Ion-Pairing Mechanism for the Valinomycin-Mediated Transport of Potassium Ions across Phospholipid Bilayers

The role of the anion on the ionophore properties of valinomycin was studied in a model floating bilayer lipid membrane (fBLM) using supporting electrolytes containing K⁺ with four different counter anion species (ClO₄^-, H₂PO₄^-, Cl^-, and F^-). The electrochemical impedance spectra indicate that the membrane resistance of the bilayer decreases with the decrease of Gibbs free energy of anion solvation. The IR spectra demonstrate that valinomycin does not readily bind to K⁺ in the KH₂PO₄, KCl, and KF electrolyte solutions, but in the presence of KClO₄, valinomycin readily binds to K⁺, forming a valinomycin-K⁺ complex. The results in the present paper reveal the role of the counter anion on the transport of cations by valinomycin across the lipid bilayer. The valinomycin-cation complex creates an ion pair with the anion, and this ion pair can enter the hydrophobic region of the bilayer transporting the cation across the membrane. Anions with low solvation energies facilitate the formation of the ion pair improving the ion conductivity of valinomycin-incorporated bilayers. This paper sheds new light on the transport mechanism of valinomycin ionophores and provides new information about the bioactivity of this molecule.

K+-selective nanospheres: maximising response range and minimising response time

Cross-linked K(+) ion-selective copolymer nanospheres have been prepared by free-radical photo-initiated polymerization of n-butyl acrylate (nBA) with hexanedioldiacrylate (HDDA). Nanospheres (<200 nm) containing H(+)-chromoionophore (ETH 5294) and lipophilic salt (KTClPB) for H(+)-sensors, or ETH 5294, a K(+)-selective ionophore (valinomycin) and anionic sites for K(+)-sensors were compared, and the effect of varying the normalised concentrations for beta (R(T)(-)/L(T)) and gamma (C(m)(T)/L(T)) was studied. Experimental data were fitted to theoretical curves for the dynamic response range, based on the effect of changes in the concentration of these lipophilic sensing components incorporated into the spheres, and conditions identified for maximising the response range. A complex valinomycin-K(+) formation constant, log K(IL) = 13.13 +/- 2.22, was obtained in the nBA matrix, and from the calibration curves the apparent acid-dissociation equilibrium constant (pK(a) = 12.92 +/- 0.03) was extracted for the H(+)-sensing system, and the equilibrium exchange constant (pK(exch) = 6.16 +/- 0.03, at pH 7) calculated for the K(+)-sensing nanospheres. A basis for establishing optimum performance was identified, whereby response range and response time were balanced with maximum fluorescence yield. Parameters for achieving nanospheres with a response time <5 minutes, covering 2-3 orders of magnitude change in activity were identified, demanding nanospheres with radius <300 nm and beta(crit) approximately 0.6. An RSD(%) approximately 3% was obtained in a study of the reproducibility of the response of the proposed nanospheres, and selectivity was also evaluated for a K(+)-selective nanosensor using several cations as interfering agents. In most cases, the fluorescent emission spectra showed no response to the cations tested, confirming the selectivity of nanospheres to potassium ion. The nanosensors were satisfactorily applied to the determination of K(+) in samples mimicking physiological conditions.

Measuring the dielectric properties of herpes simplex virus type 1 virions with dielectrophoresis

An investigation has been performed into the biophysical properties of the enveloped mammalian virus, herpes simplex virus type 1 (HSV-1). The dielectrophoretic behaviour of the virus particles was measured as a function of applied frequency (over the range 100 kHz-20 MHz) and conductivity of the suspending medium (over the range 1-100 mS m(-1)). The dielectric properties of the virus were determined from the dielectrophoretic data using the smeared-out shell model. The data suggest that the intact particle has a surface conductance of 0.3 nS, an internal and membrane permittivity of 75varepsilon(o) and 7.5varepsilon(o), respectively, an internal conductivity of approximately 0.1 S m(-1) and a zeta potential of 70 mV. The dielectric properties were measured for intact, fresh virus particles and also for particles following exposure to various modifying agents, such as treatment with enzymes, ionophores and ageing. It is shown that the observed changes in the dielectrophoretic spectrum, and the variations in the dielectric properties of the virus concur with the expected physiological effects of these agents.

Potentiometric estimation of the stability constants of ion-lonophore complexes in ion-selective membranes by the sandwich membrane method: theory, advantages, and limitations

Segmented sandwich membrane method of studying stoichiometry and stability constants of ion-ionophore complexes in ion-selective membranes is considered in detail. The experimental data (reported earlier in Russian) concerning complexes of various ions with valinomycin, with H+-selective neutral ionophore hexabutyltriamidophosphate, and with anion-binding neutral ionophore p-hexyl trifluoroacetylbenzoate is presented in a compact form. Advantages of titration technique in the sandwich membrane method (the presence of an internal criterion of reliability, and the possibility of direct determination of complex stoichiometry coefficients) are specially addressed. Biases of the estimates of the constants caused by ion-pair formation in real membranes and by diffusion potential are analyzed by means of computer simulations. The possibility of revealing two coexisting complexes with different compositions is also discussed.

Ion chromatography detector based on solid-state ion-selective electrode array

A variety of neutral carrier type ionophores for monovalent cations were employed to prepare solid-state cation-selective electrodes (SSEs) for use as a detector in single-column ion chromatography (IC). The polyurethane-based pseudoreference electrode made it possible to assemble an array type SSE detector for IC. An SSE-based detector provides not only the overall chromatogram for the separated ion species (monensin methyl ester-nonactin-based membrane), but also the enhanced chromatogram for specified ions of interest (valinomycin as K+ and nonactin for NH4+). This feature makes it possible to perform highly quantitative analysis with low detection limits even if the separation efficiency of the ion-exchange is not sufficient. Since SSE-based IC detectors are easily miniaturized and replaceable at low cost, they are an ideal component of a portable IC system.

A peptide analogue to a fusion domain within photoreceptor peripherin/rds promotes membrane adhesion and depolarization

Photoreceptor peripherin/rds promotes membrane fusion, through a putative fusion domain located within the C-terminus (Boesze-Battaglia et al., Biochemistry 37 (1998) 9477-9487). A peptide analogue to this region, PP-5, competitively inhibits peripherin/rds mediated fusion in a cell free assay system. To characterize how this region is involved in the fusion process we investigated two of the individual steps in membrane fusion, membrane adhesion and membrane destabilization inferred from depolarization studies. Membrane depolarization was measured as the collapse of a valinomycin induced K(+) diffusion potential in model membranes, using a potential sensitive fluorescent probe, diS-C(2)-5. PP-5 induced membrane depolarization in a concentration dependent manner. PP-5 has been shown by Fourier transform infrared spectroscopy to be an amphiphilic alpha-helix. Therefore, the requirement for an amphiphilic alpha-helix to promote depolarization was tested using two mutant peptides designed to disrupt either the amphiphilic nature of PP-5 (PP-5AB) or the alpha-helical structure (PP-5HB). PP-5AB inhibited PP-5 induced depolarization when added in an equimolar ratio to PP-5. Neither mutant peptide alone or in combination with PP-5 had any effect on calcium dependent vesicle aggregation. Using non-denaturing gel electrophoresis and size exclusion chromatography techniques PP-5 was shown to form a tetrameric complex. Equimolar mixtures of PP-5 and PP-5AB formed a heterotetramer which was unable to promote membrane depolarization. The hypothesis that PP-5 tetramers promote membrane depolarization is consistent with the calculated Hill coefficient of 3.725, determined from a Hill analysis of the depolarization data.

