Membrane potentials associated with Ca-induced K conductance in human red blood cells: studies with a fluorescent oxonol dye, WW 781

Indications for acceleration-dependent changes of membrane potential in the flagellate Euglena gracilis

The effects of the calcium sequester EGTA on gravitactic orientation and membrane potential changes in the unicellular flagellate Euglena gracilis were investigated during a recent parabolic-flight experiment aboard of an Airbus A300. In the course of a flight parabola, an acceleration profile is achieved which yields subsequently about 20 s of hypergravity (1.8 g(n)), about 20 s of microgravity, and another 20 s of hypergravity phases. The movement behavior of the cells was investigated with real-time, computer-based image analysis. Membrane potential changes were detected with a newly developed photometer which measures absorption changes of the membrane potential-sensitive probe oxonol VI. To test whether the data obtained by the oxonol device were reliable, the signal of non-oxonol-labelled cells was recorded. In these samples, no absorption shift was detected. Changes of the oxonol VI signals indicate that the cells depolarize during acceleration (very obvious in the step from microgravity to hypergravity) and slightly hyperpolarize in microgravity, which can possibly be explained with the action of Ca-ATPases. These signals (mainly the depolarization) were significantly suppressed in the presence of EGTA (5 mM). Gravitaxis in parallel was also inhibited after addition of EGTA. Initially, negative gravitaxis was inverted into a positive one. Later, gravitaxis was almost undetectable.

The noncompetitive inhibitor WW781 senses changes in erythrocyte anion exchanger (AE1) transport site conformation and substrate binding

WW781 binds reversibly to red blood cell AE1 and inhibits anion exchange by a two-step mechanism, in which an initial complex (complex 1) is rapidly formed, and then there is a slower equilibration to form a second complex (complex 2) with a lower free energy. According to the ping-pong kinetic model, AE1 can exist in forms with the anion transport site facing either inward or outward, and the transition between these forms is greatly facilitated by binding of a transportable substrate such as Cl(-). Both the rapid initial binding of WW781 and the formation of complex 2 are strongly affected by the conformation of AE1, such that the forms with the transport site facing outward have higher affinity than those with the transport site facing inward. In addition, binding of Cl(-) seems to raise the free energy of complex 2 relative to complex 1, thereby reducing the equilibrium binding affinity, but Cl(-) does not compete directly with WW781. The WW781 binding site, therefore, reveals a part of the AE1 structure that is sensitive to Cl(-) binding and to transport site orientation, in addition to the disulfonic stilbene binding site. The relationship of the inhibitory potency of WW781 under different conditions to the affinities for the different forms of AE1 provides information on the possible asymmetric distributions of unloaded and Cl(-)-loaded transport sites that are consistent with the ping-pong model, and supports the conclusion from flux and nuclear magnetic resonance data that both the unloaded and Cl(-)-loaded sites are very asymmetrically distributed, with far more sites facing the cytoplasm than the outside medium. This asymmetry, together with the ability of WW781 to recruit toward the forms with outward-facing sites, implies that WW781 may be useful for changing the conformation of AE1 in studies of structure-function relationships.

Nonmediated flip-flop of anionic phospholipids and long-chain amphiphiles in the erythrocyte membrane depends on membrane potential

The nonmediated inward translocation (flip) of the anionic fluorescent N-(7-nitrobenz-2-oxa-1,3-diazol-4-yl)- (NBD-)labeled phospholipid phosphatidylmethanol (PM) from the outer to the inner membrane leaflet of human erythrocytes and vice versa depends on membrane potential. Interestingly, inside-positive potentials due to chloride gradients and the native chloride conductance of the cells resulted in an increase of the flip rates. This flip enhancement could be suppressed by addition of gramicidin D, which increases cation conductance, or 4,4'-diisothiocyanatostilbene-2,2'-disufonate (DIDS), which inhibits anion conductance. Conversely, inside negative potentials established by an outward-directed K+ gradient in the presence of gramicidin on DIDS-treated cells resulted in a decrease of flip rate. Flip rate exhibited an exponential dependence on membrane potential. The opposite effects of the positive and negative potentials were obtained for the outward translocation (flop) from the inner to the outer membrane leaflet. Similar potential dependencies were found for the nonmediated flip of anionic NBD-labeled phosphatidic acid (PA) and 2-(N-decyl)aminonaphthalene-6-sulfonic acid (2,6-DENSA) following blockage of the band-3-mediated component of flip. The membrane potential also influences the stationary distribution of the anionic lipids between the inner and outer leaflets. The distribution is shifted to the inner leaflet by increasingly positive potentials and to the outer leaflet by increasingly negative potentials. It is concluded that nonmediated flip-flop of the anionic phospholipids and the long-chain sulfonate represents electrogenic translocation of the unprotonated charged lipids across the hydrophobic barrier.

