and large micellar aggregates depending whether they are extracted from the outer or inner layers of the liposomes. Below the fluid-to-gel transition of pure DMPC-d27 membranes (T_c = 21.5 °C), the micellar aggregates vanish progressively until complete extinction at 13 °C, with a probable release of pure TrimβMLC micelles leaving lipid bilayers in the gel phase doped with only a small amount of the cyclodextrin derivative. Bilayer fragmentation between T_c and 13 °C was also observed with 10% and 5% of TrimβMLC, with NMR spectra suggesting possible interactions of micellar aggregates with fluid-like lipids of the P_β' ripple phase. No membrane orientation and fragmentation was detected with unsaturated POPC membranes, which are able to accommodate the insertion of TrimβMLC without important perturbation. The data are discussed in relation to the formation of possible DMPC bicellar aggregates such as those known to occur after insertion of dihexanoylphosphatidylcholine (DHPC). These bicelles are in particular associated with similar deuterium NMR spectra exhibiting identical composite isotropic components which were never characterized before.

Effects of fluidity and charge density on the morphology of a bicellar mixture - A SANS study

The spontaneously formed structures of physiologically relevant lipid model membranes made of 1-palmitoyl-2-oleoyl-sn-glycero-3-phosphocholine, 1-palmitoyl-2-oleoyl-sn-glycero-3-phospho-(1'-rac-glycerol) and 1,2-hexanoyl-sn-glycero-3-phosphocholine have been evaluated in depth using small angle neutron scattering. Although a common molar ratio of long- to short- chain phospholipids (~4) as reported in many bicellar mixtures was used, discoidal bicelles were not found as the major phase throughout the range of lipid concentration and temperature studied, indicating that the required condition for the formation of bicelle is the immiscibility between the long- and short- chain lipids, which were in the gel and L_α phases, respectively, in previous reports. In this study, all lipids are in the L_α phase. The characterization outcome suggests that the spontaneous structures tie strongly with the physical parameters of the system such as melting transition temperature of the long-chain lipid, total lipid concentration and charge density of the system. Multilamellar vesicles, unilamellar vesicles, ribbons and perforated lamellae can be obtained based on the analysis of the small angle neutron scattering results, leading to the construction of structural diagrams. This report provides the important map to choose suitable lipid systems for the structural study of membrane-associated proteins, design of theranostic nanocarriers or other related research fields.

Role of Charge in Lipid Vesicle Binding and Vesicle Surface Saturation by Gaduscidin-1 and Gaduscidin-2

The histidine-rich antimicrobial peptides Gad-1 and Gad-2, from paralogous genes in cod, provide an opportunity to examine the effect of charge and nonelectrostatic factors on peptide-vesicle interaction and on peptide antimicrobial activity. In this study, the dependence of vesicle ζ-potential on peptide concentration has been used to examine the binding of these peptides to model vesicle surfaces at pH = 5.0, for which the charges of Gad-1 and Gad-2 are +8 and +5, respectively, and at pH = 7.0, where their charges are +3 and +1, respectively. Interpreting the observed ζ-potential behaviors as examples of Langmuir adsorption isotherms, it is possible to infer the equilibrium constant for peptide-vesicle binding, the fraction of the peptide bound at low peptide concentration, and the maximum peptide-to-lipid ratio when the vesicle surface is saturated at high peptide concentration. For both peptides, higher peptide charge is found to be correlated with a lower fraction of the peptide being bound to vesicle surfaces at low peptide concentration and with a smaller maximum bound peptide-to-lipid ratio at high peptide concentration. The equilibrium binding constant, on the other hand, is more strongly correlated with the peptide sequence than with the charge. Gad-1, which has been shown to be more biologically active than Gad-2, displayed a significantly higher equilibrium binding constant. These observations suggest that while the maximum peptide density on the vesicle surface is limited by electrostatic interactions, the free energy of peptide binding, like the observed antimicrobial activities of the Gad peptides, is also sensitive to other peptide factors which might, for example, influence hydrophobic interactions.