Transport of large organic ions through syringomycin channels in membranes containing dipole modifiers

The effect of the membrane dipole potential (φ _d ) on conductance and the steady-state number of functioning channels formed by cyclic lipodepsipeptide syringomycin E (SRE) in bilayer lipid membranes made from phosphocholine and bathed in 0.4 M solution of sodium salts of aspartate, gluconate, and chloride was shown. The φ _d value varied with the introduction of phloretin to membrane bathing solutions, which reduces φ _d and RH 421, which increases φ _d . It was established that, in all studied systems, an increase in the membrane dipole potential caused a decrease in the steady-state number of open channels. In systems containing sodium salts of aspartate (Asp) or gluconate (Glc), changes in the number of functioning channels are one order lower than those of systems that contain sodium chloride. At the same time, the conductance (g) of single SRE channels in the membranes bathed in NaCl solution increases with increase in φ _d and in the systems containing NaAsp or NaGlc the conductance of single channels does not depend on the φ _d . The latter is due to the lack of cation/anion selectivity of the SRE channels in these systems. The different channel-forming activity of SRE in the experimental systems is determined by the gating charge of the channel and the partition coefficient of the dipole modifiers between the lipid and aqueous phases.     

Conductance of phytotoxin channels in the presence of large organic ions

In this study we evaluated the effect of the size of penetrating anions on properties of the channels formed by cyclic lipodepsipeptide syringomycin E (SRE) in bilayer lipid membranes. Conductance and the mean lifetime of SRE channels were measured in 0.4 M solutions of sodium chloride, aspartate, and gluconate. A comparison of results of conductometric and electrophysiological measurements has shown the following: (1) the ratio of mobilities of aspartate anions in the channel and in the aqueous solution is five times lower than that of chlorine anions and (2) the conductance of channels in the presence of sodium gluconate is due mainly to cations. The obtained results indicate the binding of penetrating anions to the selective filter of the SRE pore. The radius of the SRE channel selective filter has been established (r ∼ 0.3 nm) and its localization in the cis-mouth of the pore has been found.     

Interaction between filamentous actin and lipid bilayer causes the increase of syringomycin E channel-forming activity

The effect of filamentous (F) actin on the channel-forming activity of syringomycin E (SRE) in negatively charged and uncharged bilayer lipid membranes (BLM) was studied. F-actin did not affect the membrane conductance in the absence of SRE. No changes in SRE-induced membrane conductance were observed when the above agents were added to the same side of BLM. However, the opposite side addition of F-actin and SRE provokes a multiple increase in membrane conductance. The similar voltage dependence of membrane conductance, equal values of single channel conductance and the effective gating charge of the channels upon F-actin action suggests that the actin-dependent increase in BLM conductance may result from an increase in the number of opened SRE-channels. BLM conductance kinetics depends on the sequence of SRE and F-actin addition, suggesting that actin-dependent rise of conductance may be induced by BLM structural changes that follow F-actin adsorption. F-actin exerted similar effect on membrane conductance of both negatively charged and uncharged bilayers, as well as on conductance of BLM with high ionic strength bathing solution, suggesting the major role for hydrophobic interactions in F-actin adsorption on lipid bilayer.     

Kinetic parameters of single ion channels and stationary conductivities of phytotoxin modified lipid bilayers

As shown earlier, phytotoxins produced by Pseudomonas syringae pv. syringae form ion channels of "small" and "large" conductance when incorporated into planar lipid membranes. The multilevel conductance is due to cluster organization of the channels (Kaulin et al., 1998; Gurnev et al., 2002). In this study the kinetic parameters of syringomycin E (SRE) and syringostatin A (SSA) channels in negatively charged bilayer lipid membranes were estimated. The average time of open state of the small channels (t(s)(open)) did not depend on transmembrane voltage (in the range of +/- 200 mV). The channel characteristics differed between two phytotoxins: the t(s)(open) for the SRE-channels was much larger than that for SSA-channels. An energetic diagram with two non-conducting states illustrating the formation of the small channel is proposed to explain the voltage independence of the kinetic parameters. The probability for synchronous functioning of small channels with SSA was higher than that with SRE. To analyse the role of the clusters in the biological activities of SRE and SSA, we estimated the cluster contribution to a net transmembrane currents to be 60 and 90%, respectively.     