Electrodiffusion, barrier, and gating analysis of DIDS-insensitive chloride conductance in human red blood cells treated with valinomycin or gramicidin

Current-voltage curves for DIDS-insensitive Cl- conductance have been determined in human red blood cells from five donors. Currents were estimated from the rate of cell shrinkage using flow cytometry and differential laser light scattering. Membrane potentials were estimated from the extracellular pH of unbuffered suspensions using the proton ionophore FCCP. The width of the Gaussian distribution of cell volumes remained invariant during cell shrinkage, indicating a homogeneous C1- conductance among the cells. After pretreatment for 30 min with DIDS, net effluxes of K+ and Cl- were induced by valinomycin and were measured in the continued presence of DIDS; inhibition was maximal at approximately 65% above 1 microM DIDS at both 25 degrees C and 37 degrees C. The nonlinear current-voltage curves for DIDS-insensitive net Cl- effluxes, induced by valinomycin or gramicidin at varied [K+] o, were compared with predictions based on (1) the theory of electrodiffusion, (2) a single barrier model, (3) single occupancy, multiple barrier models, and (4) a voltage-gated mechanism. Electrodiffusion precisely describes the relationship between the measured transmembrane voltage and [K+]o. Under our experimental conditions (pH 7.5, 23 degrees C, 1-3 microM valinomycin or 60 ng/ml gramicidin, 1.2% hematocrit), the constant field permeability ratio PK/PCl is 74 +/- 9 with 10 microM DIDS, corresponding to 73% inhibition of PCl. Fitting the constant field current-voltage equation to the measured Cl- currents yields PCl = 0.13 h-1 with DIDS, compared to 0.49 h-1 without DIDS, in good agreement with most previous studies. The inward rectifying DIDS-insensitive Cl- current, however, is inconsistent with electrodiffusion and with certain single-occupancy multiple barrier models. The data are well described either by a single barrier located near the center of the transmembrane electric field, or, alternatively, by a voltage-gated channel mechanism according to which the maximal conductance is 0.055 +/- 0.005 S/g Hb, half the channels are open at -27 +/- 2 mV, and the equivalent gating charge is -1.2 +/- 0.3.

Slow fluorescent indicators of membrane potential: a survey of different approaches to probe response analysis

Basic tenets related to the use of three main classes of potentiometric redistribution fluorescent dyes (carbocyanines, oxonols, and rhodamines) are discussed in detail. They include the structure/function relationship, formation of nonfluorescent (H-type) and fluorescent (J-type) dimers and higher aggregates, probe partitioning between membranes and medium and binding to membranes and intracellular components (with attendant changes in absorption and emission spectra, fluorescence quantum yield and lifetime). The crucial importance of suitable probe-to-cell concentration ratio and selection of optimum monitored fluorescence wavelength is illustrated in schematic diagrams and possible artifacts or puzzling results stemming from faulty experimental protocol are pointed out. Special attention is paid to procedures used for probe-response calibration (potential clamping by potassium in the presence of valinomycin, use of gramicidin D in combination with N-methylglucamine, activation of Ca-dependent K-channels by A23187, the null-point technique). Among other problems treated are dye toxicity, interaction with mitochondria and other organelles, and possible effects of intracellular pH and the quantity of cytosolic proteins and/or RNA on probe response. Individual techniques using redistribution dyes (fluorescence measurements in cuvettes, flow cytometry and microfluorimetry of individual cells including fluorescence confocal microscopy) are discussed in terms of reliability, limitations and drawbacks, and selection of suitable probes. Up-to-date examples of application of slow dyes illustrate the broad range of problems in which these probes can be used.