Liver mitochondria, confirmed as intact by complete suppression of succinate uptake and oxidation, possess a carnitine palmitoyltransferase I that is totally inhibited by malonyl CoA

Succinate dehydrogenase activity in mitochondria, which were isolated by centrifuging partially purified mitochondria through 1. 315 M sucrose, was completely suppressed when [14C]succinate uptake was abolished by prior incubation of the mitochondria with carbonyl cyanide p-trifluoromethoxyphenylhydrazone (FCCP) and valinomycin. The conclusion that these mitochondria were intact was confirmed by the fact that, when these mitochondria were broken by a freeze-thaw cycle followed by sonication, such inhibition was totally abolished. The yield of mitochondria, microsomes, and peroxisomes from the initial homogenate was 17.8, <0.1, and 0%, respectively, indicating that the mitochondria were not only intact but also essentially free of contamination from microsomes and peroxisomes. The overt form of carnitine palmitoyltransferase (CPT I) in these intact and pure mitochondria was totally inhibited by malonyl CoA, indicating that previous reports of incomplete inhibition in mitochondrial preparations resulted from interference from CPT activity in the inner mitochondrial membrane (CPT II), microsomes, or peroxisomes.

[Protection against myocardial ischemia by nisoldipine--an experimental study with valinomycin K-sensitive microelectrodes]

It has been shown that dihydropyridines exert a cardioprotective effect during experimental ischemia. This effect is reflected in a reduced K-efflux from the ischemic tissue. Recently we have shown that ischemic K-efflux is largely mediated by ATP-dependent K-channels. Using K-selective microelectrodes we studied the effect of nisoldipine on K-efflux during simulated ischemia (guinea pig papillary muscle immersed in paraffin oil; normal Tyrode solution, HEPES buffered, 100% O2-equilibrated, 37 degrees C). While ischemic K-efflux was Ca-dependent in stimulated preparations, it was independent of extracellular Ca in resting preparations. Our results show that nisoldipine leads to an inhibition of ischemic K-efflux during simulated ischemia. In resting preparations this inhibition is not a direct Ca-antagonistic effect, since withdrawal of extracellular Ca does not inhibit ischemic K-efflux but nisoldipine does. We suggest a direct effect of nisoldipine on the KATP channel which is mainly responsible for ischemic K-loss.

Streaming potentials in gramicidin channels measured with ion-selective microelectrodes

Streaming potentials have been measured for gramicidin channels with a new method employing ion-selective microelectrodes. It is shown that ideally ion-selective electrodes placed at the membrane surface record the true streaming potential. Using this method for ion concentrations below 100 mM, approximately seven water molecules are transported whenever a sodium, potassium, or cesium ion, passes through the channel. This new method confirms earlier measurements (Rosenberg, P.A., and A. Finkelstein. 1978. Interaction of ions and water in gramicidin A channels. J. Gen. Physiol. 72:327-340) in which the streaming potentials were calculated as the difference between electrical potentials measured in the presence of gramicidin and in the presence of the ion carriers valinomycin and nonactin.

[Respiration and ion permeability of the inner membrane in rat "sodium" liver mitochondria]

Ion permeability of internal membrane and a respiration in isolated rat liver mitochondria, further related to as "sodium ones", were studied following replacement of K+ ions for Na+ ones in the mitochondrial matrix. As compared with the control ("potassium mitochondria"), state 4 respiration in the sodium mitochondria, energized by succinate, was shown to be enhanced in KCl or sucrose media. Oxygen consumption rates in the sodium mitochondria, being in state 3 or stimulated by 2,4-dinitrophenol, were lower than rates for the control mitochondria. This effect was much pronounced in the sucrose medium. The coefficients, characterizing the distribution of 137Cs between mitochondria and the medium, were lower for the sodium mitochondria than for the control in the presence of 2.5 mM succinate and 10(-8) M valinomycin. In comparison with the control, a more extensive swelling for the sodium mitochondria was found, first, in the medium containing 25 mM K-acetate and 100 mM sucrose for succinate-energized mitochondria, and second, in the medium containing 125 mM NH4NO3 without mitochondrial energization. Changes disclosed in respiration, swelling and coefficients of 137Cs distribution for the sodium mitochondria are supposed to be caused by non-uniform effects of Na+ and K+ ions on the water structure of mitochondrial matrix, ion permeability of internal membrane, and the activity in oxidative phosphorylation enzymes.

Phospholipid subclass specific alterations in the passive ion permeability of membrane bilayers: separation of enthalpic and entropic contributions to transbilayer ion flux

Alterations in phospholipid class, subclass, and individual molecular species contribute to the diversity of biologic membranes, but their effects on membrane passive ion permeability have not been systematically studied. Herein, we developed a simple and efficient fluorescence technique based upon the loss of valinomycin-inducible membrane potential to characterize the passive flux of ions across phospholipid bilayers. Detailed kinetic characterization of ion flux across membrane bilayers composed of discrete chemical entities demonstrated that the class, subclass, and individual molecular species of each phospholipid have substantive effects on membrane passive ion permeability properties. Increasing the degree of unsaturation in either the sn-1 or sn-2 aliphatic chains in phosphatidylcholine markedly enhanced transmembrane ion flux, with over 10-fold differences in the first-order rate constant manifested in molecular species containing four double bonds in comparison to those possessing three double bonds (e.g., kapp = 0.0014 min-1 for 1-octadec-9'-enoyl-2-octadec-9', 12'-dienoyl-sn-glycero-3-phosphocholine (18:1-18:2 phosphatidylcholine) while kapp = 0.021 min-1 for 1,2-dioctadec-9', 12'-dienoyl-sn-glycero-3-phosphocholine (18:2-18:2 phosphatidylcholine)). Moreover, although the apparent first-order rate constants for transmembrane ion flux in vesicles composed of phosphatidylcholine or plasmanylcholine containing palmitate at the sn-1 position and arachidonate at the sn-2 position were similar (kapp = 0.04 min-1 at 22 degreesC for both), the kapp for corresponding vesicles composed of plasmenylcholine was 20-fold less (kapp = 0.002 min-1 at 22 degreesC). Examination of the temperature dependence of passive membrane ion permeability demonstrated that altered ion flux across membranes composed of choline glycerophospholipids was primarily due to entropic effects without substantial changes in the activation energy for ion translocation. For example, Ea = 19.7 +/- 0.5 and 20.7 +/- 0.6 kcal.mol-1 for 1-hexadecanoyl-2-eicosa-5',8',11', 14'-tetraenoyl-sn-glycero-3-phosphocholine (16:0-20:4 phosphatidylcholine) and 1-O-(Z)-hexadec-1'-enyl-2-eicosa-5',8',11', 14'-tetraenoyl-sn-glycero-3-phosphocholine (16:0-20:4 plasmenylcholine), respectively, while their difference in the entropies of activation (DeltaS) was 4.3 +/- 0.5 cal.mol-1.K-1. Collectively, these results identify substantial differences in the membrane passive ion permeability properties of phospholipid classes, subclasses, and molecular species present in biologic membranes of eukaryotic cells and identify entropic alterations as an important contributor to these differences.