Actin and amphiphilic polymers influence on channel formation by Syringomycin E in lipid bilayers

The bacterial lipodepsipeptide syringomycin E (SRE) added to one (cis-) side of bilayer lipid membrane forms voltage dependent ion channels. It was found that G-actin increased the SRE-induced membrane conductance due to formation of additional SRE-channels only in the case when actin and SRE were applied to opposite sides of a lipid bilayer. The time course of conductance relaxation depended on the sequence of SRE and actin addition, suggesting that actin binds to the lipid bilayer and binding is a limiting step for SRE-channel formation. G-actin adsorption on the membrane was irreversible. The amphiphilic polymers, Konig’s polyanion (KP) and poly(Lys, Trp) (PLT) produced the actin-like effect. It was shown that the increase in the SRE membrane activity was due to hydrophobic interactions between the adsorbing molecules and membrane. Nevertheless, hydrophobic interactions were not sufficient for the increase of SRE channel-forming activity. The dependence of the number of SRE-channels on the concentration of adsorbing species gave an S-shaped curve indicating cooperative adsorption of the species. Kinetic analysis of SRE-channel number growth led to the conclusion that the actin, KP, and PLT molecules form aggregates (domains) on the trans-monolayer. It is suggested that an excess of SRE-channel formation occurs within the regions of the cis-monolayer adjacent to the domains of the adsorbed molecules, which increase the effective concentration of SRE-channel precursors.     

The effect of phloretin on sphingolipid-containing membranes modified by syringomycin E

The effects of dipole modifier phloretin on the activity of syringomycin (SRE) channels in the lipid bilayers containing different sphingolipids, N-stearoyl-phytosphingosine (PSP) and N-stearoyl-D-erythrosphingosine (DSP), have been compared. It is shown that the addition of phloretin up to a concentration of 10 μM into solutions bathing the bilayers containing 20 mol.% PSP causes a 170-fold increase in the SRE channel-forming activity. In the case of DSP-containing membranes, a more significant (5200-fold) increase of the equilibrium number of open SRE channels is observed. The enhancement of SRE activity is accompanied by about 2-fold increase of the gating charge of SRE channels in the membranes with PSP, while in the bilayers with DSP the gating charge increases about 4-fold. The revealed differences in the parameters of SRE channels in the membranes including phloretin and PSP or DSP are accounted for by different partition coefficients of the toxin and dipole modifier between the lipid and water phases. The data suggest heterogeneity of dipole potential of the PSP-containing membranes in the presence of phloretin. This heterogeneity is due to the possibility of formation in these membranes of rafts with the dipole potential not affected by modifier.     

The effect of dipole potential of lipid bilayers on the properties of ion channels formed by cyclic lipodepsipeptide syringomycin E

The effect of membrane dipole potential (? _d ) on the properties of ion channels formed in bilayer lipid membranes by syringomycin E (SRE), a toxin produced by Pseudomonas syringae, has been studied. It has been shown that ? _d affects the conductance and lifetime of elementary SRE channels as well as their cluster organization, in particular, the number of elementary channels synchronously opened in the cluster and the lifetime of these clusters. The channel-forming activity of SRE was found to be ? _d -dependent. The analysis of experimental data has revealed that (i) the mechanisms of the observed effects involve the dipole-dipole and charge-dipole interactions responsible for the cooperative functioning of the elementary SRE channels; (ii) about 95% of membrane dipole potential is shielded in the SRE pore; and (iii) the channel-forming activity of SRE is mainly determined by the gating charge of the SRE channels. At the same time, the partition coefficient for the toxin distribution between the membrane and aqueous phase as well as the chemical component of the channel formation work are also responsible for the ? _d -dependence of the SRE channel forming activity.     

Transport-related modulation of the membrane properties of toad urinary bladder epithelium.

