Hervé Duclohier

Antimicrobial peptide magainin I from Xenopus skin forms anion-permeable channels in planar lipid bilayers.

The ionophore properties of magainin I, an antimicrobial and amphipathic peptide from the skin of Xenopus, were investigated in planar lipid bilayers. Circular dichroism studies, performed comparatively with alamethicin, in small or large unilamellar phospholipidic vesicles, point to a smaller proportion of alpha-helical conformation in membranes. A weakly voltage-dependent macroscopic conductance which is anion-selective is developed when using large aqueous peptide concentration with lipid bilayer under high voltages. Single-channel experiments revealed two main conductance levels occurring independently in separate trials. Pre-aggregates lying on the membrane surface at rest and drawn into the bilayer upon voltage application are assumed to account for this behaviour contrasting with the classical multistates displayed by alamethicin.

Voltage-dependent and multi-state ionic channels induced by trichorzianines, anti-fungal peptides related to alamethicin

The ionophore properties of two peptaibols of the trichorzianine family have been investigated in planar lipid bilayers and compared to those of alamethicin. Macroscopic conductance experiments reveal voltage‐dependent channels only in the thinnest membranes and a greater efficiency of the neutral analog. In single‐channel experiments, a multi‐state behaviour, consistent with the usual barrel‐stave model, is disclosed but the discrete current fluctuations are much more rapid than for alamethicin. The results indicate a stringent requirement for the helix length/bilayer thickness match in agreement with a previous model and suggest the design of new synthetic peptides.

Structure and supramolecular architecture of membrane channel-forming peptides

Peptides gathering together to induce channels in lipid bilayers may be classified in several categories according to the spatial structures involved. For example, gramicidin A forms intramolecular tubes, alamethicin, bundles of helical rods with intermolecular pores, porins (being proteins, properly speaking) are rich in beta-sheets that may form barrels, whereas cyclic peptides might stack together resulting in the formation of pores. The chemical structure of these compounds is now well characterized. The transmembrane electrical signals that they transmit are also typical of the particular supramolecular configurations (or architecture). Investigations in this field are thus relevant to structure-function relationship studies due to the availability of natural or synthetic analogues allowing the measurement of the influence of physico-chemical parameters upon the energy profiles of the pores. Consequently, questions such as the existence and probabilities of conductance substrates, their voltage-dependence and their ion or molecular selectivity can be tackled. Today, the loosest aspect of these studies lies in the actual molecular conformations and architecture in the membranes of the peptide aggregates, the knowledge of which remains imprecise, even at rest in the best-studied cases. This review attempts to point out still unresolved questions and to propose some plausible approaches concerning, for example: 1) the configurations of the molecular aggregates responsible for ion transfer; 2) the mechanisms for channel-opening and closing (gating); 3) the eventual cooperative phenomena between channels, via the bilayer or interfacial components. Possible applications of these structures will be tentatively outlined.

Conductance properties of des-Aib-Leu-des-Pheol-Phe-alamethicin in planar lipid bilayers

Abstract An alamethicin analogue in which all the amino-isobutyric acid and the C-terminal Pheol residues were replaced with Leu and an amidated Phe, respectively, has been synthesized. The purpose was to remove the ambiguity of a partial 3 10 helical character in alamethicin and thus, to study the conductance properties of a virtually full α helical rod modelling the natural voltage-dependent ionic channels. Macroscopic and single-channel experiments are consistent with the ‘barrel-staves’ model. The sequence of the conductance ratios of the sub-levels is very similar to the alamethicin one. The main difference lies in the very short-lived fluctuations displayed by the new analogue and is discussed in terms of helical conformation and length.

The influence of the trichorzianin C-terminal residues on the ion channel conductance in lipid bilayers

Four natural trichorzianin analogues, channel-forming peptaibols, differing in their C-terminal residues (Gln or Glu, Trpol or Pheol) were tested for their macroscopic and single-channel conductances in planar lipid bilayers. The results indicate that, as regards to the voltage threshold, the most efficient analogue is the charged Trpol-bearing one. In addition, Trpol brings about a drastic lengthening of the open channel life-times. This behaviour is attributed to the dipole moment of the end residues and to the bulkiness and hydrogen bonding ability of Trpol.

Ionophore properties of a synthetic alpha-helical transmembrane fragment of the mitochondrial H+ ATP synthetase of Saccharomyces cerevisiae. Comparison with alamethicin.

A 22-amino acid polypeptide was synthesized to model the central transmembrane segment of subunit 8 of the H+ ATP synthetase of Saccharomyces cerevisiae and to test ionophore properties. Solid-phase synthesis was conducted on benzhydrilamino resin, and purification followed by high pressure liquid chromatography allowed the isolation of the pure product whose NH2 terminal was acetylated and whose molecular weight determined by Fast Atomic Bombardment was the expected 2,666. The infrared spectrum of this peptide in the solid state reveals a fully alpha-helical conformation, whereas in low dielectric constant solvents the alpha-helical content is 60%, as determined by circular dichroism studies. Macroscopic current-voltage curves displayed by different planar lipid bilayers (monomyristoleoyl-glycerol and phosphatidylethanolamine) doped with this peptide suggest a weakly voltage-dependent conductance. Only one conductance level is observed in any given single-channel conductance experiment. However, a series of experiments shows a distribution of conductance states, most often 440 or 3,000 pS, and occasionally 80, 1,200, or 6,500 pS. This behavior contrasts with the usual behavior of alamethicin, chosen as a model of aggregating-helices ionophore and whose conductance fluctuates continually between substates, through uptake and release of monomers. Nevertheless, alamethicin too can display, under certain conditions, long-lived and mono-level conductance states similar to those reported here for the newly synthesized peptide. These properties could possibly be explained by the formation of large domains of helical rods with a set of allowed and independent ionic pathways.