In vitro study of passive nitrate transport by native and reconstituted plasma membrane vesicles from corn root cells

Proteins from phase-partitioned corn root plasma membrane were reconstituted into soybean lipids/egg PC (8:2, w:w) using deoxycholate and rapid gel filtration to eliminate the detergent. All (H+)ATPase molecules were inside-out reinserted and the initial activity was totally recovered in an homogeneous vesicle preparation. In addition, membrane tightness greatly increased, as shown by the size and stability of the response of the fluorescent membrane potential probe (oxonol VI) to an imposed K+ diffusion gradient. Consequently, the H(+)-pumping activity of the (H+)ATPase, monitored with the fluorescent pH probe (ACMA), increased 20-fold after reconstitution. A protein-mediated passive transport of nitrate was first demonstrated by the ability of NO3- to electrically short-circuit the (H+)ATPase in plasma membrane vesicles and not in liposomes containing only the purified enzyme. The passive transport was saturable (K(m) approximately 5 mM), thermolabile, inhibited by the arginine reagent phenylglyoxal, and selective (NO3- > I- approximately ClO3- approximately Br- > Cl- approximately NO2- > Iminodiacetate approximately SO4(2-)). Passive NO3- transport was also determined, independently of the (H+)ATPase, from the NO3(-)-dependent augmentation of the dissipation rate of imposed diffusion potentials. This second transport assay gave similar K(m) for NO3- and should be suitable to continue the functional and biochemical characterization of the NO3- transport system.

Functional heterogeneity of an isolated mitochondrial population revealed by cytofluorometric analysis at the single organelle level

Isolated rat liver mitochondria were incubated under various metabolic conditions to determine their membrane potential (MMP) as measured continuously by a tetraphenylphosphonium (TPP+)-selective electrode. By flow cytometry, a parallel analysis of fluorescence emissions observing single mitochondria stained with the lipophilic cation 5,5',6,6'-tetrachloro-1,1'3,3'-tetraethylbenzimidazolcarbocyanine iodide (JC-1) revealed linear correlation between the median orange fluorescence (FL2) due to J-aggregate formations and MMP values measured by TPP+. No correlation was detected with the green fluorescence (FL1) emission. A significantly higher correlation appeared between the FL2/FL1 ratio and MMP values. Within the same mitochondrial population, cytofluorimetric analysis revealed the presence of various classes of organelles with different MMP, whose distribution was dependent on metabolic condition. The highest functional heterogeneity was found in deenergized mitochondria, while the highest homogeneity was observed during the first phase of the phosphorylative process. Thus, these data suggest that the cytofluorimetric use of JC-1 provides direct experimental evidence for the hypothesis of functional mitochondrial heterogeneity, at least with respect to their membrane potential.

The transport mechanisms of organic cations and their zwitterionic derivatives across rat intestinal brush-border membrane. II. Comparison of the membrane potential effect on the uptake by membrane vesicles

Further investigation of organic cation transport mechanisms were continued using rat intestinal brush-border membranes following our previous report. The net uptake of organic cations was superior to that of their zwitterionic derivatives. This result agreed with the absorption behaviour of these compounds from rat intestinal loop. The uptake of tyramine and 5-benzyloxytryptamine was significantly stimulated by the valinomycin-generated K(+)-diffusion potential (inside-negative). On the other hand, the uptake of zwitterionic derivatives was not affected by the valinomycin-induced K(+)-diffusion potential. The voltage-clamped brush-border membrane vesicles exhibited a complete disappearance of the overshoot-uptake of organic cations. Therefore, this permeation mechanism across the intestinal brush-border membrane seems to be different from the well-known H(+)-antiport system of organic cation found in other organs such as kidney and liver, and depends upon an inside-negative H(+)- or K(+)-diffusion potential.

Determination of potassium by dry reagent carrier technology: a multicentre evaluation

We describe the construction, the reaction principle and the performance of Reflotron K+, a new Reflotron test for the quantitative determination of potassium in serum and heparinized plasma. The reaction principle is based on the introduction of the potassium cation via valinomycin into a non-polar phase; the accompanying loss of protons from the non-polar phase is detected by the colour change of a pH indicator. The multicentre evaluation of the reagent carrier system showed in median CVs of < 0.9% (within-series in heparinized plasmas) and 1.3% (run-to-run in control sera). The recovery in control sera was +/- 4% for seven laboratories. In the method comparison with flame emission spectrometry, using sera and heparinized plasma samples, regression analysis yielded correlations with slopes of 1.00 +/- 0.04 (median slope 1.005) and negligible intercepts. The reagent carrier system showed a linear response in the measuring range 2-12 mmol/l. Bilirubin (up to 513 mumol/l), triacylglycerols (up to 5,7 mmol/l), sodium (135-189 mmol/l) and ammonium ions (up to 590 mumol/l) did not interfere with the test. Comparison with the results from flame atomic emission spectrometry shows that the recoveries of Reflotron K+ and the direct potentiometric method are slightly and similarly influenced by total protein. With a panel of 28 drugs tested, no interference could be detected. Reflotron K+ provides a precise and reliable procedure for the measurement of potassium in serum and heparinized plasma.

Evidence in favor of the existence of a kinetic barrier for proton transfer from a surface of bilayer phospholipid membrane to bulk water

When the hydrogen-ion flux is induced by nigericin across the planar bilayer lipid membrane (BLM) with bulk pH values being equal at the opposite sides of the BLM, formation of a difference in boundary potentials (delta phi b) on the membrane is observed by the method of inner membrane field compensation. pH gradients are titrated routinely by the addition of sodium acetate at one side of the membrane. The increase in buffer concentration (citrate, phosphate, Mes) leads to a decrease in delta phi b. delta phi b forms in the presence of phosphatidylserine in the membrane-forming solution only. It is concluded that the steady-state difference of the hydrogen ion binding to the opposite surfaces of the membrane (HIBD) is created under the conditions of equal pH values near surfaces of the BLM. The model of the processes implies that nigericin transfers proton predominantly from interface to interface while acetate transfers the proton from bulk phase to bulk phase. In the other series of experiments the monensin-mediated formation of the HIBD leads to the formation of an potassium-ion gradient in the presence of nigericin. Thus, a possibility of performing a work due to the formation of HIBD is demonstrated. Owing to these properties the hydrogen-ion binding difference can be interpreted in a first approximation as a difference of surface hydrogen-ion concentration at the opposite sides of the membrane, arising due to the existence of a kinetic barrier for the proton transfer at the membrane interfaces. These findings can be significant for the mechanism of energy transduction in membrane phosphorylation in mitochondria and chloroplasts.

Membrane changes accompanying the induced differentiation of Friend murine erythroleukemia cells studied by dielectrophoresis

Dielectrophoresis measurements obtained using an image processing technique are reported over the frequency range 1 Hz to 100 kHz for the Friend murine erythroleukemia cell lines DS19 and R1 before and after treatment with hexamethylene bisacetamide and dimethylsulfoxide, agents that induce terminal differentiation in DS19 but not in R1 cells. Data are analyzed according to the single shell dielectric model of the cell. The membrane capacitance was found to fall by 30% and membrane conductivity by a factor of at least 5 when DS19 cells were induced to differentiate. R1 cells showed no such response. While the theoretical model was found to be useful for comparing differences in data for the different cell lines, several significant discrepancies between its predictions and the experimental data were observed, including positive dielectrophoretic collection at frequencies below 20 Hz and a smaller than predicted response to the membrane permeabilizing agents saponin and valinomycin. Factors that may have accounted for these discrepancies include surface charge effecgs, conduction parallel to the plasma membrane surface, and intracellular compartments.

