Potential-dependent conductances in lipid membranes containing alamethicin.

This article is concerned primarily with the mechanism of the potential-dependent conductance induced in artificial lipid membranes by the cyclic polypeptide andibiotic alamethicin. It has already been shown from studies of the fluctuations that can be detected in very small membrane currents that alamethicin forms transient pores of some 0.6 nm in diameter and that, for small inorganic ions, these are poorly selective. The origin of these pores, their spatial distribution and interaction are discussed. It is demonstrated that the sensitivity of the membrane conductance to the applied potential arises only to a slight extent from the current-voltage relations for the individual pores, and that the main effect stems from the influence of the potential on the frequency of opening of the pores. From the properties of lipid membranes containing alamethicin in a wide variety of electrolytes, and from other evidence, it is concluded that the polypeptide reacts to the electric field more probably because it has dipole moment than because it binds ions. It is proposed that the conducting complex is capable of functioning in either of two orientations, and that it is these two possibilities that give rise to certain differences in the single channel characteristics for the two directions of the field.     

Pressure effects on alamethicin conductance in bilayer membranes.

We report here the first observations of the effects of elevated hydrostatic pressure on the kinetics of bilayer membrane conductance induced by the pore-forming antibiotic, alamethicin. Bacterial phosphatidylethanolamine-squalene bilayer membranes were formed by the apposition of lipid monolayers in a vessel capable of sustaining hydrostatic pressures in the range, 0.1-100 MPa (1-1,000 atm). Principal observations were (a) the lifetimes of discrete conductance states were lengthened with increasing pressure, (b) both the onset and decay of alamethicin conductance accompanying application and removal of supra-threshold voltage pulses were slowed with increasing pressure, (c) the onset of alamethicin conductance at elevated pressure became distinctly sigmoidal, suggesting an electrically silent intermediate state of channel assembly, (d) the magnitudes of the discrete conductance levels observed did not change with pressure, and, (e) the voltage threshold for the onset of alamethicin conductance was not altered by pressure. Apparent activation volumes for both the formation and decay of conducting states were positive and of comparable magnitude, namely, approximately 100 A3/event. Observation d indicates that channel geometry and the kinetics of ion transport through open channels were not affected by pressure in the range employed. The remaining observations indicate that, while the relative positions of free-energy minima characterizing individual conducting states at a given voltage were not modified by pressure, the heights of intervening potential maxima were increased by its application.     

X-ray diffraction study of lipid bilayer membranes interacting with amphiphilic helical peptides: diphytanoyl phosphatidylcholine with alamethicin at low concentrations.

A variety of amphiphilic helical peptides have been shown to exhibit a transition from adsorbing parallel to a membrane surface at low concentrations to inserting perpendicularly into the membrane at high concentrations. Furthermore, this transition has been correlated to the peptides' cytolytic activities. X-ray lamellar diffraction of diphytanoyl phosphatidylcholine-alamethicin mixtures revealed the changes of the bilayer structure with alamethicin concentration. In particular, the bilayer thickness decreases with increasing peptide concentration in proportion to the peptide-lipid molar ratio from as low as 1:150 to 1:47; the latter is near the threshold of the critical concentration for insertion. From the decreases of the bilayer thickness, one can calculate the cross sectional expansions of the lipid chains. For all of the peptide concentrations studied, the area expansion of the chain region for each adsorbed peptide is a constant 280 +/- 20 A2, which is approximately the cross sectional area of an adsorbed alamethicin. This implies that the peptide is adsorbed at the interface of the hydrocarbon region, separating the lipid headgroups laterally. Interestingly, the chain disorder caused by a peptide adsorption tends to spread over a large area, as much as 100 A in diameter. The theoretical basis of the long range nature of bilayer deformation is discussed.     

