The effect of potassium on the cell membrane potential and the passage of synchronized cells through the cell cycle

The cell membrane potential of cultured Chinese hamster cells is known to increase at the start of the S phase. The putative role of the cell membrane potential as a regulator of cell proliferation was examined by following the cell cycle traverse of synchronized Chinese hamster cells in the presence or absense of high exogenous levels of potassium. An increase in external potassium levels results in a depressed membrane potential and a reduced rate of cell proliferation. A potassium concentration of 115 mM was used in experiments with synchronized cells since at that level cell proliferation is almost completely halted, recovery of growth is rapid and complete, and the membrane potential is reduced to a level well below that normally found in cells in the G₁ phase. A mitotic population was divided into four aliquots and plated in either control medium or medium containing 115 mM K⁺. Cells placed directly into high K⁺ medium were retarded in their exit from mitosis and displayed a delayed and abnormal entry into the S phase. If control medium was added after two hours, cell cycle traverse was normal, but delayed by two hours compared to control cells. If the mitotic cells were plated directly into control medium and two hours later were shifted to high K⁺ medium, the cells entered the S phase in the absence of the normally observed increase in membrane potential and proceeded to the next mitosis normally. It was concluded that the increase in membrane potential observed at the start of the S phase in isolated synchronized cells is not a requirement for the initiation of DNA synthesis. In addition, sensitivity to the high potassium regimen was found at two different times during the cell cycle. In one case, cells were impeded in their transit through mitosis. Such cells displayed an altered chromosome structure which may account for the partial mitotic block. In the second case, synchronized cells displayed a sensitivity to the high potassium regimen in early G₁ which appeared to be separate from the block in mitosis and independent of a change in the membrane potential.     

A rapid method for measuring intracellular pH using BCECF-AM

A rapid intracellular pH (pH(i)) measurement method based on initial rate of increase of fluorescence ratio of 2',7'-bis(2-carboxyethyl)-5,6-carboxyfluorescein upon dye addition to a cell suspension in growth medium is reported. A dye transport model that describes dye concentration and fluorescence values in intracellular and extracellular spaces provides the mathematical basis for the approach. Experimental results of ammonium chloride challenge response of the two suspension cells, Spodoptera frugiperda and Chinese hamster ovary (CHO) cells, successfully compared with results obtained using traditional perfusion method. Since the cell suspension does not require any preparation, measurement of pH(i) can be completed in about 1 min minimizing any potential errors due to dye leakage.     

Wide applicability of a flow cytometric assay to measure absolute membrane potentials on the millivolt scale

To prove the general applicability of a recently published flow cytometric method to determine the membrane potentials of cells on the absolute (mV) scale, the validity of the premises involved were analyzed individually. Experimental evidence was given for bis-oxonol, the applied membrane potential indicator being a Nernstian dye. The results of special measurements proved that extracellular dye concentrations were not affected by cellular dye uptake under the applied experimental conditions and that the dye content of the suspending medium did not contribute directly to the measured cellular fluorescence. A direct, membrane-potential-independent contribution of the extracellular dye to cellular fluorescence was also found to be negligible, as membrane potential values of the same type of cells evaluated from measurements in the presence of different extracellular oxonol concentrations were very close to each other. The transmembrane potential of B lymphoid JY cells was measured by the method as a function of cell density in the tissue culture. Cells isolated during the log phase of growth displayed a –40±4 mV membrane potential. At a high density of the culture (plateau phase), a significant increase of the membrane potential to –61±3 mV was observed and a medium value of –47±3.5 mV was measured at an intermediate density of the cells. Our observation indicates that nonadherent cells can also be hyperpolarized when optimal growth conditions are terminated. Received: 14 April 1998 / Revised version: 22 June 1998 / Accepted: 16 July 1998     

Interaction of chemotactic factors with human polymorphonuclear leukocytes: Studies using a membrane potential-sensitive cyanine dye

