Uptake of dibucaine into large unilamellar vesicles in response to a membrane potential

Local amine anesthetics appear to exert their effects in the charged (protonated) form on the cytoplasmic side of excitable membranes. Two features of interest are the mechanism whereby these drugs move across the membrane to the inner monolayer and the actual membrane concentrations achieved. In this work, we have investigated the influence of a K+ diffusion potential, delta psi, on the transmembrane distribution and concentration of the local anesthetic dibucaine employing large unilamellar vesicle systems. It is demonstrated that egg phosphatidylcholine large unilamellar vesicles exhibiting a delta psi (interior negative) actively accumulate dibucaine to achieve high interior concentrations. 31P and 13C nuclear magnetic resonance studies show that the internalized drug is localized to the vesicle inner monolayer, and suggest that the protonated form of the anesthetic is the species that is actively transported. The inner monolayer anesthetic concentrations thus achieved can be an order of magnitude or more larger than predicted on the basis of anesthetic lipid-water partition coefficients. It is suggested that these effects may be related to the mechanisms whereby local anesthetics are localized and concentrated at their sites of action in nerve membranes.     

Membrane potential and surface potential in mitochondria: Uptake and binding of lipophilic cations

Summary The uptake and binding of the lipophilic cations ethidium⁺, tetraphenylphosphonium⁺ (TPP⁺), triphenylmethylphosphonium⁺ (TPMP⁺), and tetraphenylarsonium⁺ (TPA⁺) in rat liver mitochondria and submitochondrial particles were investigated. The effects of membrane potential, surface potentials and cation concentration on the uptake and binding were elucidated. The accumulation of these cations by mitochondria is described by an uptake and binding to the matrix face of the inner membrane in addition to the binding to the cytosolic face of the inner membrane. The apparent partition coefficients between the external medium and the cytosolic surface of the inner membrane (K' _o) and the internal matrix volume and matrix face of the inner membrane (K' _i) were determined and were utilized to estimate the membrane potential from the cation accumulation factorR _c according to the relation =RT/ZF ln [(R _cV_o–K'_o)/(V_i+K'_i)] whereV _o andV _i are the volume of the external medium and the mitochondrial matrix, respectively, andR _c is the ratio of the cation content of the mitochondria and the medium. The values of estimated from this equation are in remarkably good agreement with those estimated from the distribution of⁸⁶Rb in the presence of valinomycin. The results are discussed in relation to studies in which the membrane potential in mitochondria and bacterial cells was estimated from the distribution of lipophilic cations.     

Uptake of antineoplastic agents into large unilamellar vesicles in response to a membrane potential

Many drugs exhibit lipophilic and cationic (basic) characteristics. Previous studies have shown that lipophilic cations can be accumulated into model membrane 'liposomal' (vesicular) systems in response to establishing a membrane potential (inside negative) across the vesicle membrane. We demonstrate here that the anticancer drugs, adriamycin and vinblastine, can be rapidly accumulated into egg phosphatidylcholine large unilamellar vesicles in response to a valinomycin-dependent K+ diffusion potential (delta psi) to achieve high effective interior concentrations. Further, trapping efficiencies approaching 100% can be easily achieved. The influence of lipid composition and the requirement for valinomycin have been examined for adriamycin. Equimolar cholesterol levels inhibit the uptake process at 20 degrees C. However, incubation at higher temperature results in enhanced uptake. Similarly, the presence of egg phosphatidylserine or incubation at elevated temperatures results in significant adriamycin uptake in the absence of valinomycin. It is shown that the adriamycin retention time in the vesicles is enhanced by an order of magnitude or more when actively trapped by the presence of a membrane potential in comparison to passive trapping procedures. It is suggested that such active trapping procedures may be of use for loading liposomal systems for drug delivery applications, and may provide avenues for controlled release of encapsulated material.     

