Robert Brasseur

Adriamycin inactivates cytochrome c oxidase by exclusion of the enzyme from its cardiolipin essential environment.

Abstract Adriamycin and several derivatives were found to inhibit the last oxidation site of the respiratory chain (cytochrome c oxidase EC.1.9.3.1.) both on mitochondria and on purified reconstituted systems. A new mechanism of membrane enzyme inactivation is proposed to explain the experimental results: adriamycin does not interact directly with cytochrome c oxidase but inactivates it by changing the cardiolipin environment essential for its activity. In presence of adriamycin, cardiolipin is extracted from the lipid surrounding environment of cytochrome c oxidase and segregates in a separate phase inaccessible for the enzyme. We suggest that other cardiolipin dependent enzymes could be inactivated by adriamycin.

Mechanism of inhibition of mitochondrial enzymatic complex I–III by adriamycin derivatives

We demonstrate here that complex I-III of bovine heart mitochondrial membrane is inhibited by adriamycin derivatives. This inhibition is a cardiolipin-dependent process. This lipid, specific to the inner mitochondrial membrane, has been shown previously to interact specifically with adriamycin in model membranes (Goormaghtigh, E., Chatelain, P., Caspers, J. and Ruysschaert, J.-M. (1980) Biochim. Biophys. Acta 597, 1-14) and in mitochondrial membranes (Cheneval, D., Müller, M., Toni, R., Ruetz, S. and Carafoli, E. (1985) J. Biol. Chem. 260, 13003-13007). The differential scanning calorimetry data indicate that, in multilamellar liposomes, the formation of antibiotic-cardiolipin complexes induces a clustering of cardiolipin molecules. Conformational analysis of the antibiotic-cardiolipin complexes suggests that plane-plane interactions between the antibiotics aromatic moieties stabilize this complex formation. Possible mechanisms of inactivation of complex I-III by adriamycin are proposed.

Theoretical conformational analysis of phospholipids bilayers.

Abstract We present a computational approach describing the conformation of lipid molecules (1-2-dipalmitoyl-sn-glycero-3 phosphocholine (DPPC)) organized in bilayers. The classical semi-empirical method used in peptide conformational analysis has been extended successfully to lipids. The excellent agreement between our theoretical predictions and recent experimental data on the molecular organization of lipid bilayers suggests that the method could be a valuable tool in the lipid conformational analysis but also in the prediction of orientation and mode of insertion of amphiphilic molecules into the lipid bilayer.

Secondary structure and orientation of a chemically synthesized mitochondrial signal sequence in phospholipid bilayers.

A pre-sequence of 25 amino acids is required for import of yeast cytochrome oxidase subunit IV into mitochondria. Structure and orientation of the 25 amino acids synthesized peptide (p25) in a lipid bilayer were investigated by infrared attenuated total reflection spectroscopy. This method allowed to overcome the difficulties related to the optical turbidity due to the light scattering on membrane fragments which prevents the use of circular dichroism. We demonstrate here that incubation of the peptide with DOPC (dioleoylphosphatidylcholine) and DOPC-CL (dioleoylphosphatidylcholine - cardiolipin) liposomes is accompanied by an increase in alpha-helical content as compared to beta structure. Polarisation measurements indicate that the amphipathic helical segment is inserted parallel to the lipid acyl chains in cardiolipin containing liposomes.

Acido-basic properties of lipophilic substances: A surface potential approach

Abstract A general procedure allowing the acido-basic properties of lipophilic compounds to be defined is described. Drugs are spread at the air-water interface and the surface potential is recorded at different pH values of the aqueous subphase. Comparison of this experimental parameter and the Gouy-Chapman theory prediction allows the calculation of the acid (or basic) dissociation constants and the surface charge density.