An oxonol dye is the most potent known inhibitor of band 3-mediated anion exchange

When cells are acutely exposed to the oxonol dye, bis(1,3-dibutylbarbituric acid)pentamethine oxonol (diBA), at 0 degrees C, the concentration that gives half inhibition of Cl- exchange (IC50) is 0.146 +/- 0.013 microM (n = 12) initially, but the inhibition increases with time. These characteristics indicate that a rapid initial binding is followed by a slow conformational change that makes the binding tighter. If diBA is allowed to equilibrate with band 3, the IC50 is only 1.05 +/- 0.13 nM (n = 5), making diBA a more potent inhibitor than 4,4'-diisothiocyanostilbene-2,2'-disulfonic acid (DIDS), for which the IC50 under similar conditions is 31 +/- 6 nM [T. Janas, P. J. Bjerrum, J. Brahm, and J. O. Wieth. Am. J. Physiol. 257 (Cell Physiol. 26): C601-C606, 1989]. Inhibition by diBA is very slowly reversible at 0 degrees C (t1/2 > 50 h), but the effect is more readily reversible at higher temperatures. DiBA competes with 4,4'-dinitrostilbene-2,2'-disulfonate (DNDS) for inhibition, suggesting an external site of action. In contrast to DIDS and DNDS, however, increasing Cl- concentrations do not decrease the inhibitory effect of diBA, indicating that the inhibition is not competitive. Thus diBA may be useful for investigating conformational changes during anion exchange and for stopping transport without preventing substrate binding. However, when diBA and other oxonols are used to sense membrane potential, they may have undesirable side effects on anion transport processes.

Barium evokes glutamate release from rat brain synaptosomes by membrane depolarization: involvement of K+, Na+, and Ca2+ channels

During K(+)-induced depolarization of isolated rat brain nerve terminals (synaptosomes), 1 mM Ba2+ could substitute for 1 mM Ca2+ in evoking the release of endogenous glutamate. In addition, Ba2+ was found to evoke glutamate release in the absence of K(+)-induced depolarization. Ba2+ (1-10 mM) depolarized synaptosomes, as measured by voltage-sensitive dye fluorescence and [3H]-tetraphenylphosphonium cation distribution. Ba2+ partially inhibited the increase in synaptosomal K+ efflux produced by depolarization, as reflected by the redistribution of radiolabeled 86Rb+. The release evoked by Ba2+ was inhibited by tetrodotoxin (TTX). Using the divalent cation indicator fura-2, cytosolic [Ca2+] increased during stimulation by approximately 200 nM, but cytosolic [Ba2+] increased by more than 1 microM. Taken together, our results indicate that Ba2+ initially depolarizes synaptosomes most likely by blocking a K+ channel, which then activates TTX-sensitive Na+ channels, causing further depolarization, and finally enters synaptosomes through voltage-sensitive Ca2+ channels to evoke neurotransmitter release directly. Though Ba(2+)-evoked glutamate release was comparable in level to that obtained with K(+)-induced depolarization in the presence of Ca2+, the apparent intrasynaptosomal level of Ba2+ required for a given amount of glutamate release was found to be several-fold higher than that required of Ca2+.