Impedance analysis and transepithelial electrical measurements were used to assess the effects of the apical membrane Na+ channel blocker amiloride and anion replacement on the apical and basolateral membrane conductances and areas of the toad urinary bladder (Bufo marinus). Mucosal amiloride addition decreased both apical and basolateral membrane conductances (Ga and Gbl, respectively) with no change in membrane capacitances (Ca and Cbl). Consequently, the specific conductances of these membranes decreased without significant changes in membrane area. Following amiloride removal, an increase was obtained in the steady-state rate of sodium transport compared to values before amiloride addition. This increase was independent of the initial transport rate, suggesting activation of a quiescent pool of apical sodium channels. Chloride replacement by acetate or gluconate had no significant effects on apical or basolateral membrane capacitances. The effects of these replacements on membrane conductances depended on the anion species. Gluconate (which induces cell shrinkage) decreased both membrane conductances. In contrast, acetate (which induces cell swelling) increased Ga and had no effect on Gbl. The increase in the apical membrane conductance was due to an increase in the amiloride-sensitive Na+ conductance of this membrane. In summary, mucosal amiloride addition or chloride replacements led to changes in membrane conductances without significant effects on net membrane areas.     

Activity of toxins produced by Pseudomonas syringae pv. syringae in model and cell membranes

We studied effects of toxins produced by a bacterium Pseudomonas syringae pv. syringae on the conductance of bilayer lipid membranes (BLM). The used toxins were as follows: syringopeptin 22A (SP22A), syringomycin E (SPE), syringostatin A (SSA), syringotoxin B (STB), and methylated syringomycin E (CH3-SRE). All toxins demonstrated channel-forming activity. The threshold sequence for toxin activity was SP22A > SRE approximately equal to SSA > STB > CH3-SRE, and this sequence was independent of lipid membrane composition, and NaCl concentration (pH 6) in the membrane bathing solution (in the range of 0.1-1.0 M). This sequence correlated with relative bioactivities of toxins. In addition, SRE demonstrated a more potent antifungal activity than CH3-SRE. These findings suggest that ion channel formation may underlie the bioactivities of the above toxins. The properties of single ion channels formed by the toxins in BLMs were found to be similar, which points to the similarity in the channel structures. In negatively charged membranes, bathed with diluted electrolyte solutions (0.1 M NaCl), the channels were seen to open with positive transmembrane potentials (V) (from the side of toxin addition), and close with negative potentials. In uncharged membranes the opposite response to a voltage sign was observed. Increasing the NaCl concentration up to 1 M unified the voltage sensitivity of channels in charged and uncharged membranes: channels opened with negative V, and closed with positive V. With all systems, the voltage current curves of single channels were similarly superlinear in the applied voltage and asymmetric in its sign. It was found that the single channel conductance of STB and SSA was higher than that of other toxin channels. All the toxins formed at least two types of ion channels that were multiple by a factor of either 6 or 4 in their conductance. The results are discussed in terms of the structural features of toxin molecules.     

Voltage-dependent synchronization of gating of syringomycin E ion channels

Antifungal lipodepsipeptide syringomycin E (SRE) forms two major conductive states in lipid bilayers: "small" and "large". Large SRE channels are cluster of several small ones, demonstrating synchronous opening and closure. To get insight into the mechanism of such synchronization we investigated how transmembrane potential, membrane surface charge, and ionic strength affect the number of small SRE channels synchronously functioning in the cluster. Here, we report that the large SRE channels can be presented as 3-8 simultaneously gating small channels. The increase in the absolute value of the transmembrane potential (from 50 to 200 mV) decreases the number of synchronously gated channels in the clusters. Voltage-dependence of channel synchronization was influenced by the ionic strength of the bathing solution, but not by membrane surface charge. We propose a mechanism for the voltage-dependent cluster behavior that involves a voltage-induced reorientation of lipid dipoles associated with the channel pores.     

