A high-sensitivity differential scanning calorimetric study of the interaction of melittin with dipalmitoylphosphatidylcholine fused unilamellar vesicles.

High-sensitivity differential scanning calorimetry has been used to examine the interaction of bee venom melittin with dipalmitoylphosphatidylcholine fused unilamellar vesicles. Experiments were performed under conditions for which melittin in solution is either monomeric (in low salt) or tetrameric (in high salt). It was found that under both sets of conditions melittin abolishes the pretransition at a relatively high lipid-to-protein molar incubation ratio, Ri (about 200) and that at intermediate values of Ri it broadens the main transition profile and reduces the transition enthalpy. This provides evidence which suggests that melittin is at least partially inserted into the apolar region of the bilayer. Evident at low values of Ri are two peaks in the lipid thermal transition profiles, which may arise from a heterogeneous population of lipid vesicles formed through fusion induced by melittin, or by lipid phase separation. For those profiles which exhibited only one peak, transition enthalpies, normalized to those of the lipid in the absence of the protein, are plotted vs. the bound protein-to-lipid molar ratios for the experiments performed under the conditions which give monomeric and tetrameric melittin in solution. These plots yield straight lines, the slopes of which give the number of lipid molecules each protein molecule excludes from participating in the phase transition. These were found to be 9.9 +/- 0.7 and 4.1 +/- 0.5 for monomeric and tetrameric melittin, respectively. The results are discussed in terms of possible models for the binding of melittin to phospholipid vesicles. For simple hexagonal packing of lipid molecules, incorporation as an aggregate is favored when melittin is tetrameric in solution, whereas incorporation as a monomer is favored when melittin is monomeric in solution. For low-salt solutions, evidence is obtained for the contribution of free melittin to lipid fusion, perhaps by the formation of protein bridges between apposed vesicles.

Wasp venom peptides; wasp kinins, new cytotrophic peptide families and their physico-chemical properties.

In addition to wasp kinins, the wasp venom contains a series of hydrophobic peptides, mastoparans and chemotactic peptides as major peptidergic components. The first major component in the venom is mastoparam. The peptides in the mastoparan family are tetradecapeptide amides which cause degranulation of the mast cells to release histamine from the cells, and act on the adrenal chromaffin cells to release catecholamines and adenylic acids. Some mastoparans cause hemolysis and serotonin release from the platelets. The new cytotrophic peptides as the second major components are tridecapeptide amides possessing chemotactic activity for polymorphonuclear leucocytes and monocytes. Some of the peptides in this family also cause histamine release from the mast cells. Mastoparan takes a random coil structure in aqueous solution but changes its conformation to alpha-helix in methanolic solution or in the presence of lysophosphatidyl choline. This fact is confirmed also by the transferred nuclear overhauser effect by NMR analysis. The similar phenomenon was observed in the family of chemotactic peptides. The helical conformation of these peptides are amphipathic structure in which all of side chains of the hydrophobic amino acids are located on one side of the axis, and those of the basic or the hydrophilic amino acid residues are on an opposite side. Mastoparan enhances the membrane conductivity of the lipid bilayer when the peptide is investigated by the black lipid membrane experiment. This indicates that the peptide may be assembled in the membrane by changing its conformation and, for some reason, enhances the ion transfer through the membrane. These properties of the peptide may reveal various activities on the cell membrane.