Summary Changes in the fluorescence intensity of the dye 3-3 dipentyloxacarbocyanine were measured in suspensions of purified human peripheral blood polymorphonuclear leukocytes (PMNs) during exposure to the chemotactic factors N-formyl-methionylleucyl-phenylalanine (f-met-leu-phe) and partially purified C5a. Incubation of PMNs with dye resulted in a stable fluorescence reflecting the resting membrane potential of the cell. Exposure of PMNs to dye did not affect stimulated chemotaxis or secretion. The mechanism of cell-associated dye fluorescence involved solvent effects from partitioning of the dye between the aqueous incubation medium and the cell and not dye aggregation, Chemotactically active concentrations of f-met-leu-phe (5×10^–9 m or greater) produced a biphasic response characterized as a decrease followed by an increase in fluorescence. No fluorescence response was seen in lysed PMNs, and no response was elicited by an inhibitor of f-met-leu-phe binding (carbobenzoxy-phenylalanyl-methionine). The ability of several other synthetic peptides to elicit a fluorescence response corresponded to their effectiveness as chemotactic agents. Although the first component of the response suggested a depolarization, it was not influenced by variation in the external concentration of sodium, potassium, chloride, or calcium, and could not be characterized as a membrane potential change. The second component of the response, which was inhibited by both Mg²⁺ (10mm)-EGTA (10mm) and high external potassium, was compatible with a membrane hyperpolarization. The data indicate that chemotactic factors produce changes in dye fluorescence which can, at least in part, be attributed to a hyperpolarizing membrane potential change occurring across the plasma membrane.Presented in part at the 17th Annual Cell Biology Meeting.Cell Biol. 75:103a, 1977.     

Voltage-sensitive cyanine dye fluorescence signals in lymphocytes: plasma membrane and mitochondrial components

The origin of the cyanine dye fluorescence signal in murine and human peripheral blood leukocytes was investigated using the oxa- and indo-carbocyanines di-O-C5(3) and di-I-C5(3). Fluorescence signals from individual cells suspended with nanomolar concentrations of the dyes were measured in a flow cytometer modified to permit simultaneous four-parameter analysis (including two-color fluorescence or fluorescence polarization measurements). The contributions of mitochondrial membrane potential (psi m) and plasma membrane potential (psi pm) to the total voltage-sensitive fluorescence signal were found to depend on the equilibrium extracellular dye concentration, manipulated in these experiments by varying the ratio of dye to cell density. Hence, conditions could be chosen that amplified either the psi m or the psi pm component. Selective depolarization of lymphocytes or polymorphonuclear leukocytes (PMN) in mixed cell suspensions demonstrated that defining the partition of dye between cells and medium is requisite to assessing the heterogeneity of cell responses by cyanine dye fluorescence. At extracellular dye concentrations exceeding 5 nM in equilibrated cell suspensions, both mitochondrial and plasma membrane dye toxicity were observed. In murine splenic lymphocytes, plasma membrane toxicity (dye-induced depolarization) was selective for the B lymphocytes. Certain problems in calibration of psi pm with valinomycin at low dye concentrations and perturbations of psi pm by mitochondrial inhibitors are presented. These findings address the current controversy concerning psi m and psi pm measurement in intact cells by cyanine dye fluorescence. The finding of selective toxicity at low cyanine dye concentrations suggest that purported differences in resting psi m among cells or changes in psi pm with cell activation may reflect variable susceptibility to dye toxicity rather than intrinsic cell properties.     

Monitoring of real changes of plasma membrane potential by diS-C3(3) fluorescence in yeast cell suspensions

The fluorescent dye 3,3'-dipropylthiadicarbocyanine, diS-C(3)(3), is a suitable probe to monitor real changes of plasma membrane potential in yeast cells which are too small for direct membrane potential measurements with microelectrodes. A method presented in this paper makes it possible to convert changes of equilibrium diS-C(3)(3) fluorescence spectra, measured in yeast cell suspensions under certain defined conditions, into underlying membrane potential differences, scaled in the units of millivolts. Spectral analysis of synchronously scanned diS-C(3)(3) fluorescence allows to assess the amount of dye accumulated in cells without otherwise necessary sample taking and following separation of cells from the medium. Moreover, membrane potential changes can be quantified without demanding calibration protocols. The applicability of this approach was demonstrated on the depolarization of Rhodotorula glutinis yeast cells upon acidification of cell suspensions and/or by increasing extracellular K(+) concentration.     