WW-781, a potent reversible inhibitor of red cell Cl- flux, binds to band 3 by a two-step mechanism

WW-781 ([3-methyl-1-p-sulfophenyl-5-pyrazolone-(4)]-[1,3-dibutylbarbit uric acid]-pentamethine oxonol), a fluorescent dye that has been used for measuring membrane potentials by optical methods, inhibits human red blood cell Cl- exchange, which is mediated by the membrane protein known as band 3 or capnophorin. The inhibition is slowly reversible upon removal of WW-781 from the medium, with a half time of approximately 4.7 min in 150 mM Cl- medium at 0 degrees C. The mechanism of inhibition by WW-781 involves a two-step binding reaction. WW-781 binds rapidly to band 3 to form an initial complex, which can also rapidly dissociate. Formation of this initial complex is followed by the much slower formation of a second complex (with a rate constant of approximately 1.1 min-1), probably involving a protein conformational change, through which WW-781 is more tightly bound to band 3. At low concentrations, WW-781 inhibits Cl- exchange with a stoichiometry of 1 WW-781 molecule per band 3 monomer, suggesting that under these conditions the binding of WW-781 is highly selective for the band 3 protein.

Ionophore-induced Cl- transport in human erythrocyte suspensions: a multinuclear magnetic resonance study

To investigate the effect of ionophores on Cl- distribution in human erythrocyte suspensions, we measured the membrane potential by using 19F and 31P NMR methods. Incubation of human erythrocytes with 0.005 mM of the neutral ionophores valinomycin and nonactin resulted in membrane potentials of -21.2 and -17.8 mV in the presence and absence of DIDS. However, 0.020 mM of the carboxylic ionophores lasalocid, monensin, and nigericin yielded membrane potentials similar to those measured in the absence of ionophore (-9.4 mV). In methanol, the 35Cl- NMR linewidth in the presence of valinomycin was twice as broad as those observed in the presence of carboxylic ionophores, suggesting that neutral ionophores induce Cl- efflux in part via ion pairing.

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 sidedness and the interaction of H+ and K+ on Ca2(+)-activated K+ transport in human red blood cells

The sided effects of H+ on Ca2(+)-stimulated K+ transport (the Gardos channel) were studied in human red blood cells. Cells were loaded with Ca2+ during energy depletion with the internal pH adjusted to desired levels prior to treatment with the anion-exchange inhibitor 4,4'-diisothiocyanostilbene-2,2'-disulfonic acid (DIDS), which inhibits pH equilibration across the membrane. This treatment provides a "pH clamp" whereby the internal and external H+ (H+i and H+o) concentrations can be varied separately. Channel activity was evaluated by measuring either net K+ loss or unidirectional 42K+ efflux from cells where SO2(-4) replaced Cl- on both sides of the membrane. When pHi was set at 7.4, decreasing pHo from values of 8.0 to 5.0 inhibited K+ efflux. This effect of H+o could be overcome by increasing K+o at all values of pHo. In addition, this effect of K+o could be separated from its effects on altering the membrane potential, indicating an interaction between K+o and H+o on the channel. A similar interaction was shown to occur between H+i and K+i. K+o is known to be required for activation of Ca2(+)-stimulated K+ transport, since the channel in cells preincubated in the absence of K+o (prior to exposure to Ca+i) becomes refractory to subsequent activation by Ca2+i and K+o. We found that H+o would not substitute for K+o in this regard nor would H+o inhibit the protective effect of K+o; in addition, H+ was not transported inward in exchange for K+i. Thus it would appear that there are two external sites where K+o interacts with the channel. One site is antagonized by H+o, whereas the second site is required for channel activation independent of H+ in the range studied. The inside of the channel would have, by an analogous argument, at least one site where K+i and H+i interact.

Dual-wavelength ratiometric fluorescence measurements of membrane potential

This work shows that the voltage across membranes in two very different preparations, lipid vesicles in suspension and individual HeLa cells under a microscope, is linearly related to the ratio of fluorescence excited from the two wings of the absorption spectrum of a voltage-sensitive dye. The dye di-4-ANEPPS [1-(3-sulfonatopropyl)-4-[beta-[2-(di-n-butylamino)-6-naphthyl] vin yl]pyridinium betaine] is well characterized from earlier investigations and responds via a rapid (less than millisecond) spectral shift to membrane potential changes. The resultant small change in fluorescence intensity monitored at a single wavelength is useful for measurements of temporally well-defined voltage transients such as action potentials. The dual-wavelength approach described in this work extends the usefulness of this fast potentiometric dye by filtering out complex or artifactual changes in fluorescence intensity and providing a voltage-dependent signal that is internally standardized. Thus, rapid measurements of membrane potential are made possible in nonexcitable cells.