A nucleotide-regulated Cl-/OH- anion exchanger in endoplasmic reticulum-enriched pig pancreatic microsomes

The anion conductive pathways in preparations of endoplasmic reticulum (ER)-enriched microsomes from pig pancreas were investigated. The rate of swelling induced by cation ionophores (nigericin (nig) and/or valinomycin (val)) was measured in iso-osmotic solutions by light scattering, in the presence or absence of an inward Cl- and/or pH gradients. The rate of swelling in the presence of the inward Cl- gradient and ionophores was faster than that of controls. Low pH did not change the swelling rate in the presence of valinomycin, but it increased it in the presence of nigericin. When the Cl- gradient was abolished, valinomycin plus the pH gradient increased the rate of swelling, and this was further enhanced by nigericin. Anion transport inhibitors reduced the swelling rate. The nigericin-induced swelling was stimulated by ATP and GTP. The non-hydrolysable analogues, adenosine 5'-[beta,gamma-methylene]triphosphate, guanosine 5'-[beta-thio]triphosphate and guanosine 5'-[beta-thio]diphosphate, increased the rate of swelling, whereas adenosine 5'-[gamma-thio]triphosphate inhibited it. ADP, CTP and UTP had no effect. These data suggest the presence of a Cl-/OH- exchanger and a Cl- conductance in microsomes. They indicate that nucleotides may regulate the Cl-/OH- exchanger. Nucleotides do not need to be hydrolyzed but phosphorylation may occur to counter-balance the nucleotide-induced stimulation.

Uric acid transport in rat renal basolateral membrane vesicles

Pathways for urate transport across the basolateral membrane of rat proximal tubule cells were investigated using membrane vesicles isolated from rat renal cortex. The presence of an anion exchange mechanism(s) operative in the mode of alpha-keto-glutarate/urate; Cl-/urate and OH-(HCO3-)/urate as well as a mediated conductive mechanism was assessed from tracer flux measurements. In the presence of an inwardly directed Na+ gradient an alpha-ketoglutarate dependent concentrative accumulation of PAH but not urate was observed suggesting an absence of the mediated exchange of alpha-ketoglutarate for urate. The imposition of an outwardly directed Cl- gradient stimulated urate uptake in the absence but not the presence of conditions designed to minimize membrane potential development suggesting an indirect electrostatic coupling of urate uptake to a Cl- gradient-induced diffusion potential. Conditions favoring the development of an inside-positive K+ diffusion potential was observed to induce an inhibitor-sensitive, concentrative accumulation of urate in the absence of Cl-. The stimulation of urate uptake measured in the presence of an inside-alkaline pH gradient was not of sufficient magnitude to suggest the apparent conductive urate uptake was secondary to a membrane voltage induced, inside alkaline pH gradient and the operation of an OH-(HCO3-)/urate exchanger. The evidence obtained from the present investigation suggests rat basolateral membrane urate transport occurs by a mediated, conductive mechanism and is not coupled to Cl-, alpha-ketoglutarate or HCO3-.(ABSTRACT TRUNCATED AT 250 WORDS)

Quantitative measurement of cationic fluxes, selectivity and membrane potential using liposomes multilabelled with fluorescent probes

Liposomes of egg PC/PG (8:2, mol/mol) were multilabelled with PBFI, pyranine and oxonol VI, fluorescent probes for, respectively, K+, H+ and membrane potential. Monitoring fluorescence with a multichannel photoncounting spectrofluorometer during K+ filling experiments allowed to measure K+ influx, the associated H+ efflux and the membrane potential, continuously and simultaneously. The proton net efflux quantitatively mirrored the K+ net influx. The rate of the K+/H+ exchange diminished progressively as a quasi-equilibrium was reached for both K+ and H+. In the presence of valinomycin, the measured membrane potential during the K+ filling actually corresponded to the Nernst potential calculated from the observed K+ gradient. In the absence of valinomycin, it corresponded to the Nernst potential calculated from the observed H+ gradient. In the latter case, the permeability coefficient of liposomes to K+, calculated from the Goldman-Hodgkin-Katz relation, was 6.10(-13) m s-1. The selectivity sequence for alkali cations of liposomes was determined from the measured H+ efflux associated to the influx of the different cations. The selectivity sequence corresponded to the series VI of Eisenman, suggesting interaction of the cation with an anionic field of intermediate strength.

Interaction of antimicrobial dermaseptin and its fluorescently labeled analogues with phospholipid membranes

Dermaseptin, a 34 amino-acid residue antimicrobial polypeptide [Mor, A., Nguyen, V. H., Delfour, A., Migliore-Samour, D., & Nicolas, P. (1991) Biochemistry 30, 8824-8830] was synthesized and selectively labeled at its N-terminal amino acid with either 7-nitrobenz-2-oxa-1,3-diazole-4-yl (NBD), rhodamine, or fluorescein. The fluorescent emission spectra of the NBD-labeled dermaseptin displayed a blue-shift upon binding to small unilamellar vesicles (SUV), reflecting the relocation of the fluorescent probe to an environment of increased apolarity. Titrations of solutions containing NBD-labeled dermaseptin with SUV composed of zwitterionic or acidic phospholipids were used to generate binding isotherms, from which were derived surface partition constants of (0.66 +/- 0.06) x 10(4) M-1 and (2.8 +/- 0.3) x 10(4) M-1, respectively. The shape of the binding isotherms, as well as fluorescence energy transfer measurements, suggests that some aggregation of membrane-bound peptide monomers occurs in acidic but not in zwitterionic vesicles. The preferential susceptibility of the peptide to proteolysis when bound to zwitterionic but not to acidic SUV suggests that these aggregates might then penetrate a relatively short distance into the hydrophobic region of the acidic membrane. Furthermore, the results provide good correlation between the peptide's strong binding and its ability to permeate membranes composed of acidic phospholipids, as revealed by a dissipation of diffusion potential and a release of entrapped calcein from SUV.

Electrostatic potential barrier in asymmetric planar lipopolysaccharide/phospholipid bilayers probed with the valinomycin-K+ complex

Using the carrier-ion complex valinomycin-K+, current/voltage (I/U) characteristics were registered for planar asymmetric lipid bilayers composed on one side of a phospholipid mixture and on the other side of rough mutant lipopolysaccharide. This system resembles the lipid matrix of the outer membrane of Gram-negative bacteria. The evaluation of the current/voltage curves yielded a highly asymmetric electrical potential barrier. The total potential difference between the phospholipid and the lipopolysaccharide was -85 mV, a result which cannot be explained by contributions of Gouy-Chapman potentials alone. The possible contribution of dipole potentials and influences of headgroup effects are discussed. It is shown that the asymmetry of the I/U-characteristic results from the differences of the surface charge densities of the two monolayers but not from those of the states of order of their hydrocarbon chains.

Preparation of a protein-free total brain white matter lipid fraction: characterization of liposomes

A method of preparing a total lipid extract (TLE), free of protein, by extracting brain white matter with tetrahydrofuran is presented. The optimal conditions of extraction were found to be 50 ml of THF per gram of lyophilized tissue, though fresh tissue can also be used if larger volumes of solvent are employed. The method allowed, in a short time and in a single step, a yield of TLE of 50% on a dry weight basis. Its analytical characterization revealed a qualitative and quantitative composition very similar to the lipid composition of CNS myelin, including all the phospholipid and galactolipid species, cholesterol and gangliosides, but it contained only traces (0.1%) of protein. TLE has been used to prepare liposomes, either multilamellar (MLVs) or unilamellar (LUVs, SUVs), characterized by freeze-fracture electron microscopy. A multilayered, heterogeneous population of liposomes is observed in the MLVs preparation. When these samples were submitted to a freezing and thawing procedure the resulting liposomes were single-walled, and their intravesicular volume was increased. They were quite impermeable to the monovalent cation 86Rb+ and, by contrast, rather permeable to 45Ca+ +. Their complex lipid composition, together with their permeability properties and their response to ionophores, make them very useful to study protein-lipid interactions occurring within the myelin membrane as well as the functional properties of myelin proteins in reconstitution experiments.