Sphingolipids Influence the Sensitivity of Lipid Bilayers to Fungicide,Syringomycin E

Sphingolipids with long chain bases hydroxylated at the C4 position are a requisite for the yeast, Saccharomyces cerevisia, to be sensitive to the ion channel forming antifungal agent, syringomycin E (SRE). A mutant S. cerevisiae strain, Δsyr2, having sphingolipids with a sphingoid base devoid of C4-hydroxylation, is resistant to SRE. To explore the mechanism of this resistance, we investigated the channel forming activity of SRE in lipid bilayers of varying composition. We found that the addition of sphingolipid-rich fraction from Δsyr2 to the membrane-forming solution (DOPS/DOPE/ergosterol) resulted in lipid bilayers with lower sensitivity to SRE compared with those containing sphingolipid fraction from wild-type S. cerevisiae. Other conditions being equal, the rate of increase of bilayer conductance was about 40 times slower, and the number of SRE channels was about 40 times less, with membranes containing Δsyr2 versus wild-type sphingolipids. Δsyr2 sphingolipids altered neither SRE single channel conductance nor the gating charge but the ability of SRE channels to open synchronously was diminished. The results suggest that the resistance of the Δsyr2 mutant to SRE may be partly due to the ability of sphingolipids without the C4 hydroxyl group to decrease the channel forming activity of SRE.     

Ion channels in urinary bladder.

Urinary epithelia separate urine from interstitial fluid. In the mammal, this tight epithelium has a limited transport capacity but is capable of moving sodium from urine to blood through an aldosterone-sensitive cellular pathway. In lower vertebrates, absorption of ions and water from the urine can contribute significantly to fluid and electrolyte homeostasis. Transepithelial ion transport and maintenance of cellular composition are interdependent, requiring a balance between movements across the apical and basolateral plasma membranes through a variety of pathways including electrodiffusion through ion channels. A variety of such channels has been identified in urinary epithelia. Apical membranes contain amiloride-sensitive, highly selective sodium channels of low conductance (approximately 5-10 pS). There is evidence that in mammalian bladders trypsin-like enzymes in the urine continually degrade these channels, decrease in cation selectivity being followed by loss of the channels from the membrane. New channels stored in the cytoplasm appear to provide a source for replenishment of the membrane. Other channels of higher conductance and lower selectivity have also been described in both mammalian and amphibian bladders, but their physiological significance remains to be established. Basolateral membranes contain potassium channels. In the mammalian bladder, in which chloride appears to be distributed at electrochemical equilibrium, chloride conductance exceeds potassium conductance and patch clamp studies have revealed a chloride channel of conductance approximately 60 pS detectable immediately on patch excision and active at normal membrane potentials. In the amphibian bladder, a variety of findings indicates the presence of a basolateral membrane chloride conductance, but patch clamp data are not yet available.     

Membrane dipole potential modulates proton conductance through gramicidin channel: movement of negative ionic defects inside the channel.

The effect of membrane dipole potential on gramicidin channel activity in bilayer lipid membranes (BLMs) was studied. Remarkably, it appeared that proton conductance of gramicidin A (gA) channels responded to modulation of the dipole potential oppositely as compared with gA alkali metal cation conductance. In particular, the addition of phloretin, known to reduce the membrane dipole potential, resulted in a decrease in gA proton conductance, on one hand, and an increase in gA alkali metal conductance, on the other hand, whereas 6-ketocholestanol, the agent raising the membrane dipole potential, provoked an increase in gA proton conductance as opposed to a decrease in the alkali metal cation conductance. The peculiarity of the 6-ketocholestanol effect consisted in its dependence on the H(+) concentration. The experiments with the impermeant dipolar compound, phloridzin, showed that the response of proton transport through gramicidin channels to varying the membrane dipole potential did not change qualitatively if the dipole potential of only one monolayer or both monolayers of the BLM was altered. In contrast to gA proton conductance, the single-channel lifetime changed similarly with varying the membrane dipole potential, regardless of the kind of permeant cations (protons or potassium ions). The results of this study could be tentatively accounted for by an assumption that one of the rate-limiting steps of proton conduction through gramicidin channels represents, in fact, movement of negatively charged species (negative ionic defects) across a membrane.     