Use of lipophilic cations to measure the membrane potential of oat leaf protoplasts

Uptake of the lipophilic cation triphenylmethylphosphonium into mesophyll protoplasts of oat (Avena sativa L. cv. “Garry”) approaches equilibrium at 3 to 4 hours. The resulting external and internal concentrations are then used with the Nernst equation to obtain a membrane potential of −62 millivolts, inside negative. Potentials calculated in this manner are depolarized by adding 2 mm sodium azide and 50 μm carbonyl cyanide m-chlorophenylhydrazone as well as by increasing the external proton and potassium concentrations. The depolarizations are qualitatively similar to those seen when oat mesoyphll cells are measured in situ with microelectrodes. It is concluded that due to the lack of turgor and fragility of protoplasts, estimations of their membrane potential may be made more reliably, under some conditions, with lipophilic cations than with microelectrodes.     

Determination of membrane potential with lipophilic cations: correction of probe binding

The binding of lipophilic ions to the membrane of envelope vesicles from Halobacterium halobium was examined in the absence and presence of membrane potential. The lipophilic ions used constitute a homologous series of (Phe)₃-P⁺-(CH₂)_n-CH₃ (n = 0–4) and tetraphenylphosphonium (TPP⁺). In the absence of membrane potential, the amounts of binding were proportional to the probe concentration in the medium when the concentration is dilute. Upon illumination, interior negative membrane potential is generated which induces the uptake of phosphonium cation probe. 2 μM were employed as the initial probe concentration. The real membrane potential was evaluated by means of extrapolation to the state of no binding: The values of for various probes are plotted against the binding coefficient. Here, C_i^app is the apparent intra-vesicular concentration of the probes which is calculated without consideration of bound probes. The ordinate intercept of the plot gives the true concentration ratio, and from this the membrane potential is evaluated. The membrane potential-dependent binding was analysed with a model: the membrane is split into two halves, outer and inner half, and the amounts of bound probes in each region are governed by the concentration in the contiguous solution. We obtained a formula which describes amounts of binding as a function of the membrane potential.     

A critical assessment of the use of lipophilic cations as membrane potential probes

A critical review has been made of the literature on the use of lipophilic cations, such as triphenylmethyl phosphonium (TPMP⁺) as membrane potential probes in prokaryotes, uekaryote organelles in vitro, and eukaryote cells. An ideal lipophilic cation should be capable of penetrating through a biological membrane and obey the Nernst equation between a membrane bound phase and its environment. Many different forms of the Nernst equation are presented, useful in the calculation equilibrium potentials of lipophilic cations across membranes. Lipophilic cations appear to behave as valid membrane potential probes in prokaryotes and eukaryote organelles in vitro and even in vivo although some technical difficulties may be involved. On the other hand in valid forms of the Nernst equation have often been used to calculate the equilibrium potential of lipophilic cations across the plasma membranes of eukaryotic cells. In particular, the problem of intracellular compartmentation of lipophilic cations has often not been appreciated. Lipophilic cations do not appear to behave as reliable plasma membrane potential probes in eukaryotic cells. Some other avenues are discussed which might be useful in the determination of the plasma membrane potentials of small eukaryotic cells, e.g. the use of lipophilic anions as membrane potential probes.     

Undesirable feature of safranine as a probe for mitochondrial membrane potential

This communication describes experiments showing that safranine, at the concentrations usually employed as a probe of mitochondrial membrane potential, causes significant undesirable side effects on Ca2+ transport by liver mitochondria. The major observations are: (i) safranine potentiates the spontaneous Ca2+ release from liver mitochondria induced by phosphate or acetoacetate. This is paralelled by potentiation of the release of state-4 respiration and of the rate of mitochondrial swelling, indicating a generalized effect of the dye on the mitochondrial membrane; (ii) the efflux of mitochondrial Ca2+ stimulated by hydroperoxide is irreversible in the presence of safranine even if membrane stabilizers such as Mg2+ and ATP are present. It is concluded that the use of safranine to monitor the changes in membrane potential during Ca2+ transport by mitochondria should be avoided or special care be taken.     

