Polarity-dependent conformational switching of a peptide mimicking the S4-S5 linker of the voltage-sensitive sodium channel.

The S4-S5 linker (or S45) in voltage-sensitive sodium channels was previously shown to be involved in the permeation pathway. The secondary structure, investigated by circular dichroism, of a S4-S45 peptide from domain IV and its fragments (including S45) is reported here and compared with that of the homologous peptide from domain II as a function of the solvent dielectric constant. The reduction in helicity seen for S4-S45 (II) in polar media is cancelled in membrane-like environment. The most striking result-- a sharp alpha-helix --> beta-sheet transition upon exposure of the S45 moiety to aqueous solvents-- is discussed as regards channel activation and selectivity.

Correlation between anti-bacterial activity and pore sizes of two classes of voltage-dependent channel-forming peptides.

Anti-bacterial activities were compared for two series of voltage-dependent pore-formers: (i) alamethicin (Alm) and its synthetic analogs (Alm-dUL) where alpha-amino-isobutyric acid residues (Aibs) were replaced by leucines and selected key residues substituted and (ii) homologous voltage sensors of the electric eel sodium channel (repeats S4L45 (III) and S4L45 (IV)). Spiroplasma melliferum, a bacterium related to the mycoplasmas, was used as a target cell. The data show that with respect to growth inhibition, cell deformation and plasma membrane depolarization, the highest efficient peptide remained natural Alm although the minimal inhibitory concentrations of its Leu analogs were within the same range as the parent molecule, except for Alm-dUL P14A. Thus, as for the pore-forming activity observed in artificial membranes and for the toxicity towards mammalian cells, proline-14 proved to be a critical residue for the anti-bacterial activity of alamethicin. Regarding the sodium voltage sensors, their anti-bacterial efficiency was at least 10 times lower although they promoted spiroplasma cell agglutination. The anti-bacterial activities of the peptides were correlated with their pore-forming properties, especially with the apparent and mean number of monomers per conducting aggregate () when both peptide families were considered and, secondly, with mean open times (tau(o)) within each family. This suggests that although they may form 'raft-like' structures, the mechanism underlying anti-bacterial activity of Alm and its active analogs, as well as the S4L45 voltage sensors with the S. melliferum plasma membrane, is predominantly through pore-formation according to the 'barrel-stave' mechanism.

Lateral diffusion and conductance properties of a fluorescein-labelled alamethicin in planar lipid bilayers.

In order to follow alamethicin diffusion within membranes under conditions of pore-formation, a fluorescein isothiocyanate (FITC) analogue was synthesized. To test the influence of the fluorescent probe addition on the pore-forming activity of the new analogue, macroscopic and single-channel experiments into planar lipid bilayers were performed. Although the apparent mean number of monomers per conducting aggregate was equivalent, the voltage-dependence of the new analogue was slightly reduced and hysteresses were broader, in agreement with the much longer duration of the open single-channels. Thus, the conducting aggregates seem to be stabilized by the introduction of the probe, presumably through the interaction of the conjugated cycles with the lipid headgroups, while the added steric hindrance may account for the slightly higher conductances of the open substates. Lateral diffusion of the labelled peptide associated with the bilayer was then investigated by the fluorescence recovery after photobleaching technique. Under applied voltage, associated with high conductance, D, the lateral diffusion coefficient, was reduced by 50% when compared to peptide at rest. These results provide new independent experimental evidence for a voltage-driven insertion of the highly mobile surface-associated peptide into the bilayer as a prominent step in pore formation.

Coupling Optical and Electrical Measurements in Artificial Membranes: Lateral Diffusion of Lipids and Channel Forming Peptides in Planar Bilayers.

Planar lipid bilayers (PLB) were prepared by the Montal-Mueller technique in a FRAP system designed to simultaneously measure conductivity across, and lateral diffusion of, the bilayer. In the first stage of the project the FRAP system was used to characterise the lateral dynamics of bilayer lipids with regards to phospholipid composition (headgroup, chain unsaturation etc.), presence of cholesterol and the effect of divalent cations on negatively-charged bilayers. In the second stage of the project, lateral diffusion of two fluorescently-labelled voltage-dependent pore-forming peptides (alamethicin and S4s from Shaker K(+) channel) was determined at rest and in the conducting state. This study demonstrates the feasibility of such experiments with PLBs, amenable to physical constraints, and thus offers new opportunities for systematic studies of structure-function relationships in membrane-associating molecules.

Sodium channel fragments: contributions to voltage sensitivity and ion selectivity.

