melitten and 1-2-dioleoyl-sn-glycero-3-phosphoglycerol

This article presents coarse-grained molecular dynamics simulations of pore-forming antimicrobial peptide melittin and its interactions with vesicles composed of a mixture of zwitterionic and anionic phospholipids. Besides creating holes in the membrane, the adsorption of melittin also induces vesicle budding, which can develop into vesiculation at high peptide concentrations, as well as vesicle invagination, which can eventually result in a corrugated membrane surface. These rich morphology changes are mediated by the curvature of the vesicles and the peptide concentration. Highly curved vesicles favor the recruitment of melittins with a higher density of binding sites. The peptides mainly penetrate into the membrane surface in monomers via hydrophobic interaction. Lowly curved vesicles recruit melittins with a low density of binding sites. Surplus peptides are prone to form oligomers and shallowly adsorb on the surface of membrane via electrostatic interaction. The penetration of monomers induces membrane pore formation and positive membrane curvature, which promote vesicle budding. The adsorption of oligomers induces negative membrane curvature, which promotes vesicle invagination. This work demonstrates that antimicrobial peptides adopt multiple actions to destroy bacterial membranes.

Topics: Anti-Bacterial Agents; Binding Sites; Cell Membrane; Melitten; Molecular Dynamics Simulation; Peptide Fragments; Phosphatidylcholines; Phosphatidylglycerols; Protein Conformation; Protein Interaction Domains and Motifs; Unilamellar Liposomes

Antimicrobial peptides (AMPs) inactivate microorganisms by forming transmembrane pores in a cell membrane through adsorption and aggregation. Energetics of addition of an AMP to a transmembrane pore is important for evaluation of its formation and growth. Such information is essential for the characterization of pore forming ability of peptides in cell membranes. This study quantifies the potential of mean force through molecular dynamics (MD) simulation for the addition of melittin, a naturally occurring AMP, into a DOPC/DOPG mixed bilayer, a mimic of bacterial membrane, for different extents of insertion into either a bilayer or a pore consisting of three to six transmembrane peptides. The energy barrier for insertion of a melittin molecule into the bilayer was highest in the absence of transmembrane peptides and decreased for the number of transmembrane peptides from three to six, eventually approaching zero. The decrease in free energy for complete insertion of peptide was found to be higher for larger pore size. Water channel formation occurred only for insertion into pores consisting of three or more transmembrane peptides with the radius of water channel being larger for a larger number of transmembrane peptides. The structure of the pore was found to be paraboloid. The estimated free energy barrier for insertion of melittin into an ideal paraboloid pore accounting for different intermolecular interactions was consistent with MD simulation results. The results reported in this manuscript will be useful for the development of a model for nucleation of pores and a rational methodology for selection of synthetic antimicrobial peptides.

Topics: Amino Acid Sequence; Lipid Bilayers; Melitten; Models, Chemical; Molecular Dynamics Simulation; Phosphatidylethanolamines; Phosphatidylglycerols; Physical Phenomena

Melittin induces various reactions in membranes and has been widely studied as a model for membrane-interacting peptide; however, the mechanism whereby melittin elicits its effects remains unclear. Here, we observed melittin-induced changes in individual giant liposomes using direct real-time imaging by dark-field optical microscopy, and the mechanisms involved were correlated with results obtained using circular dichroism, cosedimentation, fluorescence quenching of tryptophan residues, and electron microscopy. Depending on the concentration of negatively charged phospholipids in the membrane and the molecular ratio between lipid and melittin, melittin induced the "increasing membrane area", "phased shrinkage", or "solubilization" of liposomes. In phased shrinkage, liposomes formed small particles on their surface and rapidly decreased in size. Under conditions in which the increasing membrane area, phased shrinkage, or solubilization were mainly observed, the secondary structure of melittin was primarily estimated as an α-helix, β-like, or disordered structure, respectively. When the increasing membrane area or phased shrinkage occurred, almost all melittin was bound to the membranes and reached more hydrophobic regions of the membranes than when solubilization occurred. These results indicate that the various effects of melittin result from its ability to adopt various structures and membrane-binding states depending on the conditions.

Topics: Animals; Chemical Phenomena; Circular Dichroism; Hydrophobic and Hydrophilic Interactions; Insect Proteins; Kinetics; Lipid Bilayers; Liposomes; Melitten; Membrane Proteins; Membranes; Microscopy, Electron, Transmission; Phosphatidylcholines; Phosphatidylglycerols; Phospholipids; Protein Structure, Secondary; Solubility; Surface Properties; Tryptophan

Melittin is a cationic hemolytic peptide isolated from the European honey bee, Apis mellifera. The organization of membrane-bound melittin has earlier been shown to be dependent on the physical state and composition of membranes. In this study, we covalently labeled the N-terminal (Gly-1) and Lys-7 of melittin with an environment-sensitive fluorescent probe, the NBD group, to monitor the influence of negatively charged lipids and cholesterol on the organization and dynamics of membrane-bound melittin. Our results show that the NBD group of melittin labeled at its N-terminal end does not exhibit red edge excitation shift in DOPC and DOPC/DOPG membranes, whereas the NBD group of melittin labeled at Lys-7 exhibits REES of approximately 8 nm. This could be attributed to difference in membrane microenvironment experienced by the NBD groups in these analogs. Interestingly, the membrane environment of the NBD groups is sensitive to the presence of cholesterol, which is supported by time-resolved fluorescence measurements. Importantly, the orientation of melittin is found to be parallel to the membrane surface as determined by membrane penetration depth analysis using the parallax method in all cases. Our results constitute the first report to our knowledge describing the orientation of melittin in cholesterol-containing membranes. These results assume significance in the overall context of the role of membrane lipids in the orientation and function of membrane proteins and peptides.

