Trichogin GA IV is a lipopeptide antibiotic of fungal origin, which is known to be able to modify the membrane permeability. TOAC nitroxide spin-labeled analogues of this membrane active peptide were investigated in hydrated bilayers of 1-palmitoyl-2-oleoyl-sn-glycero-3-phosphocholine (POPC) by electron spin echo (ESE) spectroscopy. Because the TOAC nitroxide spin label is rigidly attached to the peptide backbone, it may report on the backbone orientational dynamics. The ESE signal in this system is observed below ∼150 K. Previously, three-pulse stimulated ESE was found to be sensitive to two types of orientational motion of spin-labeled POPC lipid bilayers at these temperatures. The first type is fast stochastic librations, with a correlation time on the nanosecond scale (which also manifests itself in a two-pulse primary ESE experiment). The second type is slow millisecond inertial rotations. In the present work, we find that at low molar peptide to lipid ratio (1:200), where the individual peptide molecules are randomly distributed at the membrane surface, the spin labels show only a fast type of motion. At the high molar peptide to lipid ratio (1:20), a slow motion is also observed. Because at this high concentration trichogin GA IV is known to change its orientation from the in-plane topology to the transmembrane disposition, the observed onset of a slow motion may be safely attributed to the dynamics of peptides, which are elongated along the lipid molecules of the membrane. The possible interrelation between this backbone rotational motion of the peptide antibiotic and the membrane leakage is discussed.
Trichogin GA IV is a membrane-active lipopeptide, the antibiotic activity of which was proposed to be based on its capability to induce leakage due to formation of pores into the bacterial cell membrane. However, less attention has been paid to its biological selectivity, i.e., discrimination between bacterial versus cholesterol containing (mammalian) membranes. This is the reason which motivated us to study the role of cholesterol on penetration of the peptide into the membrane and formation of water channels. The ESEEM technique was used to measure the modulation amplitudes for TOAC spin-labeled trichogin GA IV peptide analogues in hydrated membranes of phosphatidylcholine (PC) lipid in the presence of 50 mol % cholesterol-d7. From the interaction between the nitroxide spin-label and the nearby located deeply membrane inserted deuterons, the N-terminus was found to be positioned at the core of the membrane. Separately, ESEEM measurements for the FTOAC-8 labeled peptide, but in D2O hydrated cholesterol/PC membranes, provide strong evidence for the polar C-terminus situated near the membrane surface. The apparently too high modulation amplitude measured for the buried FTOAC-1 label is likely attributed to the presence of peptide associated water. In cholesterol depleted membrane, however, the long axes of the helical molecules are found oriented parallel to the membrane surface even at high peptide concentration. Continuous wave EPR spectroscopy indicates that, for cholesterol containing membrane, peptide insertion is accompanied by self-aggregation of parallelly aligned transmembrane peptide molecules, while for cholesterol lacking membranes they are monomolecularly distributed. Thus, cholesterol tends to stabilize the transmembrane peptide aggregate.
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