Measurements of the extracellular potassium concentrations in the isolated rabbit retina with different kinds of potassium-sensitive microelectrodes

When the dark-adapted isolated rabbit retina has been superfused from one side with a plasma-saline mixture containing 3.5 mM potassium, the extracellular potassium concentration within the dark-adapted retina was significantly higher (4.5-6.1 mM) than the potassium of the superfusate, when measured with an electrode filled with Corning 477317. The substantial difference between the [K+]0 of the perfusate and the [K+]0 within the retina is difficult to explain and could be an instrumental artefact. To probe this possibility measurements have now been repeated using 2 different K+ electrodes, one filled with Corning 477317 and the other filled with a valinomycin-based ion exchanger. With the latter electrodes there was practically no gradient between the [K+]0 in the retina (3.2-4.0 mM) and the potassium concentration of the superfusate. It is thus evident that the earlier enigmatic values for [K+]0 relate to the use of Corning 477317-filled K+ electrodes. When, however, changes in [K+]0 were induced by a light stimulus, the measured magnitudes of change in [K+]0 were the same with the 2 types of electrode.

Calcium influx and intracellular calcium release in anti-CD3 antibody-stimulated and thapsigargin-treated human T lymphoblasts

Jurkat and MOLT-4 cultured T lymphoblasts were loaded with low concentrations (30-50 microM) of indo-1 and with high concentrations (3.5-4.5 mM) of quin-2, respectively, in order to follow the activation of calcium transport pathways after stimulation of the cells by a monoclonal antibody against the T cell antigen receptor (aCD3), or after the addition of thapsigargin, a presumed inhibitor of endoplasmic reticulum calcium pump. In the indo-1 loaded cells the dynamics of the intracellular calcium release and the calcium influx could be studied, while in the quin-2 overloaded cells the changes in cytoplasmic free calcium concentration ([Ca2+]i) were strongly buffered and the rate of calcium influx could be quantitatively determined. We found that in Jurkat lymphoblasts, in the absence of external calcium, both aCD3 and thapsigargin induced a rapid calcium release from internal stores, while upon the readdition of external calcium an increased rate of calcium influx could be observed in both cases. aCD3 and thapsigargin released calcium from the same intracellular pools. The calcium influx induced by either agent was of similar magnitude and had a nonadditive character if the two agents were applied simultaneously. As demonstrated in quin-2 overloaded cells, a significant initial rise in [Ca2+]i or a pronounced depletion of internal calcium pools was not required to obtain a rapid calcium influx. The activation of protein kinase C by phorbol ester abolished the internal calcium release and the calcium influx induced by aCD3, while having only a small effect on these phenomena when evoked by thapsigargin. Membrane depolarization by gramicidin inhibited the rapid calcium influx in both aCD3- and thapsigargin-treated cells, although it did not affect the internal calcium release produced by either agent. In MOLT-4 cells, which have no functioning antigen receptors, aCD3 was ineffective in inducing a calcium signal, while thapsigargin produced similar internal calcium release and external calcium influx to those observed in Jurkat cells.

Two mechanisms by which fluorescent oxonols indicate membrane potential in human red blood cells

Optical potentiometric indicators have been used to monitor the transmembrane electrical potential (Em) of many cells and organelles. A better understanding of the mechanisms of dye response is needed for the design of dyes with improved responses and for unambiguous interpretation of experimental results. This paper describes the responses to delta Em of 20 impermeant oxonols in human red blood cells. Most of the oxonols interacted with valinomycin, but not with gramicidin. The fluorescence of 15 oxonols decreased with hyperpolarization, consistent with an "on-off" mechanism, whereas five oxonols unexpectedly showed potential-dependent increases in fluorescence at less than 2 microM [dye]. Binding curves were determined for two dyes (WW781, negative response and RGA451, positive response) at 1 mM [K]o (membrane hyperpolarized with gramicidin) and at 90 mM [K]o (delta Em = 0 with gramicidin). Both dyes showed potential-dependent decreases in binding. Changes in the fluorescence of cell suspensions correlated with changes in [dye]bound for WW781, in accordance with the "on-off" mechanism, but not for RGA451. Large positive fluorescence changes (greater than 30%) dependent on Em were observed between 0.1 and 1.0 microM RGA451. A model is suggested in which RGA451 moves between two states of different quantum efficiencies within the membrane.

Membrane potential, anion and cation conductances in Ehrlich ascites tumor cells

The fluorescence intensity of the dye 1,1'-dipropylox-adicarbocyanine (DiOC3-(5] has been measured in suspensions of Ehrlich ascites tumor cells in an attempt to monitor their membrane potential (Vm) under different ionic conditions, after treatment with cation ionophores and after hypotonic cell swelling. Calibration is performed with gramicidin in Na+-free K-/choline-media, i.e., standard medium in which NaCl is replaced by KCl and cholineCl and where the sum of potassium and choline is kept constant at 155 mM. Calibration by the valinomycin "null point" procedure described by Laris et al. (Laris, P.C., Pershadsingh, A., Johnstone, R.M., 1976, Biochim, Biophys. Acta 436:475-488) is shown to be valid only in the presence of the Cl- -channel blocker indacrinone (MK196). Distribution of the lipophilic anion SCN- as an indirect estimation of the membrane potential is found not to be applicable for the fast changes in Vm reported in this paper. Incubation with DiOC3-(5) for 5 min is demonstrated to reduce the Cl permeability by 26 +/- 5% and the NO3- permeability by 15 +/- 2%, while no significant effect of the probe could be demonstrated on the K+ permeability. Values for Vm, corrected for the inhibitory effect of the dye on the anion conductance, are estimated at -61 +/- 1 mV in isotonic standard NaCl medium, -78 +/- 3 mV in isotonic Na+-free choline medium and -46 +/- 1 mV in isotonic NaNO3 medium. The cell membrane is depolarized by addition of the K+ channel inhibitor quinine and it is hyperpolarized when the cells are suspended in Na+-free choline medium, indicating that Vm is generated partly by potassium and partly by sodium diffusion. Ehrlich cells have previously been shown to be more permeable to nitrate than to chloride. Substituting NO3- for all cellular and extracellular Cl- leads to a depolarization of the membrane, demonstrating that Vm is also generated by the anions and that anions are above equilibrium. Taking the previously demonstrated single-file behavior of the K+ channels into consideration, the membrane conductances in Ehrlich cells are estimated at 10.4 microS/cm2 for K+, 3.0 microS/cm2 for Na+, 0.6 microS/cm2 for Cl- and 8.7 microS/cm2 for NO3-. Addition of the Ca2+-ionophore A23187 results in net loss of KCl and a hyperpolarization of the membrane, indicating that the K+ permeability exceeds the Cl- permeability also after the addition of A23187. The K+ and Cl- conductances in A23187-treated Ehrlich cells are estimated at 134 and 30 microS/cm2, respectively.(ABSTRACT TRUNCATED AT 400 WORDS)

Proton flux in large unilamellar vesicles in response to membrane potentials and pH gradients

The transport of protons across liposomes composed of phosphatidylcholine in response to electrical potentials or pH gradients has been investigated. The results support three major conclusions. The first of these concerns the need for reliable measurements of electrical potentials and pH gradients. It is shown that the potential probe tetraphenylphosphonium and the pH probe methylamine provide accurate and self consistent measures of electrical potentials and pH gradients respectively in these systems. Second, it is shown by two independent techniques that the pH gradients induced in response to valinomycin and potassium dependent electrical potentials are significantly smaller than would be expected for electrochemical equilibrium. The pH gradients observed are stable over an 8 h time course and are sensitive to the ionic composition of the buffers employed, where the presence of external sodium results in the smallest induced pH gradients. These results are discussed in terms of current models of proton conductance across membranes. In a final area of investigation, it is shown that valinomycin and carbonyl cyanide m-chlorophenyl hydrazone (CCCP) can transport sodium ions in a synergistic manner.