Binding of lipophilic cations to the liposomal membrane: thermodynamic analysis

Lipophilic ions are widely used as probes for measuring membrane potentials. Since binding of the probes to the membrane interferes with the accurate estimation of the membrane potential, it is necessary to clarify the characteristics of probe binding to membranes. The present paper deals with the binding of lipophilic cations to liposomes. The results can be summarized as follows: (1) The binding of triphenylmethylphosphonium, its homologues and tetraphenylphosphonium to liposomes of dipalmitoylphosphatidylcholine followed the Langmuir adsorption isotherm. (2) Spin-labeled lipophilic cations were synthesized and the binding to liposomes of egg phosphatidylcholine was examined. The binding also followed the Langmuir adsorption isotherm. The dissociation constant (the concentration giving half-maximal binding), K, was independent of the temperature, indicating that the binding is entropy-driven. (3) The binding was influenced by the fluidity of the membrane. Except in the case of triphenylmethylphosphonium (TPMP+), K and A (maximum amounts of binding) increased above the transition temperature. In other words, above the phase transition temperature the binding affinity is decreased, while maximum amounts of binding are increased for all phosphoniums used except TPMP+.     

Transmembrane distribution of lipophilic cations in response to an electrochemical potential in reconstituted cytochromec oxidase vesicles and in vesicles exhibiting a potassium ion diffusion potential

It has been shown previously that biogenic amines and a number of pharmaceutical agents can redistribute across vesicle membranes in response to imposed potassium ion or proton gradients. Surprisingly, drug accumulation is observed for vesicles exhibiting either a pH gradient (interior acidic) or a membrane potential (interior negative), implying that these compounds can traverse the lipid bilayer as either the neutral or charged species. This interpretation, however, is complicated by the fact that vesicles exhibiting a membrane potential (interior negative) accumulate protons in response to this potential, thereby creating a pH gradient (interior acidic). This raises the possibility that in both vesicle systems drug redistribution occurs in response to the proton gradient present. We have therefore compared the uptake of several lipophilic cations by reconstituted cytochromec oxidase vesicles and by similar vesicles exhibiting a potassium ion diffusion potential. While turnover of the oxidase generates a membrane potential of comparable magnitude to the potassium ion diffusion system, it is associated with a proton gradient of opposite polarity (interior basic). Both systems show rapid uptake of the permanently charged lipophilic cation, tetraphenylphosphonium, but only the potassium ion diffusion system accumulates the lipophilic amines doxorubicin and propranolol. This provides compelling evidence that such weak bases redistribute only in response to pH gradients and not membrane potential.     

Determination of membrane potential with lipophilic cations. Comparison of estimated values with various phosphonium ions

The binding of lipophilic ions to the membrane of envelope vesicles from Halobacterium halobium was examined. The lipophilic ions used constitute a homologous series of (Phe)₃-P⁺-(CH₂)_n-CH₃ (n = 0–5) and tetraphenylphosphonium (TPP⁺). In the absence of membrane potential, the binding of probes to the membrane was measured. For the probes of n = 0 and n = 1, and for TPP⁺, binding followed the Langmuir adsorption isotherm. For other probes, analysis revealed the presence of two, high- and low-affinity, binding sites. Upon illumination, which generated the membrane potential, the probe molecules were accumulated into the vesicles. If we ignore the membrane-potential-dependent binding of the probe molecules, the estimated values are larger when the probe used is more hydrophobic. We have tested some models describing the amount of probe bound on membranes in terms of concentration of free probe inside and outside the vesicles. No model has fulfilled the criterion of valid estimation that the membrane potentials estimated are independent of probes used. An experimental method for the estimation of true membrane potential is proposed. Effects of tetraphenylboron on the estimation of membrane potential and on the transport rate of phosphonium cations were examined.     

Measurement of membrane potential inBacillus subtilis: A comparison of lipophilic cations,rubidium ion,and a cyanine dye as probes