Impermeant potential-sensitive oxonol dyes: III. The dependence of the absorption signal on membrane potential

We have measured potential-dependent changes in the absorption of light by oxidized cholesterol bilayer lipid membranes in the presence of impermeant oxonol dyes. The magnitude of the absorption signal increased linearly with the size of potential steps over a range of 500 mV. The signal also increased when the offset voltage of the pulse train was increased from -150 to +150 mV. The data are consistent with the "on-off" mechanism proposed by E. B. George et al. (J. Membrane Biol. 103:245-253, 1988) in which the probe undergoes potential-dependent movement between a binding site in the membrane and an aqueous region just off the surface of the membrane. An equilibrium thermodynamic analysis of the experimental data indicates that the negatively charged oxonol chromophore senses only 5-10% of the total membrane potential difference across the membrane when it is driven into a nonpolar binding site on the membrane.

Impermeant potential-sensitive oxonol dyes: I. Evidence for an "on-off" mechanism

This series of papers addresses the mechanism by which certain impermeant oxonol dyes respond to membrane-potential changes, denoted delta Em. Hemispherical oxidized cholesterol bilayer membranes provided a controlled model membrane system for determining the dependence of the light absorption signal from the dye on parameters such as the wavelength and polarization of the light illuminating the membrane, the structure of the dye, and delta Em. This paper is concerned with the determination and analysis of absorption spectral changes of the dye RGA461 during trains of step changes of Em. The wavelength dependence of the absorption signal is consistent with an "on-off" mechanism in which dye molecules are driven by potential changes between an aqueous region just off the membrane and a relatively nonpolar binding site on the membrane. Polarization data indicate that dye molecules in the membrane site tend to orient with the long axis of the chromophore perpendicular to the surface of the membrane. Experiments with hyperpolarized human red blood cells confirmed that the impermeant oxonols undergo a potential-dependent partition between the membrane and the bathing medium.

Calcium, cell shrinkage, and prolytic state of human red blood cells

The effects of intracellular calcium, or Cac, on the Na permeability of human red blood cells were examined during 3-h incubations with the Ca ionophore A23187 and varied external Ca, Cao. Above 3 microM Cao, Nac increased significantly as ATP decreased. Maintenance of normal ATP with vanadate did not prevent the gain of Nac. Similar amounts of Nac were gained in 3 h by ouabain-treated cells exposed to the K ionophore valinomycin or by cells osmotically shrunken. Cells shrunken with sucrose also exhibited partial loss of Kc. When the cells with increased Nac were subsequently transferred to Na-free, high-K medium, the Nac and Kc that had changed slowly over 3 h returned toward normal within 10 min. The development of irreversible high cation permeability in shrunken cells was not prevented by a variety of transport inhibitors. These observations and cell volume distributions suggest that prolonged shrinkage induces a subpopulation of cells to become highly cation permeable, or "prolytic". The major effect of Cac on Na permeability appears to be an indirect consequence of cell shrinkage due to KCl loss.

The interaction of potential-sensitive molecular probes with dimyristoylphosphatidylcholine vesicles investigated by 31P-NMR and electron microscopy