Evaluation of the anesthetic-lipid association constant: A monolayer approach

A new approach is presented which allows to describe the binding of different local anesthetics to lipids. Lipids (DL- alpha-dipalmitoylphosphatidylcholine, phosphatidylserine, cardiolipin) are spread at the air-water interface and the anesthetic (procaine, butacaine, tetracaine) injected into the aqueous subphase. The equilibrium constants associated to the interfacial reaction: D+ (subphase) +L- (monolayer) in equilibrium DL (monolayer) (where D+ denotes the anesthetics, L- the lipid anionic site and DL the complex) are calculated from an experimental evaluation of the surface potential of the lipid monolayer. This mode of determination is based essentially on the good correlation between the experimental values of the surface potential and the theoretical predictions from the Gouy-Chapman theory. Fluorescence measurements on liposomes are carried out in order to locate the position of the drug in the lipid layer. This method can be extended to any positively charged drug-anionic lipid interaction.

pH dependent insertion of a diphtheria toxin B fragment peptide into the lipid membrane: a conformational analysis.

A peptide of diphtheria toxin B fragment (residues 147-266) has been shown to induce pore formation in lipid bilayer membranes at low pH. Such an effect was obtained at a much lower extent or not at all at pH = 7. The region localized between residues 225 and 246 is highly hydrophobic (27.3% polarity) and characterized by a high concentration of proline residues. Since proline cis-trans isomerization is highly sensitive to the pH of the medium, we investigated the capability of the cis and trans isomers to penetrate into the lipid matrix. Obviously, the cis-trans isomerization of proline 242 and 245, assumed to be imposed by a low pH, uncovers the hydrophobic region and induces its insertion into a lipid layer of dipalmitoylphosphatidylcholine. The lipid matrix destabilization resulting from this process could promote the penetration into the lipid bilayer of an amphipatic structure (153-178) similar to the transverse lipid associating domains of membrane proteins.

Semi-empirical conformational analysis of propranolol interacting with dipalmitoylphosphatidylcholine.

A semi-empirical conformational analysis is used to compute the conformation of (+)-propranolol inserted in dipalmitoylphosphatidylcholine. In a first step, the minimal conformational energy of the isolated molecule at the hydrocarbon-water interface is calculated as the sum of the contributions resulting from the Van der Waals, the torsional, the electrostatic and the transfer energies. Five pairs of conformers of minimal energy are determined. They are compared to data available from other experimental approaches. In a second step, they are assembled with dipalmitoylphosphatidylcholine at the interface. Although propranolol is considered in its protonated form, the electrostatic interaction with dipalmitoylphosphatidylcholine is negligible as compared to the Van der Waals interaction. The area occupied per propranolol molecule is between 0.53 and 0.64 nm2/molecule. In the most probable modes of insertion of propranolol into the lipid layer, the naphthyl moiety of the compound interacts with the lipid acyl chains. The protonated amino group is located in the vicinity of the phosphate residue possibly causing an electrostatic interaction.

Structural considerations for calcium ionophoresis by prostaglandins

The prostaglandins PGB2, PGE2 and PGF2 alpha were found to translocate calcium in a modified Pressman cell. At pH 7.40, PGB2 was more potent than PGE2 and than PGF2 alpha. When incorporated at a 1% molar ratio in liposomes made of cholesterol and different diacyl phosphatidyl choline, prostaglandins are able to mediate a slow calcium exchange diffusion. A significant prostaglandin-mediated calcium release that depends on the lipid matrix rigidity is observable at 37 degrees but not at 22 degrees. Conformational analysis of the complex formed by two molecules of prostaglandins and one calcium atom, either at a simulated membrane-water interface or in a simulated bulk lipid phase reveals rigid complexes with great distances between hydrophilic and hydrophobic gravity centres that predict low ionophoretic properties.

Mode of Organization of Galactolipids: a Conformational Analysis

Despite the fact that photosynthetic membranes show the conventional bilayer structure, their major lipid component monogalactosyldiacylglycerol does not form lamellar structure but takes up an hexagonal-II structure when dispersed alone in water and forms inverted lipids micelle structures when dispersed together with other lipid components of the photosynthetic membrane. We present here evidence that the mode of organization of these lipids can be predicted from a conformational approach allowing to describe the configuration of assembled amphiphilic molecules. The minimal conformational energy is calculated as the sum of the contributions resulting from the Van der Waals interactions, the torsional potentials, the electrostatic interaction and the transfer energy. Because of its calculated cone shaped structure monogalactosyldiacylglycerol forms inverted lipid structure with the hydrophilic groups pointing inward; for digalactosyldiacylglycerol, an other essential lipid constituent of photosynthetic membrane, its calculated cylindrical shape induces an organization in bilayer structures.