Alamethicin incorporation in lipid bilayers: a thermodynamic study

Interaction of the peptide antibiotic alamethicin with phospholipid vesicles has been monitored by changes in its circular dichroic and fluorescent properties. The data are consistent with an incorporation of the peptide in the lipid bilayer. Aggregation of alamethicin in the membrane phase is evident from a characteristic concentration dependence of the incorporation, reflecting the existence of a critical concentration. The data can be fully understood in terms of a theoretical approach that includes aggregation and thermodynamic nonideality. Thermodynamic parameters of the peptide-lipid interaction have been evaluated under a variety of conditions of temperature, ionic strength, and lipid type (saturated and unsaturated fatty acid chains). From the results obtained in this study, one can extrapolate to the incorporation behavior of alamethicin at low concentrations, as they are typical for measurements of conductance across planar lipid films. This leads to a simple explanation of the voltage-gating mechanism of alamethicin in a straightforward way.     

Two states of cyclic antimicrobial peptide RTD-1 in lipid bilayers

RTD-1 is a recently discovered cyclic peptide that, like other well-studied antimicrobial peptides, appears to bind to the lipid matrix of cell membrane in the initial stage of activity. We studied the states of RTD-1 bound to lipid bilayers by two methods: oriented circular dichroism and X-ray diffraction. RTD-1 shows two physically distinct bound states in lipid bilayers like magainins, protegrins, alamethicin, and melittin that were previously studied. However, the nature of transition between the two states is different for RTD-1 as compared with the aforementioned peptides. In one of the two states, RTD-1 is oriented with its backbone ring parallel to the plane of the bilayer. Only in this state RTD-1 induces membrane thinning. But the effect of membrane thinning is much weaker than all other peptides, suggesting that the mechanism of RTD-1 may be different from the other peptides.     

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.     

Alamethicin-induced current-voltage curve asymmetry in lipid bilayers.

We have examined the causes of the asymmetry of the current-voltage curve induced by addition of alamethicin to one side of a black lipid membrane. We find that the alamethicin-induced current-voltage (I-V) curve has an inherent asymmetry. If it were possible to confine all alamethicin molecules to one side of the membrane, the I-V curve would exhibit a positive branch (voltage being measured with respect to the side of the membrane trans to the alamethicin addition) of steeper logarithmic slope than the negative branch and at a lower absolute value of potential. This condition is not usually realized, however, because alamethicin can leak through the membrane, so that, except at very high alamethicin concentrations and in certain kinds of membranes, the positive branch of the current-voltage curve has the same logarithmic slope as the negative branch and appears to arise from alamethicin which diffuses from the cis to the trans side of the membrane. We develop simple quantitative models for these two cases.     

A three state model for alamethicin conductance in bilayer membranes

Alamethicin is an antibiotic which produces voltage gated channels in lipid bilayer membranes. Recently completed studies of the pressure dependence of alamethicin conductance have shown that its onset following application of a suprathreshold voltage step at a pressure of 100 MPa (1000 atm) is markedly slowed relative to that observed at ambient pressure. Furthermore, the time course of the onset of conductance becomes distinctly sigmoidal at elevated pressure, a condition which is not evident at atmospheric pressure. The decay of alamethicin conductance upon removal of suprathreshold applied voltage is also slowed by application of hydrostatic pressure, but it follows a single exponential time course at all pressures. In addition, kinetic parameters characterizing the onset and decay of conductance show distinctly different pressure dependences. These observations cannot be explained by a two state model in which alamethicin moves reversibly between nonconducting and conducting states. Therefore we re-examine critically a hypothesis made by previous workers, namely that alamethicin, in monomeric or aggregate form, moves upon application of suprathreshold voltage first from a nonconducting surface state to a nonconducting preassembly or precursor state, and then finally into a conducting state. Parameters of this three state model are related to a geometric factor which measures the degree of sigmoidal conductance response and which can be evaluated directly from experimental data. An alternative aggregation-type analysis, equivalent to that applied by Hodgkin & Huxley to the potassium conductance in squid axon, is also considered in the context of this same geometric factor. The possibility of distinguishing between these analyses on the basis of experimental data is discussed.     