The peptide strategy was employed to resolve structure-function relationships in the voltage-dependent sodium channel Two families of motifs were studied: the four voltage sensors S4 extended with the short cytoplasmic linkers L45 and the four P-regions, between S5 and S6, each from the homologous domains of the electric eel sodium channel. Macroscopic conductance experiments conducted with synthetic S4L45s in neutral lipid planar bilayers pointed to a moderate voltage-sensitivity for repeat IV which has no proline, whereas S4L45 of repeats I and II (Pro 19) and especially of repeat III (Pro 14) were much more voltage-sensitive. The influence both of Pro and its position within the sequence was confirmed by comparing the human skeletal muscle channel isoform D4/S4 wild-type and the R4P analogue. Circular dichroism spectroscopy shows highest and lowest helicities for repeats IV and III. The conformational transition (from helix to extended, mainly beta forms), which occurs when the solvent dielectric constant increases, was broader with repeat III. These structural and functional correlates suggest alternative gating mechanisms. The different contributions of each repeat also have effects at the level of the main selectivity filter, which suggests self-recognition between the four P-regions is a key component of intact sodium channel selectivity. In addition, the P-region from domain III is significantly voltage-sensitive and molecular dynamics simulations show that the C-terminal part of P-regions is mainly helical whilst the N-terminus tends to unfold. Such specializations of the four domains both in gating and selectivity are independently confirmed in recent electrophysiological studies.

Voltage sensitivity and conformational change of isolated S4L45 fragments from sodium channels are tuned to proline.

Peptide fragments reproducing the sequences of S4 segments extended with L45 linkers from the four homologous domains of the electric eel sodium channel were chemically synthesized and purified to allow circular dichroism studies in various solvents and conductance assays in planar lipid bilayers. Repeats III (with proline) and IV (lacking proline) present the lowest and highest helicities, respectively. The conformational transition (from helix to beta-strand) shown to occur on an increase of solvent dielectric constant is broader with repeat III. Analytical ultracentrifugation (interference fringe pattern) is consistent with a monodispersion of the peptide. In macroscopic conductance experiments, the proline containing peptides (repeats I, II and especially III) display higher voltage-sensitivities than repeat IV. The apparent and averaged number of monomers per intramembrane conducting aggregate is 4-5. The influence of proline is confirmed in similar experiments carried out on homologous S4 segments of repeat IV of the human skeletal muscle sodium channel comparing the wild type and an analogue where the fourth arginine was substituted with a proline. Thus, both conformational switching and voltage-sensitivity appear correlated to the presence and position of a single proline residue. Since voltage sensors are likely to experience different polarity environments in the channel open and closed states, our results suggest an alternative gating mechanism, i.e. a voltage-driven conformational change of S4L45s. The data also implies a plausible functional asymmetry, namely a "three- or four-stroke" activation sequentially involving the four domains of the sodium channel.

Implication of segment S45 in the permeation pathway of voltage-dependent sodium channels.

A 34-mer peptide, encompassing the S4 and S45 segments of domain IV of the electric eel voltage-dependent sodium channel, was synthesized in order to test the potential implication of S45 in the gating or permeation pathway. The secondary structure of peptide S4-S45 assessed by circular dichroism was found mainly helical, both in organic solvents and in lipid vesicles, especially negatively-charged ones. The macroscopic conductance properties of neutral and negatively-charged Montal-Mueller planar lipid bilayers doped with S4-S45 were studied and compared with those of S4. With regard to voltage-dependence, the most efficient system was S4-S45 in neutral bilayers. Voltage thresholds for exponential conductance development were found to correlate with the background or "leak" conductance. Assuming that the latter reflects interfacial peptide concentration, the mean apparent number of monomers per conducting aggregate could be estimated to be 3-5. In single-channel experiments, the most probable events had amplitudes of 8 pS and 5 pS in neutral and negatively-charged bilayers respectively. Ionic selectivity under salt gradients conditions, both at macroscopic and single-channel levels, was in favour of sodium ions (PNa/PK = 3). These properties compare favourably to previous reports dealing with peptide modelling transmembrane segments of voltage-dependent ionic channels. Specifically, when compared to S4 alone, the reduced unit conductance and the increased selectivity for sodium support the implication of the S45 region in the inner lining of the open configuration of sodium channels.

The activation state of alphavbeta 3 regulates platelet and lymphocyte adhesion to intact and thrombin-cleaved osteopontin.

Cleavage of osteopontin by thrombin has been reported to enhance cell adhesion. We asked whether thrombin could regulate the alpha(v)beta(3)-mediated adhesion of platelets and B lymphocytes to this substrate. Although there was no difference in the extent or the avidity of thrombin- and ADP-stimulated platelet adhesion to intact or thrombin-cleaved human osteopontin, both the extent and avidity of phorbol ester-stimulated B cell adhesion to thrombin-cleaved osteopontin was significantly increased. Thus, these data suggest that the ability of alpha(v)beta(3) to recognize osteopontin can be differentially regulated in a cell-specific manner. To localize the alpha(v)beta(3) binding site on osteopontin, we measured cell adhesion to the two thrombin cleavage products of osteopontin and to a series of nested RGD-containing osteopontin peptides cross-linked to albumin. Whereas ADP-stimulated platelets adhered to the amino-terminal but not the carboxyl-terminal osteopontin fragment and to the osteopontin peptide RGDSVVYGLR, phorbol ester-stimulated B cells did not adhere to this peptide, although they did so in the presence of 1 mm Mn(2+). Thus, our data confirm that thrombin cleavage enhances the accessibility of the binding motif for alpha(v)beta(3) on osteopontin, but this enhancement is also a function of the activation state of alpha(v)beta(3). Moreover, they indicate that the sequence RGDSVVYGLR contains sufficient information to specify activation-dependent alpha(v)beta(3)-mediated platelet and lymphocyte adhesion.