Summary Two of the commonly used probes for measuring membrane potential—lipophilic cations and the cyanine dye diS-C₃(5)—indicated nominally opposite results when tetraphenylarsonium ion was added as a drug to suspensions of metabolizingBacillus subtilis cells. [³H]-Triphenylmethylphosphonium uptake was enhanced by the addition, indicating hyperpolarization, yet fluorescence of diS-C₃(5) was also enhanced, indicating depolarization. Evidence is presented that both effects are artifactual, and can occur without any change in membrane potential, as estimated by⁸⁶Rb⁺ uptake in the presence of valinomycin. The fluorescence studies suggest that tetraphenylarsonium ion displaces the cyanine dye from the cell envelope, or other binding site, into the aqueous phase.The uptake characteristics of the radiolabeled lipophilic cations were quite unusual: At low concentrations (e.g., less than 10 m for triphenylmethylphosphonium) there was potential-dependent uptake of the label to a stable level, but subsequent addition of nonradioactive lipophilic cation caused further uptake of label to a new stable level. Labeled triphenylmethylphosphonium ion taken up to the first stable level could be displaced by 10mm magnesium ion, whereas⁸⁶Rb⁺ uptake was unperturbed. Association of the lipophilic cations with the surface of de-energized cells was concentration-dependent, but there was no evidence for cooperative binding. This phenomenon of stimulated uptake inB. subtilis (which was not seen inEscherichia coli cells or vesicles) is consistent with a two-compartment model with access to the second compartment only being possible above a critical cation concentration. We tentatively propose such a model, in which these compartments are the cell surface and the cytoplasm, respectively.Triphenylmethylphosphonium up to 0.5mm exhibited linear binding to de-energized cells; binding of tetraphenylphosphonium and tetraphenylarsonium was nonlinear but was not saturated at the highest concentration tested (1mm). The usual assumption, that association of the cation with cell surfaces is saturated and so can be estimated on de-energized cells, therefore leads to undercorrected estimates of cytoplasmic uptake inB. subtilis, and hence to overestimates of membrane potential. We describe a more realistic procedure, in which the estimate of extent of binding is based on a mean aqueous concentration related both to the external concentration and to the much higher internal concentration that exists in energized cells. Using this procedure we estimate the membrane potential inB. subtilis to be 120 mV, inside-negative. The procedure is of general applicability, and should yield more accurate estimates of membrane potential in any system where there is significant potential-dependent binding.Work performed while on sabbatical leave from Department of Biology, Ben-Gurion University of the Negev, Beer-Sheva, Israel.     

Cyanine and safranine dyes as membrane potential probes in cytochrome c oxidase reconstituted proteoliposomes

Safranine and the cyanine dye, 3',3'-dipropylthiadicarbocyanine (diSC3-5), were examined as membrane potential probes in cytochrome c oxidase vesicles. The spectra of the vesicle-associated dyes resemble those of the same dyes in organic solvents, indicating that safranine and diSC3-5 probably dissolve in a hydrophobic region of the proteoliposomal membrane. This binding of safranine to proteoliposomes occurs with a dye-membrane dissociation constant in the micromolar range. The binding of safranine and of diSC3-5 to liposomes or proteoliposomes is accompanied by fluorescence enhancement. This enhanced fluorescence is quenched by respiration or by the establishment of a K+ diffusion potential by valinomycin (negative interior). An optimal dye/lipid ratio was required to secure maximum fluorescence quenching of the dyes, whether that quenching was active or passive. Calibrations of both the safranine and the diSC3-5 responses with K+ diffusion potentials were also affected by the dye/lipid ratio. At lower dye/lipid ratios, the calibration curve was linear at higher potentials but deviated from linearity at lower potentials. The converse was true at higher dye/lipid ratios. The non-linearity of the calibration curve at higher potential was attributed to a 'saturation' effect; it may also involve increased permeability of proteoliposomal membrane to protons. Destacking of dye at the lower dye/lipid ratio was probably responsible for the non-linearity of the calibration curves at lower potentials. When all these effects are taken into account, the steady-state value of delta psi generated during maximal proteoliposomal respiration was calculated to be between 140 and 160 mV (interior negative) when measured with either safranine or diSC3-5. We conclude that quantitative estimates of delta psi values can be made using these probes in cytochrome c oxidase reconstituted proteoliposomes provided that appropriate precautions are taken.     

Effects of lipophilic cations on motility and other physiological properties of Bacillus subtilis.

Lipophilic cations (tetraphenylarsonium, tetraphenylphosphonium, and triphenylmethylphosphonium) caused a number of major changes in the physiology of Bacillus subtilis. Macromolecular synthesis was inhibited, adenosine 5'-triphosphate concentration increased, swimming speed was reduced, tumbling was suppressed, and the capacity to take up the cations was greatly enhanced; respiration was not significantly altered. The effects occurred at lipophilic cation concentrations in the range commonly employed for measurement of membrane potential. Neither the enhancement of cation uptake nor the motility inhibition was a consequence of alteration of membrane potential, since both effects were still seen in the presence of valinomycin, with the extent of 86Rb+ uptake indicating a constant potential. Because suppression of tumbling accompanied speed reduction, as has also been found when protonmotive force is reduced, it is likely that lipophilic cations are perturbing the process of conversion of proton energy into work, rather than simply causing structural damage.     