Potassium movement during sodium-induced motility initiation in the rat caudal epididymal spermatozoa

The sodium-induced sperm motility initiation of the rat cauda epididymal sperm has been studied in different potassium concentrations. High K+ inhibited motility initiation. At a K+ concentration of 50 mM (concentration found in the rat cauda epididymidis), sperm motility was inhibited by 80%. K+ movement across the sperm membrane has been followed by using 86Rb+ as a marker for K+. When the 86Rb+ preloaded sperm were suspended in a sodium-free medium, there was a little efflux of 86Rb+. However, if they were suspended in a sodium-containing medium, the efflux rate was greatly increased. This increase in 86Rb+ efflux rate was associated with an initiation of sperm motility. Both 86Rb+ efflux and motility initiation were triggered by a K+ ionophore 18-crown-6 (2 X 10(-3)M). However, the ionophore-induced 86Rb+ efflux and motility initiation only occurred in the presence of extracellular Na+. Tetraethylammonium (TEA) chloride, which blocks K+ channels, inhibited motility initiation in a dose-dependent manner. Changes in the membrane potential of sperm have been followed using the fluorescent dye diO-C6-(3) whose fluorescence in sperm suspension changes markedly with changes in sperm membrane potential. During motility initiation, there was a fall in fluorescence of the dye due to increased partition into sperm cells. This observation may indicate a hyperpolarization of the sperm membrane during motility initiation. It was concluded that sperm motility initiation is associated with a complex ionic event. Na+ enters sperm cells in exchange with H+ and K+. This change in the permeability of the sperm membrane to ions is reflected by a change in the sperm membrane potential.     

Transmembrane potential of isolated rat alveolar type II cells

Type II cells were isolated from rat lungs by elastase digestion and purified by centrifugal elutriation. The fluorescent dye, Di-S-C3(5), was used as a probe to monitor transmembrane potential (Em) of cells suspended in N-2-hydroxyethylpiperazine-N'-2-ethanesulfonic acid (HEPES)-buffered medium. With this technique, the Em of type II cells was estimated to be -27 +/- 2 mV. This resting Em is very close to the equilibrium potential for chloride (-21 mV), which suggests that chloride is passively distributed in type II cells. The resting Em of type II cells is more dependent on the extracellular concentration of potassium (K+) than on external sodium (Na+); i.e., the membrane depolarizes as external sodium is replaced by potassium, suggesting that in unstimulated type II cells the membrane is more permeable to potassium than to sodium. In addition, the resting potential appears to be due, in part, to the activity of a ouabain-sensitive, Na-K pump, which acts to hyperpolarize type II cells. Addition of a membrane perturbant, phorbol myristate acetate (PMA, 10 micrograms/ml), to a type II cell suspension results in an increase in oxygen consumption and membrane depolarization. Both of these responses are sodium dependent and thus appear to be linked to a PMA-induced increase in sodium permeability.     

The effects of ionophores on the fluorescence of the cation 3,3''-dipropyloxadicarbocyanine in the presence of pigeon erythrocytes, erythrocyte ''ghosts'' or liposomes.

1. Pigeon erythrocytes, resealed lysed erythrocytes or liposomes derived from erythrocyte lipids were suspended in solutions containing up to 2 micrometer-3,3'-dipropyloxadicarbocyanine iodide. Gramicidin, valinomycin, nigericin or carbonyl cyanide p-trifluoromethoxy-phenylhydrazone, or combinations of these, were used to induce electrical diffusion potentials dependent on Na+, K+ or protons. In each instance hyperpolarization of the cell membrane lowered the fluorescence of the cell suspension, a process that was completed in about 1 min. Subsequent depolarization caused an increase in fluorescence. 2. Quenching of the fluorescence of the cell suspension appeared to be due to the reversible binding of the dye to the cells. Much larger amounts of dye were bound, both to the intact and to the resealed erythrocytes, than would be expected if partitioning of the dye cation followed the Nernst equation. The dependence of the binding on the extracellular dye concentration was studied in the presence and absence of valinomycin. The results were consistent with the suggestion of Sims, Waggoner, Wang & Hoffman [(1974) Biochemistry 13, 3315-3330] that the dye was bound at both membrane surfaces and that, at low dye concentrations, hyperpolarizing the cells promoted dye binding at the inner membrane surface. 3. The applications of the technique are limited by the circumstance that the direct effect of the electric field on the uptake of the dye into the cells is amplified by a binding process that may be affected by other physiological variables.     

Cyanine dye as monitor of membrane potentials in Escherichia coli cells and membrane vesicles.

The fluorescence response of a positively charged cyanine dye: 3,3'-dimethylindodicarbocyanine iodide can be specifically related to the generation in Escherichia coli cells and E. coli membrane vesicles of an electrical membrane potential induced either by substrate oxidation or by an artificially imposed potassium diffusion gradient. The energy-dependent quenching of the dye fluorescence correlates well with the known effect on delta phi of: oxidation of various energy sources, external pH and solute accumulation. Thus, in the vesicles, the fluorescence quenching of the dye increases from succinate to D-lactate, to ascorbate/phenazine methosulfate and parallels the increasing ability of these electron donors to generate a delta phi. In the vesicles, delta phi is only weakly dependent on external pH, whereas in the cells, delta phi increases with increasing external pH. Lactose accumulation in the vesicles results in the partial utilization of delta phi. A calibration of the dye fluorescence in terms of delta phi has been determined using valinomycin-induced potassium diffusion potential.     