NMR study of the interactions of polymyxin B, gramicidin S, and valinomycin with dimyristoyllecithin bilayers

The interactions of three polypeptide antibiotics (polymyxin B, gramicidin S, and valinomycin) with artificial lecithin membranes were studied by nuclear magnetic resonance (NMR). Combination of 31P and 2H NMR allowed observation of perturbations of the bilayer membrane structure induced by each of the antibiotics in the regions of the polar headgroups and acyl side chains of the phospholipids. The comparative study of the effects of these membrane-active antibiotics and the lipid bilayer structure demonstrated distinct types of antibiotic-membrane interactions in each case. Thus, the results showed the absence of interaction of polymyxin B with the dimyristoyllecithin membranes. In contrast, gramicidin S exhibited strong interaction with the lipid above the gel to liquid-crystalline phase transition temperature: disordering of the acyl side chains was evident. Increasing the concentration of gramicidin S led to disintegration of the bilayer membrane structure. At a molar ratio of 1:16 of gramicidin S to lecithin, the results are consistent with coexistence of gel and liquid-crystalline phases of the phospholipids near the phase transition temperature. Valinomycin decreased the phase transition temperature of the lipids and increased the order parameters of the lipid side chains. Such behavior is consistent with penetration of the valinomycin molecule into the interior of the lipid bilayers.

Effect of calcium and temperature on mixed lipid-valinomycin monolayers. A comparison of glycosphingolipids (ganglioside GT1b, sulphatides) and phosphatidylcholine

The influence of calcium and temperature on pure lipid (bovine brain PC, sulphatides, ganglioside GT1b), valinomycin and mixed lipid-valinomycin monolayers at the air/water interface was studied. In mixed films, evidence was found that the two components were miscible. On the other hand, at higher surface pressures, phase separation occurs in the cases of PC and sulphatides. Measuring the area requirement and the collapse pressure the stability of both lipid and the peptide was increased in particular due to ganglioside-valinomycin interaction. The addition of 10(-5) M calcium into the subphase at 20 and 37 degrees C and surface pressures of 10 and 20 mN/m led to a condensing effect in ganglioside mixtures, with formation of aggregates as indicated also by the nearly ideal behaviour of two component monolayers.

Influence of ion gradients on the transbilayer distribution of dibucaine in large unilamellar vesicles

The uptake of dibucaine into large unilamellar vesicles in response to proton gradients (delta pH; inside acidic) or membrane potentials (delta psi; inside negative) has been investigated. Dibucaine uptake in response to delta pH proceeds rapidly in a manner consistent with permeation of the neutral (deprotonated) form of the drug, reaching a Henderson-Hasselbach equilibrium where [dibucaine]in/[dibucaine]out = [H+]in/[H+]out and where the absolute amount of drug accumulated is sensitive to the buffering capacity of the interior environment. Under appropriate conditions, high absolute interior concentrations of the drug can be achieved (approximately 120 mM) in combination with high trapping efficiencies (in excess of 90%). Dibucaine uptake in response to delta psi proceeds more than an order of magnitude more slowly and cannot be directly attributed to uptake in response to the delta pH induced by delta psi. This induced delta pH is too small (less than or equal to 1.5 pH units) to account for the transmembrane dibucaine concentration gradients achieved and does not come to electrochemical equilibrium with delta psi. Results supporting the possibility that the charged (protonated) form of dibucaine can be accumulated in response to delta psi were obtained by employing a permanently positively charged dibucaine analogue (N-methyldibucaine). Further, the results suggest that delta psi-dependent uptake may depend on formation of a precipitate of the drug in the vesicle interior. The uptake of dibucaine into vesicles in response to ion gradients is of direct utility in drug delivery and controlled release applications and is related to processes of drug sequestration by cells and organelles in vivo.

Influence of Ca2+ and temperature on the interaction of gangliosides with valinomycin in mixed monolayers at the air/water interface

The effects of Ca2+ and temperature on mixed ganglioside-valinomycin-monolayers at the air/water interface were studied. Surface pressure-area isotherms of the pure gangliosides (GM1, GD1a) exhibited the typical monolayer characteristics. Pressure-area isotherms of the cyclodepsipeptide, valinomycin, were determined. In mixed monolayers, positive and negative deviation from the mean molecular area indicated the two components were miscible. Especially in GD1a mixtures, the addition of 0.01 mM calcium exhibited, with low molar fractions of valinomycin, a demixing effect in the direction of the phase separation of the components.

[The difference between the mechanism of 67Ga accumulation and 59Fe accumulation in cultured tumor cells]

It is well known that the mechanism of 67Ga accumulation into tumor cells is mediated with transferrin receptor as well as iron. The present study was designed to explore the difference between the mechanism of gallium accumulation and that of iron by using mouse leukemic cell line L5178Y. When monensin which inhibits the recycle of transferrin receptor was added to the incubated system, accumulation of 59Fe and 67Ga was clearly diminished compared with that of control. However, inhibition of 59Fe accumulation was more remarkable than that of 67Ga. Furthermore, monensin has a action of Na+ ionophore which decreases Na+ gradient between the inside and the outside of the plasma membrane. Following administration of monensin, 67Ga accumulation was diminished according to the loss of the Na+ gradient. On the other hand, following administration of valinomycin, 67Ga accumulation was not affected by the loss of the K+ gradient. From these results, it was suggested that the mechanism of 67Ga accumulation into tumor cells differed from that of 59Fe and transferrin receptor and Na+ gradient of tumor cells played an important role on 67Ga accumulation into tumor cells.

Correlation of the turnover number of the ATP synthase in liposomes with the proton flux and the proton potential across the membrane

The fluorescent indicator pyranine was used for recording the internal pH of liposomes. The proton permeability was deduced from the velocity of the internal pH increase which was caused by shifting the external pH from 7 to 9. From valinomycin titration of the proton permeability in the presence of internal and external KCl (0.1 M), the permeability coefficient of H+ (PH) was obtained as 10(-4) cm/s at 22 degrees C. The coefficient was twice this value with the ATP synthase isolated from Wolinella succinogenes present in the liposomal membrane (10 mg protein/g phospholipid). ADP and phosphate had no effect on the latter PH. The protonophore TTFB (5 mumol/g phospholipid) increased the PH by 3 orders of magnitude. The permeability coefficients of H+ and K+ were used for calculating the delta uH and the proton flux associated with the phosphorylation which was driven by gradients of H+ and K+. For the conditions of limiting permeability of K+, the following conclusions were drawn. (1) In the steady state of rapid ion flux, the electrical potential across the liposomal membrane as calculated according to the Goldman equation, is directed opposite to the corresponding Nernst potential which is calculated from the K+ gradient. (2) The maximum turnover numbers of phosphorylation require a delta uH of 200-220 mV across the liposomal membrane. These values of delta uH and the corresponding turnover numbers are close to those brought about by the bacterial electron transport and the coupled phosphorylation. (3) The velocity of phosphorylation is linearly related to the proton flux. The slope of the line can be explained on the basis of an H+/ATP ratio of approx. 3.