Thermodynamic analysis of incorporation and aggregation in a membrane: application to the pore-forming peptide alamethicin

Interaction of the pore-forming antibiotic alamethicin with small unilamellar vesicles of dioleoylphosphatidylcholine has been studied by means of circular dichroism. The data strongly suggest that alamethicin does not bind to the surface of the vesicles but incorporates into the lipid phase to a fairly large extent. Furthermore, aggregation of the peptide in the membrane is apparent from the existence of a 'critical concentration'. Quantitative evaluation and interpretation of the data rest on a quite generally applicable thermodynamic analysis. The underlying phenomenon is treated in terms of a partition equilibrium between the aqueous and lipid media. In the bilayer phase non-ideal interactions (described by appropriate activity coefficients) as well as aggregate formation are considered. Using this approach the relevant parameters of the alamethicin-lipid system have been determined (yielding, in particular, a partition coefficient of 1.3 X 10(3) for the monomeric peptide and a critical aqueous concentration of 2.5 microM). Finally, the possible relevance of these results for the voltage-dependent gating of alamethicin is briefly pointed out.     

Template-free self-assembling fullerene and lipopeptide conjugates of alamethicin form voltage-dependent ion channels of remarkable stability and activity.

N- and C-terminally modified with fullerene or lipopeptide alamethicin molecules were designed for the formation of template-free, self-assembling, voltage-dependent ion conducting channels. The automated solid phase synthesis of the alamethicin-F30 sequence was performed by in situ fluoride activation on 2-chlorotritylchloride-polystyrene resin and the conjugation with fullerenes-C60 and -C70 was carried out in solution. Voltage-dependent bilayer experiments revealed preferred channel sizes for C-terminal alamethicin F30-fullerene-C60 and -C70 conjugates and higher activity compared with native alamethicin, whereas N-terminally linked fullerene balls destabilize pore formation. C-terminal alamethicin F30-fullerene-C70 conjugates show pore states with remarkably long lifetimes of seconds. C-terminal lipopeptide conjugates of alamethicin were prepared by coupling via short peptide spacers with synthetic tripalmitoyl-S-glyceryl-cysteine. which represents the strong membrane anchoring N-terminus of bacterial lipoprotein. Alamethicin-lipopeptide conjugates exhibit high channel forming activities, whereby they self-assemble and adopt preferred pore states with extremely long lifetimes. The novel membrane modifying peptaibol constructs are valuable lead compounds for developments in sensorics related to transmembrane ion conductance.     

Evidence for membrane thinning effect as the mechanism for peptide-induced pore formation

Antimicrobial peptides have two binding states in a lipid bilayer, a surface state S and a pore-forming state I. The transition from the S state to the I state has a sigmoidal peptide-concentration dependence indicating cooperativity in the peptide-membrane interactions. In a previous paper, we reported the transition of alamethicin measured in three bilayer conditions. The data were explained by a free energy that took into account the membrane thinning effect induced by the peptides. In this paper, the full implications of the free energy were tested by including another type of peptide, melittin, that forms toroidal pores, instead of barrel-stave pores as in the case of alamethicin. The S-to-I transitions were measured by oriented circular dichroism. The membrane thinning effect was measured by x-ray diffraction. All data were in good agreement with the theory, indicating that the membrane thinning effect is a plausible mechanism for the peptide-induced pore formations.     

Probability of alamethicin conductance states varies with nonlamellar tendency of bilayer phospholipids.

With few exceptions, membrane lipids are usually regarded as a kind of filler or passive solvent for membrane proteins. Yet, cells exquisitely control membrane composition. Many phospholipids found in plasma membrane bilayers favor packing into inverted hexagonal bulk phases. It was suggested that the strain of forcing such lipids into a bilayer may affect membrane protein function, such as the operation of transmembrane channels. To investigate this, we have inserted the peptide alamethicin into bilayer membranes composed of lipids of empirically determined inverted hexagonal phase "spontaneous radii" Ro, which will have expectably different degrees of strain when forced into bilayer form. We observe a correlation between measured Ro and the relative probabilities of different conductance states. States of higher conductance are more probable in dioleoylphosphatidylethanolamine, the lipid of highest curvature, 1/Ro, than in dioleoylphosphatidylcholine, the lipid of lowest curvature.     