Uptake of adriamycin into large unilamellar vesicles in response to a pH gradient

Previous work has shown that adriamycin can be accumulated into large unilamellar vesicle (LUV) systems in response to K⁺ diffusion potential established by valinomycin. It is demonstrated here that adriamycin can also be rapidly and efficiently accumulated into egg phosphatidylcholine (egg PC) and egg PC-cholesterol (1:1) LUVs in response to a transmembrane pH gradient (interior acidic) in the absence of ionophores. This ‘active’ loading gives rise to trapping efficiencies as high as 98%, interior drug concentrations as high as 100 mM and significantly enhances drug retention within the vesicles. This procedure may be of general utility for loading liposomal systems for in vivo drug delivery.     

Liposomes as a model for olfactory cells: changes in membrane potential in response to various odorants

Various odorants were found to depolarize azolectin liposomes. The results obtained are as follows. (1) Changes in the membrane potential of azolectin liposomes in response to various odorants were monitored by measuring changes in the fluorescence intensity of 3,3'-dipropylthiocarbocyanine iodide [disS-C3(5)]. Ten odorants examined increased the fluorescence intensity of the liposome-dye suspensions in a dose-dependent manner, which indicates that odorants depolarize the liposomes. Concentrations of odorants that depolarized the liposomes greatly varied among the odorants. There existed a good correlation between the minimum concentrations of odorants to depolarize the liposomes and the thresholds of respective odorants in the frog or porcine olfactory responses. (2) Addition of sphingomyelin (SM) to azolectin led to a large enhancement of depolarizations by nonanol, citral, and n-amyl acetate. The results indicate that lipid composition of liposomes is one of the factors that control the sensitivity to odorants. (3) Odorants changed the membrane fluidity of the liposomes, which was monitored by changes in the fluorescence polarization of 1,6-diphenyl-1,3,5-hexatriene (DPH). The membrane fluidity was changed in concentration ranges of odorants similar to those where the membrane potential changes occurred, which suggests that changes in the membrane fluidity are related to generation of the membrane potential changes. (4) Changes in the membrane potential in response to odorants were electrically measured with the planar lipid bilayer made of an azolectin-SM (2:1 w/w) mixture. It was shown that odorants (nonanol, citral, and n-amyl acetate) depolarized the planar lipid bilayer.(ABSTRACT TRUNCATED AT 250 WORDS)     

Albumin enhances the diffusion of lipophilic drugs into the membrane bilayer

In earlier work, we reported on the manner with which lipophilic drug molecules interact with the cell membrane in order to (a) enter the bilayer and laterally diffuse to their respective protein sites of action, or (b) penetrate this biological barrier to reach the cell interior. A remaining uncertainty is how lipophilic molecules reach the hydrophobic membrane core after traversing the aqueous medium and membrane polar surface. Here we present preliminary data using deuterium NMR, demonstrating the role of bovine serum albumin in facilitating this process. Our observation allows us to postulate a mechanism by which the passive transport of lipophilic ligands across the membrane can be greatly enhanced through the assistance of carrier proteins.     

Self-sustained oscillations of electric potential in a model membrane

A model membrane constructed from a Millipore filter, whose pores are filled with dioleyl phosphate molecules, exhibits a self-oscillation of the electric potential with a period of about a few seconds in the presence of a salt-concentration difference, pressure difference and/or electric current across the filter. In this paper, the effects of chemicals such as KCl, CaCl2, pH and sucrose on the self-oscillation are investigated experimentally. These chemical substances are shown to alter the characteristic properties as the frequency of oscillation. Theoretical consideration of electrochemical interaction between these substances and DOPH molecules gives a fairly good explanation of the observed results.     

Properties of mitochondria from Penicillium cyclopium and their response to calcium and other divalent cations

The respiratory properties of isolated mitochondria from P. cyclopium were studied with particular attention to their response to calcium ions. The results obtained indicate concentration dependent stimulation of NADH oxidation by calcium ions. Similar effects could also be obtained with other divalent cations.