Interaction of carrier ionophores with phospholipid vesicles

The interactions of carrier ionophores, nonactin, A23187, and lasalocid A with liposomes formed from the synthetic lipids dimyristoylphosphatidylcholine and dipalmitoylphosphatidylcholine are investigated by differential scanning calorimetry and 1H and 31P nuclear magnetic resonance techniques. The results indicate that the mode of interaction of these ionophores is dependent on the fluidity of the bilayer and on the chemical nature of these ionophores. The 31P NMR studies are suggestive of the formation of small particles that are probably intervesicular lipid-ionophore aggregates in multilamellar vesicles when they are incorporated with these ionophores at high concentrations. The results are interpreted on the basis of the chemical structure and conformations of the ionophores in membrane mimetic media. The 1H NMR line-width measurements indicate that the aromatic rings containing the carboxyl groups of lasalocid A and A23187 are located near the membrane interface while the rest of the molecule is buried in the membrane interior.

Valinomycin-based K+ selective microelectrodes with low electrical membrane resistance

A valinomycin-based membrane phase for microelectrodes with relatively low electrical membrane resistances is described. Microelectrodes with tip diameters of about 1 micron exhibit resistances of about 10(10) omega. Extremely high K+ selectivities are obtained, e.g. a rejection of Na+ by a factor of 5000 and of acetylcholine by a factor of 3400. At a constant background of 140 and 500 mM Na+, the detection limit of the K+ sensor is at 1.6 X 10(-5) and at 2.5 X 10(-5) M K+, respectively.

Effect of ionizing radiation on artificial (planar) lipid membranes. II. The ion carriers valinomycin and nonactin as probes for radiation induced structural changes of the membrane

Planar lipid membranes in the presence of the ion carriers valinomycin or nonactin were irradiated with 14 MeV electrons from a linear accelerator. A large increase of the membrane conductance by up to more than two orders of magnitude was found. The effect is virtually abolished either at high pH, or in the absence of oxygen, or in the presence of the radical scavenger ethanol. A further prerequisite for the effect is the presence of unsaturated fatty acid residues. A kinetic analysis of the carrier transport model based on current-voltage curves and on voltage-jump relaxation experiments was performed as a function of radiation dose. Only the translocation rate constant, kMS, of the charged carrier-ion complex was found to be influenced by irradiation. The effect is interpreted as an increase of the polarity (dielectric constant) of the membrane interior induced by the presence of polar products of lipid peroxidation. A combined action of OH- and HO2-radicals seems to be responsible for the phenomena. At large radiation doses (greater than or equal to 10(3) Gy) a reduction of the membrane conductance was observed. This is interpreted as an increased microviscosity, possibly caused by cross-linking of fatty acid residues. Ion carriers represent sensitive probes of radiation induced membrane damage.

Effects of double-layer polarization on ion transport

It has been proposed that changes in ionic strength will alter the shape of current-voltage relations for ion transport across a lipid membrane. To investigate this effect, we measured currents across glyceryl monooleate membranes at applied potentials between 10 and 300 mV using either gramicidin and 1 mM NaCl or valinomycin and 1 mM KCl. A bridge circuit with an integrator as null detector was used to separate the capacitative and ionic components of the current. The changes in the current-voltage relations when ionic strength is varied between 1 and 100 mM are compared with predictions of Gouy-Chapman theory for the effects of these variations on polarization of the electrical diffuse double-layer. Double-layer polarization accounts adequately for the changes observed using membranes made permeable by either gramicidin or valinomycin.

Nonequilibrium voltage fluctuations in biological membranes. II. Voltage and current noise generated by ion carriers, channels and electrogenic pumps

As applications of the general theoretical framework of charge transport in biological membranes and related voltage and current noise, a number of model calculations are presented for ion carriers, rigid channels, channels with conformational substates and electrogenic pumps. The results are discussed with special reference to the problem of threshold values for sensory transduction processes and their limitations by voltage fluctuations. Furthermore, starting from the special results of model calculations, an attempt is made to determine more general aspects of electric fluctuations generated by charge-transport processes in biological membranes: different frequency dependences of voltage and current noise, and dependence of noise intensities with increasing distance from the equilibrium state.

A general approach to the optimization of the conformation of ring molecules with an application to valinomycin

A general and efficient methodology is presented which allows molecules containing one or many rings of any size to be manipulated within energy minimization procedures. Variables describing the conformation of the molecules concerned are limited to dihedral and ring valence angles and the ring closure conditions are treated as equality constraints. An application is made to the ion transporter valinomycin and its complexes with K+ and Na+ which illustrates the possibilities of the approach and leads to results which allow a better understanding of the conformational mechanics of this important ionophore.

Transport of organic cations in brush border membrane vesicles from rabbit kidney cortex

The transport of three organic cations, tetraethylammonium (TEA), morphine and N1-methylnicotinamide (NMN) was studied in brush border membrane vesicles from rabbit kidney cortex under voltage clamp conditions. A proton gradient (pHi = 6.0, pHo = 7.4) produced a large stimulation of TEA and morphine uptake, yielding a transient overshoot of 190 and 220% respectively, as compared to equilibrium uptake values. No overshoot was observed under pH equilibrium conditions (pHi = pHo = 7.4, control). These data suggest the presence of a proton-organic cation exchange mechanism in the rabbit renal cortical brush border membrane. Identical experimental conditions (proton gradient) failed however to stimulate significantly NMN transport above control values measured under pH equilibrium conditions. Proton gradient driven TEA transport showed an inhibition of 21% in the presence of NMN (1 mM) and of 63% in the presence of TEA (1 mM), and TEA transport was stimulated by preloading the vesicles with 1 mM TEA (305%) but not with 1 mM NMN (128%). NMN transport showed an inhibition of 39% in the presence of 1 mM TEA and of 27% in the presence of 1 mM NMN and its transport was stimulated by preloading the vesicles with 1 mM TEA (228%) and 1 mM NMN (178%). Our data suggest that TEA, NMN and morphine are transported by a common transport mechanism for which NMN has only a low affinity.

Dependency of delta pH-relaxation across vesicular membranes on the buffering power of bulk solutions and lipids

The dependency of delta pH-relaxation kinetics across the membrane of sonicated small phospholipid vesicles on the concentration of internally entrapped buffer has been investigated by means of the pH-indicator dye pyranine. A very high contribution of lipid headgroups to the internal buffering power of the liposomes is observed, amounting to an equivalent phosphate buffer concentration of 110 mM. This localized two-dimensional proton/hydroxide ion reservoir must be considered in any determination of the H+/OH- permeability coefficient. Furthermore, it could have significance for energy-transduction across biological membranes. From the established linear relation between delta pH-relaxation rates and buffering power, net H+/OH- permeabilities of 3 X 10(-3) cm/s for soybean phospholipid (SBPL) and 1 X 10(-4) cm/s for diphytanoyl phosphatidylcholine (diphytanoyl PC) vesicles at pH 7.2 as well as buffering powers per lipid molecule of 6 X 10(-2) (pH-unit)-1 (SBPL) and 4 X 10(-2) (pH-unit)-1 (diphytanoyl PC) are calculated. In the case of diphytanoyl PC vesicles, delta pH-decay is accelerated by the presence of chloride ions.