High-resolution electrophysiology on a chip: Transient dynamics of alamethicin channel formation

Microstructured planar substrates have been shown to be suitable for patch clamp recording from both whole cells and isolated patches of membrane, as well as for measurements from planar lipid bilayers. Here, we further explore this technology with respect to high-resolution, low noise single-channel recording. Using solvent-free lipid bilayers from giant unilamellar vesicles obtained by electro-swelling, we recorded channels formed by the peptaibol alamethicin, a well-studied model system for voltage-dependent channels, focusing on the transient dynamics of single-channel formation upon application of a voltage step. With our setup, we were able to distinctly resolve dwell times well below 100 mus and to perform a thorough statistical analysis of alamethicin gating. Our results show good agreement with models that do not rely on the existence of non-conducting preaggregate states. Microstructured apertures in glass substrates appear promising with respect to future experiments on cellular ion channels reconstituted in suspended lipid membranes.     

Comparison of the conformation and orientation of alamethicin and melittin in lipid membranes

The secondary structure of alamethicin in lipid membranes below and above the lipid phase transition temperature Tt is determined by Raman spectroscopy and circular dichroism (CD) measurements. In both cases structural data are obtained by fitting the experimental spectra by a superposition of the spectra of 15 reference proteins of known three-dimensional structure. According to the Raman experiments, in a lipid bilayer above Tt alamethicin is helical from residue 1 to 12, whereas below Tt the helix extends from residue 1 to 16. The remaining C-terminal part is nonhelical up to the end residue 20 both above and below Tt. A considerable lower helix content is derived from CD, namely, 38% and 46% above and below Tt, respectively, in agreement with several reported values for CD in the literature. It is shown that the commonly used set of CD spectra of water-soluble reference proteins is unsuitable to describe the CD spectra of alamethicin correctly. Therefore the secondary structure of alamethicin as derived from CD measurements is at the present state of analysis unreliable. In contrast to the case of alamethicin, the CD spectra of melittin in lipid membranes are correctly described by the reference protein spectra. The helix content of melittin is determined thereby to be 72% in lipid membranes above Tt and 75% below Tt. The data are in accord with a structure where the hydrophobic part of melittin adopts a bent helix as determined recently by Raman spectroscopy [Vogel, H., & J?hnig, F. (1986) Biophys. J. 50, 573]. The orientational order parameters of the helical parts of alamethicin and of melittin in a lipid membrane are deduced from the difference between a corresponding CD spectrum of a polypeptide in planar multibilayers and that in lipid vesicles. The presented method for determining helix order parameters is new and may be generally applicable to other membrane proteins. The orientation of the helical part of both polypeptides depends on the physical state of the lipid bilayer at maximal membrane hydration and in the ordered lipid state furthermore on the degree of membrane hydration. Under conditions where alamethicin and melittin are incorporated in an aggregated form in a fluid lipid membrane at maximal water content the helical segments are oriented preferentially parallel to the membrane normal. Cooling such lipid membranes to a temperature below Tt changes the orientation of the helical part of alamethicin as well as melittin toward the membrane plane.(ABSTRACT TRUNCATED AT 400 WORDS)     

Signal transduction across alamethicin ion channels in the presence of noise.

We have studied voltage-dependent ion channels of alamethicin reconstituted into an artificial planar lipid bilayer membrane from the point of view of electric signal transduction. Signal transduction properties of these channels are highly sensitive to the external electric noise. Specifically, addition of bandwidth-restricted "white" noise of 10-20 mV (r.m.s.) to a small sine wave input signal increases the output signal by approximately 20-40 dB conserving, and even slightly increasing, the signal-to-noise ratio at the system output. We have developed a small-signal adiabatic theory of stochastic resonance for a threshold-free system of voltage-dependent ion channels. This theory describes our main experimental findings giving good qualitative understanding of the underlying mechanism. It predicts the right value of the output signal-to-noise ratio and provides a reliable estimate for the noise intensity corresponding to its maximum. Our results suggest that the alamethicin channel in a lipid bilayer is a good model system for studies of mechanisms of primary electrical signal processing in biology showing an important feature of signal transduction improvement by a fluctuating environment.     