Pore forming activity of the major outer membrane protein of Rhodobacter capsulatus in lipid bilayer membranes

Porin of the outer membrane of Rhodobacter capsulatus St. Louis (ATCC 23782) was isolated and reconstituted into lipid bilayer membranes. The porin was obtained either by the sodium dodecyl sulfate treatment of cell envelopes (SDS-porin) or by saline extraction of whole cells (NaCl-porin). Nanomolar concentrations of both porin preparations resulted in a strong conductance increase of the lipid bilayer membranes by many orders of magnitude. At small protein concentrations the conductance increased in a stepwise fashion, the average single channel conductance being about 0.35 nS in 0.1 M KCl for SDS-porin and NaCl-porin as well. The single channel conductance was a linear function of the specific conductance of the aqueous phase. The results were consistent with the assumption that the porin formed large water-filled transmembrane channels in the membrane. From the average value of the single channel conductance in 0.1 M KCl an effective channel diameter of about 1.5 nm was estimated for both types of porins.Abbreviations EDTA ethylenediamine tetraacetic acid - SDS sodium dodecyl sulfate     

The localization of transport properties in the frog lens.

The selectivity of fiber-cell membranes and surface-cell membranes in the frog lens is examined using a combination of ion substitutions and impedance studies. We replace bath sodium and chloride, one at a time, with less permeant substitute ions and we increase bath potassium at the expense of sodium. We then record the time course and steady-state value of the intracellular potential. Once a new steady state has been reached, we perform a small signal-frequency-domain impedance study. The impedance study allows us to separately determine the values of inner fiber-cell membrane conductance and surface-cell membrane conductance. If a membrane is permeable to a particular ion, we presume that the conductance of that membrane will change with the concentration of the permeant ion. Thus, the impedance studies allow us to localize the site of permeability to inner or surface membranes. Similarly, the time course of the change in intracellular potential will be rapid if surface membranes are the site of permeation whereas it will be slow if the new solution has to diffuse into the intercellular space to cause voltage changes. Lastly, the value of steady-state voltage change provides an estimate of the lens' permeability, at least for chloride and potassium. The results for sodium are complex and not well understood. From the above studies we conclude: (a) surface membranes are dominated by potassium permeability; (b) inner fiber-cell membranes are permeable to sodium and chloride, in approximately equal amounts; and (c) inner fiber-cell membranes have a rather small permeability to potassium.     

Lipid-mediated regulation of pore-forming activity of syringomycin E by thyroid hormones and xanthene dyes

The effects of dipole modifiers, thyroid hormones (thyroxine and triiodothyronine) and xanthene dyes (Rose Bengal, phloxineB, erythrosin, eosinY and fluorescein) on the pore-forming activity of the lipopeptide syringomycin E (SRE) produced by Pseudomonas syringae were studied in a model bilayer. Thyroxine does not noticeably influence the steady-state number of open SRE channels (N_op), whereas triiodothyronine decreases it 10-fold at − 50 mV. Rose Bengal, phloxine B and erythrosin significantly increase N_op by 350, 100 and 70 times, respectively. Eosin Y and fluorescein do not practically affect the pore-forming activity of SRE. Recently, we showed that hormones decrease the dipole potential of lipid bilayers by approximately 60 mV at 50 μM, while Rose Bengal, phloxine B and erythrosin at 2.5 μM reduce the membrane dipole potential by 120, 80 and 50 mV, respectively. In the present study using differential scanning microcalorimetry, confocal fluorescence microscopy, the calcein release technique and measurements of membrane curvature elasticity, we show that triiodothyronine strongly affects the fluidity of model membranes: its addition leads to a significant decrease in the temperature and cooperativity of the main phase transition of DPPC, calcein leakage from DOPC vesicles, fluidization of solid domains in DOPC/DPPC liposomes, and promotion of lipid curvature stress. Thyroxine exerts a weaker effect. Xanthene dyes do not influence the phase transition of DPPC. Despite the decrease in the dipole potential, thyroid hormones modulate SRE channels predominantly via the elastic properties of the membrane, whereas the xanthene dyes Rose Bengal, phloxine B and erythrosine affect SRE channels via bilayer electrostatics.     

Purification and patch clamp analysis of a 40-pS channel from rat liver mitochondria.