Effects of hydrostatic pressure on lipid bilayer membranes. II. Activation and reaction volumes of carrier mediated ion transport

Measurements of voltage relaxations following brief charge-pulses applied to lipid bilayers have been performed at different hydrostatic pressures in the presence of the neutral carriers cyclo (D-Val-L-Pro-L-Val-D-Pro)3(PV) and valinomycin. From double-exponential relaxations observed in membranes containing PV-K+ complexes estimates were obtained of the amount of membrane absorbed complexes, NMS, and of the rate of complex translocation, kMS. The pressure dependence of kMS corresponded to an activation volume for translocation of approximately 12 cm3/mol independent of ionic strength and K+ concentration. The pressure dependence of NMS strongly varied with K+-concentration suggesting a major role of ion-complexation in solution which is estimated to involve a reaction volume of 25.5 cm3/mol, while the volume of absorption of a PV-K+ complex by the membrane was estimated -7.5 cm3/mol. The relaxations observed in the presence of valinomycin contained three exponentials and could be used to estimate four rate constants and one absorption parameter which characterize the valinomycin-mediated transport. When the transport of Rb+ was tested, the rate constant for the complex dissociation, kD, and the total concentration of free and complexed carriers in the membrane, No, were found to be pressure insensitive. The translocation rates for the complex, kMS and for the free carrier, kS, were instead markedly pressure dependent according to estimated activation volumes in the range of 11 to 18 cm3/mol. The recombination rate constant kR was also pressure dependent according to an activation volume of 12-14 cm3/mol. The study of the valinomycin-K+ transport yielded similar results as far as N.,ks, and kms are concerned, but in this case kR was pressure independent, while kD was increased by pressure. The net volume change associated with the transfer of a free ion to the membrane in the form of a valinomycin-ion complex was nevertheless very similar for K+ and Rb+. It is concluded that pressure affects the transmembrane mobility of liposoluble molecules, whether charged or not, mostly by increasing the effective viscosity of the hydrocarbon core of the bilayer. The pressure dependence of the membrane uptake of amphipathic compounds seems also to obey the general rule: that of involving a negative volume change. However, when the compounds arise from a complexation reaction in solution or at the membrane solution interface possible positive volumes of complexation may make effective uptake to be reversed rather than increased by pressure.

Internal potassium activity in ferret ventricular muscle

Measurements of the K activity (aiK) in ferret ventricle were made using either single- or double-barrelled K-sensitive micro-electrodes. aiK was also estimated from the Nernst equation by measuring the membrane potential when changing the external K concentration. Micro-electrodes filled with the Corning K sensor gave unreliable results most probably due to interference from some substance(s) in the heart cells. Reproduceable measurements were obtained using a valinomycin cocktail as the K sensor. The mean value +/- S.D. for aiK from four experiments which met strict criteria for calibration, electrode penetration and drift was 104 mmol/l +/- 9 mmol/l. If all nine experiments were taken the value was 101 mmol/l +/- 8 mmol/l. Estimation from the Nernst equation gave values of aiK that were on average 20 mmol/l higher than the measured values with the valinomycin cocktail. It is recommended that a valinomycin cocktail be used to measure aiK.

Determination of the molecularity of the colicin E1 channel by stopped-flow ion flux kinetics

A fluorescence technique that measures fast ion fluxes across liposome membranes was used to determine the molecularity of the colicin E1 channel. The rate of flux of Tl+ (used as a K+ analogue) into large unilamellar vesicles was measured by its ability to quench the fluorescence of a membrane-impermeable fluorophore entrapped in the vesicles. The dependence of Tl+ flux rate on the concentration of ionophore in the vesicle suspension reveals the molecularity of the ionophore. The method is demonstrated with two ionophores, valinomycin and gramicidin, whose molecularities are known to be one and two, respectively. The molecularity of the colicin E1 channel was determined to be one. This method can be used to study the properties of any ionophore that mediates K+ flux.

The effect of cholesterol on glycerophosphono- and glycerophosphinocholines. Permeability measurements in lipid vesicles

The kinetics of spontaneous chloride ion efflux and valinomycin-mediated rubidium-86 efflux from vesicles prepared from synthetic phospholipids with carbon-phosphorus linkages were investigated at temperatures above the gel-to-liquid-crystalline phase transition. The rate constants for the movement of chloride and rubidium ions were reduced by incorporation of cholesterol into bilayers of phosphono- and phosphinocholines. Nonisosteric phosphonolipids in which the oxygen was removed from the glycerol side of phosphorus without substitution by a methylene group interacted less with cholesterol than the analogous isosteric derivatives, as judged from the magnitude of the decrease in the rate constants for chloride and rubidium ion efflux. The experiments reported in this study suggest that steric factors in the glycerol side of the phosphorus function are important in phosphatidylcholine-cholesterol interaction. However, the oxygen atom on the choline side of the phosphorus in the phosphatidylcholine molecule is not required for strong phosphatidylcholine-cholesterol interaction, since isosteric glycerophosphinocholines interacted as well as the corresponding isosteric glycerophosphonocholines. Furthermore, steric requirements on the choline side of phosphorus are not important in this interaction since phosphinates whose head-group structures are -P(O-)CH2CH2N+(CH3)3 and -P(O-)CH2CH2CH2N+(CH3)3 interacted equally well with cholesterol, as estimated by these permeability studies.

High-resolution solid-state 13C NMR study of free and metal-complexed macrocyclic antibiotic ionophores valinomycin, nonactin, and tetranactin: conformational elucidation in solid and solution by conformation-dependent 13C chemical shifts

We recorded high-resolution 13C NMR spectra of the macrocyclic antibiotic ionophores valinomycin, nonactin, and tetranactin in the solid state by the cross-polarization-magic angle spinning (CP-MAS) method, in order to gain insight into the use of conformation-dependent 13C chemical shifts as a convenient means to delineate a conformational change induced by metal ion complexation. The 13C peak splittings in the solid state are consistent with the symmetry properties of the ionophores as revealed by X-ray diffraction: C2 symmetry in free tetranactin and S4 or S6 symmetry for a variety of metal complexes of nonactin and tetranactin or the K+ complex of valinomycin, respectively. Interestingly, many of the 13C NMR peaks of carbons in the skeletal backbones were significantly displaced (up to 8 ppm). The displacements of the peaks were explained by a conformational change as characterized by variations of torsion angles. Accordingly, we were able to obtain conformational features of Na+ and Cs+ complexes of valinomycin, for which X-ray diffraction data are unavailable, on the basis of the displacements of the 13C NMR peaks. Further, we discuss conformational features of these complexes in chloroform solution, with reference to those observed in the solid state.

Apparent activation volumes of hydrophobic ions and carriers in planar lipid bilayers

A gas-free high-pressure cell has been developed to measure planar bilayer conductances induced by hydrophobic ions and ionophores as a function of hydrostatic pressure. Plots of log conductance versus pressure for valinomycin and nonactin-mediated potassium transport in egg phosphatidyl cholinedecane membranes are essentially linear over a pressure range of 1 to 818 atm. Calculated activation volumes give similar results for both nonactin and valinomycin yielding values of + 48 and + 42 cc/mole, respectively. The valinomycin activation volume agrees reasonably well with the results obtained by Johnson and Miller (Biochim. Biophys. Acta 375:286-291, 1975) for K+-valinomycin transport in liposomes. In contrast to the activation volumes for nonactin and valinomycin, relaxation measurements of tetraphenyl boron (TPB) and dipicrylamine (DPA) give very small values of less than 5 cc/mole for the translocation rate constant, ki. Similarly, steady-state conductance measurements on tetraphenyl arsonium (TPA) and carbonylcyanide m-chlorophenylhydrazone (CCCP), give small values of 6 and 7 cc/mole, respectively. These low figures do not support transport theories based on the formation of bilayer holes or kinks (H. Träuble, J. Membrane Biol. 4:193-208, 1971). The low values for TPB and TPA are especially interesting because their cross-sectional areas are not much different than those of valinomycin and nonactin. Pressure-induced changes in membrane dielectric constant and thickness which lower the bilayer electrostatic barrier could explain the low values for the hydrophobic ions. Additionally, larger activation volumes might be expected for carriers such as nonactin and valinomycin that undergo significant rearrangement and change in hydration during surface complexation of cations.