Single-Molecule Investigation of the Influence Played by Lipid Rafts on Ion Transport and Dynamic Features of the Pore-Forming Alamethicin Oligomer

In this experimental work we employed single-molecule electrical recordings on alamethicin oligomers inserted in lipid bilayers made of brain sphingomyelin (bSM), palmitoyloleoylphosphatidylcholine (POPC) and cholesterol (chol) to unravel novel aspects regarding lipid raft interactions with pore-forming peptides. We probed the effect of lipid rafts on electrical properties of inserted alamethicin oligomers, and our data convincingly prove that the single-channel electrical conductance of various subconductance states of the alamethicin oligomer (1) increases in the presence of raft-containing ternary lipid mixtures (POPC-chol-bSM) compared to cases when bilayers were made of POPC-chol and POPC and (2) decreases in the presence of raft-containing ternary lipid mixtures compared to nonraft ternary mixtures which favor the fluid and liquid ordered phases alone. Our data demonstrate that the presence of lipid rafts leads to a slower association kinetics of alamethicin oligomers, seemingly reflecting a slower lateral diffusion process of such peptide aggregates compared to the case of nonraft, binary lipid mixtures. Furthermore, we show that the electrical capacitance of ternary lipid mixtures (POPC-chol-bSM) decreases in the presence of raft domains by comparison to nonraft binary phases (POPC-chol) or POPC alone, and this could constitute an additional mechanism via which macroscopic electrical manifestations of eukaryotic cells are modulated by the coexistence of gel and fluid domains of the plasma membrane.     

High-resolution electrophysiology on a chip: Transient dynamics of alamethicin channel formation

Microstructured planar substrates have been shown to be suitable for patch clamp recording from both whole cells and isolated patches of membrane, as well as for measurements from planar lipid bilayers. Here, we further explore this technology with respect to high-resolution, low noise single-channel recording. Using solvent-free lipid bilayers from giant unilamellar vesicles obtained by electro-swelling, we recorded channels formed by the peptaibol alamethicin, a well-studied model system for voltage-dependent channels, focusing on the transient dynamics of single-channel formation upon application of a voltage step. With our setup, we were able to distinctly resolve dwell times well below 100 μs and to perform a thorough statistical analysis of alamethicin gating. Our results show good agreement with models that do not rely on the existence of non-conducting preaggregate states. Microstructured apertures in glass substrates appear promising with respect to future experiments on cellular ion channels reconstituted in suspended lipid membranes.     

Differential susceptibility of phosphatidylcholine small unilamellar vesicles to phospholipases A2, C and D in the presence of membrane active peptides.

Activities of phospholipases C and D along with A2 were followed on egg phosphatidylcholine small unilamellar vesicles in the presence of membrane active peptides melittin, gramicidin S and alamethicin. Decrease in the activity of phospholipase C and D and enhancement of phospholipases A2 activity suggest that these enzymes are sensitive to alterations in the lipid packing in the membranes in the presence of these peptides. Phospholipase C and D, which have not been used to study peptide--membrane interactions, have potential use in studying membrane perturbations, since their activities are very sensitive to lipid packing.     

Oscillation phenomena in black lipid membranes induced by a single alamethicin pore.

In this paper we show how alamethicin (a small cyclic peptide of molecular weight 1691) can produce voltage oscillations in black lipid membranes and how a nonactin-alamethicin oscillator can be constructed. Alamethicin alone induces oscillations only with an applied bias current, but with nonactin and appropriate salt solutions oscillations occur with no bias current. Both kinds of oscillations can be quantitatively understood in terms of the known properties of alamethicin and nonactin and both depend on the statistical nature of the formation opores in the membrane by alamethicin.