The effect of a number of commonly employed potential-sensitive molecular probes on the 31P-NMR properties of dimyristoylphosphatidylcholine vesicles at two field strengths has been investigated in order to obtain information on the location and effect of these probes on the membrane bilayer. In comparison to the control dye-free vesicle spectrum, the probes diS-C3-(5) and diS-C4-(5), when added to a vesicle suspension, cause a substantial broadening of the 31P resonance with no detectable chemical shift within an uncertainty of +/- 0.05 ppm at 24 MHz. The spin-lattice and spin-spin relaxation times are also reduced when the cyanines are present by well over 20% relative to those of the control vesicle preparation. The addition of anionic probes, including several oxonol derivatives and merocyanine 540, causes no chemical shift, line broadening, or changes in the relaxation times. Possible explanations for the failure of the anionic probes to alter the vesicle 31P-NMR properties include charge repulsion between these dyes and the phosphate group that prevents the probes from penetrating the bilayer to a depth sufficient to alter the local motion of the phosphate moiety. The 31P resonance broadening and reduction in the relaxation times caused by the two cyanines is at least in part due to an increase in vesicle size as judged by electron microscopy measurements, although an inhibition of the local phosphate motion as well cannot be completely eliminated. The cyanine-mediated increase in vesicle size appears to be due to an irreversible vesicle-fusion process possibly initiated by the screening of surface charge by these probes. The implications of these observations in relation to functional energy-transducing preparations is discussed.

The effects of ionophore A23187 and concanavalin A on the membrane potential of human peripheral blood lymphocytes and rat thymocytes

Effects of the Ca2+-ionophore A23187 and concanavalin A on the membrane potential of human lymphocytes and rat thymocytes have been studied using the fluorescent potential probe diS-C3-(5). At concentrations of 10(-8) to 10(-6) M A23187 changes the membrane potential, inducing both hyper- and depolarization. Depending on concentrations of A23187 and the external Ca2+, and on the type of lymphocytes, one of these effects predominates. The hyperpolarization induced by A23187 is caused by activation of Ca2+-dependent K+ channels. It is blocked by quinine and high concentrations of extracellular K+. The dependence of Ca2+-activated K+ transport on extracellular Ca2+ and its sensitivity to calmodulin antagonists is different for human lymphocytes and for thymocytes. As distinct from lymphocytes, in thymocytes calmodulin is not involved in activation of Ca2+-dependent K+ transport. The depolarization induced in lymphocytes by A23187 is caused by an increase in Na+ permeability of the lymphocyte plasma membrane: it is eliminated in a low-Na+ medium. At mitogenic concentrations concanavalin A does not change the membrane potential of the lymphocytes. The results obtained permit elucidation of the relationship between two early events in lymphocyte activation, namely the increase in intracellular Ca2+ concentration and the increase in lymphocyte plasma membrane permeabilities to monovalent cations.

The Ca2+-sensitive K+-conductance of the human red cell membrane is strongly dependent on cellular pH

The conductance of the Ca2+-sensitive K+-channels in human red cell membranes has been determined as a function of the intracellular pH. A sudden increase in the intracellular concentration of ionized calcium was established by addition of ionophore A23187 to a suspension of cells in buffer-free, Ca2+-containing salt solution. At the various cellular pH-values cellular concentrations of ionized Ca, saturating with respect to activation of the Ca2+-sensitive K+-conductance, were obtained by the use of varied concentrations of extracellular Ca2+ and added ionophore A23187. Changes in membrane potential was monitored as CCCP-mediated changes in extracellular pH. Initial net effluxes of K+, cellular K+ contents and the K+ Nernst equilibrium potentials were calculated from flame photometric measurements. Cellular Ca-contents were determined by aid of 45Ca. With cellular Ca2+ at the saturating level with respect to activation of the K+-channel the K+-conductance calculated from these data was independent of extracellular pH and a steep function of cellular pH with a half maximal conductance of 31 microSeconds/cm2 at a cellular pH of 6.1. The K+-conductance is not a simple function of cellular pH (pHc). From pHc = 6.5 and down to pHc = 6.0 a Hill-coefficient of 2.5 was found, indicating cooperativity between at least two sites regulating the conductance. Below pHc = 6.0 an extremely high Hill-coefficient of 11 was found, probably indicating that the additional titration of the channel protein leads to an increased cooperativity. The importance, as a physiological regulatory mechanism, of a K+-conductance increasing from zero to maximal conductance within less than one unit of pH, is discussed.