Synthetic analogues of alamethicin: effect of C-terminal residue substitutions and chain length on the ion channel lifetimes.

In a previous study, a synthetic analogue of the peptaibol alamethicin, in the sequence of which all alpha-aminoisobutyric acid (Aib) were substituted by leucine residues and the C-terminal residue modified, was shown to display the same single-channel behaviour as alamethicin in planar lipid bilayer, except that the sublevel lifetimes were much reduced. New analogues differing in their C-terminal residue (Phe-NH2, Pheol, Trp-NH2) have now been tested for their single channel properties in neutral lipid bilayers. The conductance amplitudes and open channel lifetimes do not differ significantly from the previous analogue. Thus, the nature of the last residue, which may be located near the membrane interface, does not seem to play an important role in the destabilisation of the conducting aggregate observed after the Aib substitution by Leu. Since the deletion of one residue (Glu18) in the 14-20 moiety induces a slight decrease of the increment between the conductance levels, but has no effect upon the channel lifetimes, this residue and the length of this segment do not interfer much with the channel lifetime of peptaibols. In conclusion the factors influencing the aggregate stability may be sought in the helix-helix interactions.

The effects of the insecticide decamethrin on action potential and voltage-clamp currents of Myxicola giant axon

Abstract 1. The effects of the externally applied insecticide decamethrin on nerve excitability was studied on the giant axons of Myxicola infundibulum. 2. Membrane resting potential was only slightly reduced; Spike amplitudes were irreversibly reduced by 8–12%. 3. Voltage-clamp analysis showed a reduction of both early transient and late steady-state conductances. Kinetic effects were a prolongation of the time to peak early transient current and a slowing down of the first component of sodium tail current. 4. These results present similarities with allethrin-treated squid axons. The mechanism of action of pyrethroids is discussed.

Conformation, pore-forming activity, and antigenicity of synthetic peptide analogues of a spiralin putative amphipathic α helix

Current models depict spiralin as a bitopic transmembrane protein with the transbilayer domain being an amphipathic alpha helix. However, though secondary structure prediction methods suggest a helical conformation for the hypothetical transmembrane segment of spiralin, no potential transmembrane helices could be detected in this protein using the method of Von Heijne (Von Heijne, G. (1992) J. Mol. Biol. 225, 487-494). Therefore, we have reconsidered the spiralin topological model by investigating the properties of the chemically synthesized peptides SM-BC3 (LNAVNTYATLAKAVLDAIQN-NH2) and SC-R8A2 (LNAVNTYATLASAVLEAIKN-NH2), corresponding to the hypothetical transmembrane segments of spiralins of two distinct spiroplasma species. The hydrophobic moment plot method suggests that these spiralin amino acid stretches are class G amphipathic alpha helices (i.e., helices localized on the surface of a globular protein domain). Circular dichroism spectra showed that both peptides have little ordered structure in aqueous solutions but adopt a mainly helical conformation in the presence of 25% trifluoroethanol or in detergent micelles (up to 74% alpha helix). Both peptides formed concentration- and voltage-dependent pores in planar lipid bilayers with a unitary conductance of 130 pS in 1 M KCl and with mean numbers of monomers per conducting aggregates of 6 for SC-R8A2 and 9 for SM-BC3. However, the two peptides displayed a haemolytic activity only at high concentrations (> 250 microM) and reacted with antibodies raised against membrane-bound spiralin. Together with previously published results, these data suggest that spiralin is a monotopic membrane protein anchored at the surface of the spiroplasma cell and that the 20-residue amphipathic segment is most probably a class G helix containing a B-cell epitope.

Conformational Changes in Alamethicin Associated with Substitution of Its α-Methylalanines with Leucines: A FTIR Spectroscopic Analysis and Correlation with Channel Kinetics

Alamethicin, a 20 residue-long peptaibol remains a favorite high voltage-dependent channel-forming peptide. However, the structural significance of its abundant noncoded residues (alpha-methylalanine or Aib) for its ion channel activity remains unknown, although a previous study showed that replacement of all Aib residues with leucines preserved the essential channel behavior except for much faster single-channel events. To correlate these functional properties with structural data, here we compare the secondary structures of an alamethicin derivative where all the eight Aibs were replaced by leucines and the native alamethicin. Fourier transform infrared (FTIR) spectra of these peptides were recorded in methanol and in aqueous phospholipid membranes. Results obtained show a significant conformational change in alamethicin upon substitution of its Aib residues with Leu. The amide I band occurs at a lower frequency for the Leu-derivative indicating that its alpha-helices are involved in stronger hydrogen-bonding. In addition, the structure of the Leu-derivative is quite sensitive to membrane fluidity changes. The amide I band shifts to higher frequencies when the lipids are in the fluid phase. This indicates either a decreased solvation due to a more complete peptide insertion or a peptide stretching to match the full thickness of the bilayer. These results contribute to explain the fast single-channel kinetics displayed by the Leu-derivative.