Membrane Potential Changes Visualized in Complete Growth Media through Confocal Laser Scanning Microscopy of bis-Oxonol-Loaded Cells

Confocal laser scanning microscopy (CLSM) was employed to visualize and measure membrane potential changes in several types of cultured adherent cells, such as human fibroblasts, mouse mammary tumor C127 cells, and human saphenous vein endothelial cells, preloaded with the anionic dye bis-1,3,-diethylthiobarbituratetrimethineoxonol (bis-oxonol). The fluorescence of cell-associated bis-oxonol was detected in a single confocal plane. An original flow-chamber apparatus was employed to replace the extracellular medium, avoiding alterations of the plane selected for observation. In all the cell types and the experimental situations tested the intracellular distribution of the dye was typical; perinuclear zones accumulated the dye which, conversely, was excluded by the nucleus. Fluorescence was calibrated versus the membrane potential by varying the extracellular concentration of sodium in the presence of gramicidin. With this approach membrane potential was measured (i) in cultured human fibroblasts incubated under anisotonic conditions, (ii) in heterogeneous cell populations which respond unevenly to potential perturbing conditions, and (iii) in human macrovascular endothelial cells maintained in high-serum, complete growth medium. The results obtained indicate that CLSM can be successfully employed to measure changes of membrane potential in single, bis-oxonol-loaded adherent cells under experimental conditions which severely hinder conventional spectrofluorimetric approaches.     

Comparative measurements of membrane potentials with microelectrodes and voltage-sensitive dyes

The usefulness of a new voltage-sensitive fluorescent dye, the membrane permeant negatively charged oxonol dye diBA-C4-(3)-, was evaluated by measuring the membrane potentials of BICR/M1R-k and L cells with glass microelectrodes and simultaneously recording the fluorescence of the stained cells. The membrane potential of BICR/M1R-k cells was varied between -25 mV and -90 mV by changing the bicarbonate concentration in the medium or by voltage clamping. To avoid any interference by the inserted electrodes with the fluorescence measurement of the cytoplasm, the cells were fused by polyethyleneglycol to form giant cells (homokaryons). These homokaryons also allowed penetration by two glass microelectrodes without causing a serious leakage of the plasma membrane. The slow responding dye diBA-C4-(3)- had a fluorescence response of about 1% per mV. Mathematical analysis of the fluorescence changes after voltage clamping revealed a first-order reaction with a rate constant between 0.1 min-1 and 0.8 min-1, depending on the cell size which was determined by the number of nuclei per homokaryon. A model for the mechanism of the fluorescence changes is proposed.     

Oxonol VI as an optical indicator for membrane potentials in lipid vesicles

Experiments with large unilamellar dioleoylphosphatidylcholine vesicles were carried out in order to study the effect of membrane potential on the fluorescence of Oxonol VI. A partition equilibrium of dye between membrane and water was found to exist with a partition coefficient gamma identical to c lipid/c water of about 19,000 (at zero voltage). In the presence of an inside-positive membrane potential, the negatively charged dye accumulates in the intravesicular aqueous space according to a Nernst equilibrium. This leads to an increased adsorption of dye to the inner lipid monolayer and to a concomitant increase of fluorescence. The fluorescence change can be calibrated as a function of transmembrane voltage by generating a potassium diffusion potential in the presence of valinomycin. The intrinsic fluorescence of the membrane-bound dye is not affected by voltage; the whole influence of voltage on the fluorescence results from voltage-dependent partitioning of the dye between water and membrane. The voltage dependence of the apparent partition coefficient can be quantitatively described by a three-capacitor model in which the dye is assumed to bind to adsorption planes located on the hydrocarbon side of the membrane/solution interface. Oxonol VI was found to be suitable for detecting changes of membrane potential associated with the activity of the (Na+ + K+)-ATPase in reconstituted vesicles. When ATP is added to the external medium, pump molecules with the ATP-binding side facing outward become activated; this results in a translocation of net positive charge towards the vesicle interior. Under this condition, fluorescence changes corresponding to (inside-positive) potentials of up to 150-200 mV are observed. After the build-up of the membrane potential, a quasi-stationary state is reached in which the pump current is compensated by a back-flow of charge through passive conductance pathways.     