KCl loss and cell shrinkage in the Ehrlich ascites tumor cell induced by hypotonic media, 2-deoxyglucose and propranolol

Ehrlich ascites tumor cells lose KCl and shrink after swelling in hypotonic media and in response to the addition of 2-deoxyglucose, propranolol, or the Ca2+ ionophore, A23187, plus Ca2+ in isotonic media. All of these treatments activate cell shrinkage via a pathway with the following characteristics: (1) the KCl loss responsible for cell shrinkage does not alter the membrane potential; (2) NO3(-) does not substitute for Cl-; (3) the net KCl movements are not inhibited by quinine or DIDS; and (4) early in this study furosemide was effective in inhibiting cell shrinkage but this sensitivity was subsequently lost. This evidence suggests that the KCl loss in these cells occurs via a cotransport mechanism. In addition, hypotonic media and the other agents used here stimulate a Cl(-) - Cl(-) exchange, a net loss of K+ and a net gain of Na+ which are not responsible for cell shrinkage. The Ehrlich cell also appears to have a Ca2+-activated, quinine-sensitive K+ conductive pathway but this pathway is not part of the mechanism by which these cells regulate their volume following swelling or shrink in isotonic media in response to 2-deoxyglucose or propranolol. Shrinkage by the loss of K+ through the Ca2+ stimulated pathway appears to be limited by Cl- conductive movements; for when NO3(-), an anion demonstrated here to have a higher conductive movement than Cl-, is substituted for Cl-, the cells will shrink when the Ca2+-stimulated K+ pathway is activated.

Relationship between the shape and the membrane potential of human red blood cells

Microscopic observations of isotonic suspensions of human red blood cells demonstrate that cell shape is unaltered when the transmembrane electrical potential, or Em, is set in the range -85 to + 10 mV with valinomycin at varied external K+, or Ko X Em was measured with the fluorescent potentiometric indicator, diS-C3(5), as calibrated by a delta pH method. Repeating Glaser's experiments in which echinocytosis was attributed to hyperpolarization, we found that at low ionic strength the pH-dependent effects of amphotericin B appear to be unrelated to Em. The effects of increased intracellular Ca2+, or Cac, on echinocytosis and on Em are separable. With Ca ionophore A23187 half-maximal echinocytosis occurs at greater Cao than that which induces the half-maximal hyperpolarization associated with Ca-induced K+ conductance (Gardos effect). Thus, cells hyperpolarized by increased Cac remain discoidal when Ca is below the threshold for echinocytosis. With A23187 and higher Cao, extensive echinocytosis occurs in cells which are either hyperpolarized or at their resting potential. The Ca-activation curve for echinocytosis is left-shifted by low Ko, a new observation consistent with increased DIDS-sensitive uptake of 45Ca by hyperpolarized cells. These results support the following conclusions: (1) the shape and membrane potential of human red blood cells are independent under the conditions studied; (2) in cells treated with A23187, the Gardos effect facilitates echinocytosis by increasing Cac.

Partial requirements for in vitro survival of human red blood cells

Some of the requirements for survival of human red blood cells were studied in vitro at 25 and 37 degrees C for 1--2 weeks. During the first week at 25 degrees C in Krebs-Ringer bicarbonate medium with glucose, the cells at 2--5% hematocrit (HCT) maintained normal K+, Na+, and water contents with negligible hemolysis. After six days ion gradients decreased, preceded by decline of ATP. With adenosine, ATP was maintained for 1--2 weeks. Sustained in vitro survival of human red blood cells at 25 or 37 degrees C requires constant pHo and sufficient substrates to support a glycolytic carbon flux as well as a nitrogen flux via nucleotide turnover. In Earle's salts buffered with HEPES and supplemented with glucose, Eagle's essential vitamins, albumin, and antibiotics, suspensions at 0.1% HCT exhibited constant pH at 7.39 +/- 0.03 for at least two weeks at 37 degrees C. With glucose alone, ATP declined steadily to negligible levels despite constant pHo, but 0.1 mM adenine supported ATP for one week. Also, several amino acids partially prevented the decline of reduced glutathione during the first week at 37 degrees C. These results and current knowledge of red cell metabolism suggest a new defined medium for experiments requiring long term incubations, and extend the characterization of human red cell in vitro survival to a time period not previously studied.