Topics: Amino Acid Sequence; Animals; Bees; Cholesterol; Fluorescence Polarization; Fluorescent Dyes; Hemolysis; In Vitro Techniques; Lipid Bilayers; Melitten; Molecular Conformation; Molecular Sequence Data; Phosphatidylcholines; Phosphatidylglycerols; Protein Structure, Secondary; Rats; Rats, Wistar

In order to investigate the effect of primary amphipathic peptides on mollicutes (wall-less bacteria), we have synthesised five molecules (P1, P2, P3, JM123, and JM133) comprising a 16 to 18-residue hydrophobic sequence and the nuclear localization sequence (NLS) PKKKRKV of simian virus 40 large-T antigen, C-terminated by a cysteamide group. The hydrophobic cluster was in P1 the signal sequence of the heavy chain of Caiman crocodilus immunoglobulin G and in JM123 the fusion peptide of human immunodeficiency virus 1 glycoprotein gp41 in which phenylalanine7 was replaced by a tryptophan residue. The homologues P2, P3, and JM133 were obtained by slight alterations of these sequences. Circular dichroism spectroscopy revealed that, in liposomes, P-series peptides were mainly under the form of beta-sheets whereas JM-series peptides displayed a high proportion of turns. These peptides proved to be bactericidal for some mollicutes, notably Acholeplasma laidlawii, but were much less potent than melittin. Furthermore, their antibiotic activity was independent of the average thickness of the plasma membrane hydrophobic core whilst that of melittin was inversely related to the thickness. Melittin and the synthetic peptides abolished spiroplasma cell motility and helicity, but only melittin and P-series peptides split the cells into globular forms displaying an average diameter of ca. 1 microm. In contrast to melittin, the synthetic peptides agglutinated spiroplasmas, suggesting that their polycationic NLS was exposed on the cell surface. P-series peptides decreased, though less efficiently than melittin, A. laidlawii and Spiroplasma melliferum membrane potential (delta psi) and transmembrane pH gradient (delta pH), at concentrations much lower than their minimal inhibitory concentrations whilst JM-series peptides had no effect on delta psi and delta pH in the same conditions. Actually, the bactericidal activity of these peptides towards mollicutes was proportional to their ability to collapse the electrochemical transmembrane potential.

Topics: Alligators and Crocodiles; Amino Acid Sequence; Amino Acid Substitution; Animals; Anti-Bacterial Agents; Anti-Infective Agents; Antigens, Viral, Tumor; Cell Wall; Circular Dichroism; HIV Envelope Protein gp41; HIV-1; Humans; Immunoglobulin G; Immunoglobulin Heavy Chains; Liposomes; Melitten; Micelles; Molecular Sequence Data; Nuclear Localization Signals; Peptides; Phenylalanine; Phosphatidylglycerols; Protein Conformation; Sequence Alignment; Simian virus 40; Spiroplasma; Structure-Activity Relationship; Tryptophan

Melittin is a cationic hemolytic peptide isolated from the European honey bee, Apis mellifera. Since the association of the peptide in the membrane is linked with its physiological effects, a detailed understanding of the interaction of melittin with membranes is crucial. We have investigated the interaction of melittin with membranes of varying surface charge in the context of recent studies which show that the presence of negatively charged lipids in the membrane inhibits membrane lysis by melittin. The sole tryptophan residue in melittin has previously been shown to be critical for its hemolytic activity. The organization and dynamics of the tryptophan residue thus become important to understand the peptide activity in membranes of different charge types. Wavelength-selective fluorescence was utilized to monitor the tryptophan environment of membrane-bound melittin. Melittin exhibits a red edge excitation shift (REES) of 5 nm when bound to zwitterionic membranes while in negatively charged membranes, the magnitude of REES is reduced to 2-3 nm. Further, wavelength dependence of fluorescence polarization and near-UV circular dichroism spectra reveal characteristic differences in the tryptophan environment for melittin bound to zwitterionic and anionic membranes. These studies are supported by time-resolved fluorescence measurements of membrane-bound melittin. Tryptophan penetration depths for melittin bound to zwitterionic and anionic membranes were analyzed by the parallax method [Chattopadhyay, A., and London, E. (1987) Biochemistry 26, 39-45] utilizing differential fluorescence quenching obtained with phospholipids spin-labeled at two different depths. Our results provide further insight into molecular details of membrane lysis by melittin and the modulation of lytic activity by negatively charged lipids.

Topics: Animals; Bees; Circular Dichroism; Dimyristoylphosphatidylcholine; Kinetics; Lipid Bilayers; Melitten; Models, Molecular; Phosphatidylcholines; Phosphatidylglycerols; Phospholipids; Protein Conformation; Spectrometry, Fluorescence; Structure-Activity Relationship; Tryptophan