Confocal microscopical analysis of epithelial cell heterogeneity in mouse Peyer's patches

Summary Cyanine dye fluorescence and alkaline phosphatase activities have been compared directly by confocal microscopy in a wide variety of cells present in the follice-associated epithelium of the mouse Peyer's patch to test the hypothesis that antigen-transporting M cells have a low membrane potential. In order to make these comparisons it was first necessary to equilibrate living tissue with the membrane potential sensitive dye DIOC₅(3), fix with glutaraldehyde and then incubate the fixed tissue with naphthol AS-BI phosphate, a substrate which is hydrolysed by alkaline phosphatase present in the luminal membrane of these epithelial cells. Naphthol AS-BI produced by this reaction, is then coupled to Fast Red TR diazonium salt at the site of hydrolysis. Selecting the 488 nm wavelength of the argon laser source then allows one to measure alkaline phosphatase activities as Fast Red absorbance and membrane potentials by DIOC₅(3) fluorescence.Results obtained show a linear correlation between membrane potential and alkaline phosphatase activity. Relative lack of alkaline phosphatase activity, determined in fixed tissue, has been used previously to identify antigen-transporting M cells (Smithet al., 1987). The present work shows that it is now possible to recognize these cells in living tissue by measurement of DIOC₅(3) fluorescence. The possible importance of this finding in providing a way to study cell surface-antigen interactions taking place in living tissue is discussed.     

Cell suspensions from porcine olfactory mucosa. Changes in membrane potential and membrane fluidity in response to various odorants

A suspension of olfactory epithelial cells was prepared from porcine olfactory mucosa and the physiological functions of the suspension were examined. The membrane potential of the cell suspension, which was monitored by measuring the fluorescence changes of rhodamine 6G, was depolarized by an increase in the K+ concentration in the external medium. Various odorants depolarized the cell suspension in a dose-dependent fashion. The magnitude of depolarization by odorants was either unchanged or slightly increased by a reduction of the concentration of Na+, Ca2+, and Cl- in the external medium, which suggests that changes in the permeabilities of specific ions are not involved in depolarization by odorants. The application of various odorants to the cell suspension induced changes in the membrane fluidity at different sites of the membrane that were monitored with various fluorescent dyes [8-anilino-1-naphthalene sulfonate, n-(9-anthroyloxy) stearic acids, 12-(9-anthroyloxy) oleic acid, and (1,6-diphenyl-1,3,5-hexatriene)], which suggests that the odorants having different odors are adsorbed on different sites in the membrane. On the basis of these results, a possible mechanism of odor discrimination is discussed.     

Depolarization of synaptosomal membranes: a study of mechanism by which rhodamine 6G measures membrane potential

The fluorescence intensity of Rhodamine 6G in synaptosomal suspensions has been measured to monitor the membrane potential changes in pre-synaptic nerve terminals. The fluorescence response of the dye was seen to be a function of potential-dependent partitioning of dye molecules between the synaptosomes and the extracellular medium. Binding of dye molecules to the hydrophobic regions of membranes results in the quenching of fluorescence. Upon depolarization of the synaptosomal membrane, the dye molecules are released from the cells. The effect of changing extracellular ionic composition was also studied. The membrane potential increased linearly with log of [K]0. The resting membrane potential in buffer containing 5 mM K+ was calculated to be -60 mV. Raising the extracellular Ca2+ and Mg2+ from 1.2 mM to 10 mM did not change the membrane potential. Ca2+ ionophore A23187, in the presence of Ca2+ was found to depolarize the membranes.     

Effect of killer toxin K1 on yeast membrane potential reported by the diS-C3(3) probe reflects strain-and physiological state-dependent variations

The rate and extent of uptake of the fluorescent probe diS-C₃(3) reporting on membrane potential inS. cerevisiae is affected by the strain under study, cell-growth phase, starvation and by the concentration of glucose both in the growth medium and in the monitored cell suspension under non-growth conditions. Killer toxin K1 brings about changes in membrane potential. In all types of cells tested,viz. in glucose-supplied stationary or exponential cells of the killer-sensitive strain S6/1 or a conventional strain RXII, or in glucose-free exponential cells of both strains, both active and heat-inactivated toxin slow down the potential-dependent uptake of diS-C₃(3) into the cells. This may reflect “clogging” of pores in the cell wall that hinders, but does not prevent, probe passage to the plasma membrane and its equilibration. The clogging effect of heat-inactivated toxin is stronger than that exerted by active toxin. In susceptible cells,i.e. in exponential-phase glucose-supplied cells of the sensitive strain S6/1, this phase of probe uptake retardation is followed by an irreversible red shift in probe fluorescence maximumλ _max indicating damage to membrane integrity and cell permeabilization. A similar fast red shift inλ _max signifying lethal cell damage was found in heat-killed or nystatin-treated cells.     