Patch clamp analysis of membranes reconstituted with a fraction isolated from detergent-solubilized mitochondrial membranes by affinity chromatography on immobilized quinine earlier indicated the presence of two classes of ion channels, of about 40- and 140-pS conductance in medium including 150 mM KCl. Now a 57-kDa constituent of the quinine-affinity column eluate has been identified as the 40-pS channel. Protein fractions derived from the quinine-affinity column eluate by preparative isoelectric focusing with a Rotofor cell have been reconstituted into phospholipid vesicle membranes by detergent dialysis, and vesicles have been enlarged for patch clamping by dehydration and rehydration. Voltage clamp analysis has been carried out on excised patches bathed symmetrically in buffered medium containing 150 mM KCl and 100 microM CaCl2. Patches of membrane incorporating the 57-kDa protein exhibit 40-pS conductance transitions. The magnitude of conductance transitions is similar when Na+ replaces K+ in the bathing medium, indicating little selectivity of the 40-pS channel for K+ relative to Na+. Another fraction derived from the quinine-affinity column eluate is found to contain the larger channel, now estimated to have an average conductance of about 130 pS. Patches of control membrane prepared in the same way but without protein exhibit no channel activity.     

Electrical conductivity of bilayer lipid membranes in electrolytic solution

The electrical conductivity of bilayer lipid membranes (BLM) of oxidized cholesterol has been measured separately in bathing solutions of sodium sulphate, sodium chloride, sodium bromide, sodium iodide and also in bathing solutions of iodine and iodine containing these salts. An attempt has been made to explain the conduction of electric current across the membranes.     

Outer membrane protein P of Pseudomonas aeruginosa: regulation by phosphate deficiency and formation of small anion-specific channels in lipid bilayer membranes.

A new major outer membrane protein, P, was induced in Pseudomonas aeruginosa PAO1 upon growth in medium containing 0.2 mM or less inorganic phosphate. Studies with media containing different levels of phosphate and with mutants of PAO1 suggested that protein P was coregulated with alkaline phosphatase and phospholipase C. Protein P was substantially purified and shown to form sodium dodecyl sulfate-resistant oligomers on polyacrylamide gels. The incorporation of purified protein P into artificial lipid bilayers resulted in an increase of the membrane conductance by many orders of magnitude. Single-channel experiments demonstrated that protein P channels were substantially smaller than all previously studied porins from P. aeruginosa and enteric bacteria, with an average single-channel conductance in 1 M NaCl of 0.25 nS. The protein P channel was apparently not voltage induced or regulated. The results of single-channel conductance experiments, using a variety of different salts, allowed a minimum channel diameter estimate of 0.7 nm. Furthermore, from these results it was concluded that the protein P channel was highly specific for anions. Zero-current potential measurements confirmed that protein P was at least 30-fold more permeable for Cl- than for K+ ions. The possible biological role of the small, anion-specific protein P channels in phosphate uptake from the medium is discussed.     

Probing amphotericin B single channel activity by membrane dipole modifiers

The effects of dipole modifiers and their structural analogs on the single channel activity of amphotericin B in sterol-containing planar phosphocholine membranes are studied. It is shown that the addition of phloretin in solutions bathing membranes containing cholesterol or ergosterol decreases the conductance of single amphotericin B channels. Quercetin decreases the channel conductance in cholesterol-containing bilayers while it does not affect the channel conductance in ergosterol-containing membranes. It is demonstrated that the insertion of styryl dyes, such as RH 421, RH 237 or RH 160, in bilayers with either cholesterol or ergosterol leads to the increase of the current amplitude of amphotericin B pores. Introduction of 5α-androstan-3β-ol into a membrane-forming solution increases the amphotericin B channel conductance in a concentration-dependent manner. All the effects are likely to be attributed to the influence of the membrane dipole potential on the conductance of single amphotericin B channels. However, specific interactions of some dipole modifiers with polyene-sterol complexes might also contribute to the activity of single amphotericin B pores. It has been shown that the channel dwell time increases with increasing sterol concentration, and it is higher for cholesterol-containing membranes than for bilayers including ergosterol, 6-ketocholestanol, 7-ketocholestanol or 5α-androstan-3β-ol. These findings suggest that the processes of association/dissociation of channel forming molecules depend on the membrane fluidity.