F20C,a new fluorescent membrane probe,moves more slowly in malignant and mitogen-transformed cell membranes than in normal cell membranes

New fluorescent probes of membrane mobility can be introduced into cell membranes at single points with particles of a membrane mobility agent, A₂C. The initial entry of fluorescence from the particle into the cell membrane and the subsequent lateral spread of fluorescence have been observed for cells in suspension. A dramatic difference between the behavior of normal lymphocytes and that of mitogen-transformed and mastocytoma cells is found. Both the initial entry and the spreading of fluorescence are much slower in the transformed and tumor cells than in the normal cells at 18°C. Entry and spread of fluorescence in normal cells become slow enough to be observed only at 12°C or below.     

Comparative study of membrane potential-sensitive fluorescent probes and their use in ion channel screening assays

In this study, the authors compared and evaluated 4 membrane potential probes in the same cellular assay: the oxonol dye DiBAC(4)(3), the FLIPR membrane potential (FMP) dye (Molecular Devices), and 2 novel fluorescence resonance energy transfer (FRET) dye systems from PanVera [CC2-DMPE/DiSBAC(2)(3)] and Axiom [DiSBAC(1)(3)/DiSBAC(1)(5)]. The kinetic parameters of each membrane probe were investigated in RBL-2H3 cells expressing an endogenous inward rectifier potassium channel (IRK1). The FMP dye presented the highest signal over background ratio whereas the FRET dyes from PanVera gave the fastest response. The determination of IC(50) values for 8 different channel modulators indicated a good correlation between the 4 membrane probe systems. The compound-dye interaction was evaluated in the presence of compounds at 10 muM and clearly indicated no effect on the FMP or the PanVera donor dye, whereas some major interference with the oxonol probes was observed. Using a cell permeabilization assay in the presence of gramicidin, the authors concluded that the FRET dyes from PanVera and the FMP dye are unable to measure the gramicidin-induced cell membrane hyperpolarizations. The 4 dye systems were investigated under high-throughput screening (HTS) conditions, and their respective Z' parameter was determined. The characteristics of each dye system and its potential use in HTS assays is discussed.     

The use of the potential-sensitive fluorescent probe bisoxonol in mast cells.

The regulation of the plasma membrane potential of rat peritoneal mast cells at the resting state and during activation was investigated using bisoxonol as a potential-sensitive fluorescent dye. Fluorescence microphotography showed that this negatively charged probe was not only present in the plasma membrane, but was also distributed in the cytoplasm. The intracellular localization of bisoxonol was confirmed by conducting experiments which showed that bisoxonol fluorescence was not enhanced in ATP-permeabilized mast cells. Rotenone (10(-7) M) and oligomycin (10(-6) M) did not change the fluorescence of bisoxonol showing, therefore, mitochondrial depolarization was not recorded with bisoxonol and suggesting that bisoxonol may represent a useful probe to study plasma membrane potential changes in the absence of exocytosis. We showed that, in non-stimulated mast cells, the blockade of the sodium pump enhanced the fluorescence of bisoxonol as did gramicidin a non selective ionophore used to fully depolarize the cells. High concentration of potassium (30 mM) as well as different ionic channel blockers did not significantly change the fluorescence intensity of bisoxonol, suggesting that ionic channel permeabilities were not involved in maintaining the resting plasma membrane potential of mast cells. Mast cells stimulated by compound 48/80 completely lost the fluorescence, shown by fluorescence microphotography, suggesting that exocytotic phenomena might induce a dye redistribution which is not only due to changes in the plasma membrane potential. In mast cells pretreated with pertussis toxin, which blocks mast cell-exocytosis, compound 48/80 induced a delayed (2 min) decrease of bisoxonol fluorescence which was shown to be dependent on the activity of the sodium pump. Considering that bisoxonol is a useful potential-sensitive probe in exocytosis-deprived mast cells, our results suggest that the sodium pump is mainly involved in the changes of plasma membrane potential of mast cells.