Role of extracellular Na and K in lymphocyte activation

Cavβ1 regulates T cell expansion and apoptosis independently of voltage-gated Ca2+ channel function

TCR stimulation triggers Ca2+ signals that are critical for T cell function and immunity. Several pore-forming α and auxiliary β subunits of voltage-gated Ca2+ channels (VGCC) were reported in T cells, but their mechanism of activation remains elusive and their contribution to Ca2+ signaling in T cells is controversial. We here identify CaVβ1, encoded by Cacnb1, as a regulator of T cell function. Cacnb1 deletion enhances apoptosis and impairs the clonal expansion of T cells after lymphocytic choriomeningitis virus (LCMV) infection. By contrast, Cacnb1 is dispensable for T cell proliferation, cytokine production and Ca2+ signaling. Using patch clamp electrophysiology and Ca2+ recordings, we are unable to detect voltage-gated Ca2+ currents or Ca2+ influx in human and mouse T cells upon depolarization with or without prior TCR stimulation. mRNAs of several VGCC α1 subunits are detectable in human (CaV3.3, CaV3.2) and mouse (CaV2.1) T cells, but they lack transcription of many 5' exons, likely resulting in N-terminally truncated and non-functional proteins. Our findings demonstrate that although CaVβ1 regulates T cell function, these effects are independent of VGCC channel activity.

The functional network of ion channels in T lymphocytes

For more than 25 years, it has been widely appreciated that Ca2+ influx is essential to trigger T-lymphocyte activation. Patch clamp analysis, molecular identification, and functional studies using blockers and genetic manipulation have shown that a unique contingent of ion channels orchestrates the initiation, intensity, and duration of the Ca2+ signal. Five distinct types of ion channels--Kv1.3, KCa3.1, Orai1+ stromal interacting molecule 1 (STIM1) [Ca2+-release activating Ca2+ (CRAC) channel], TRPM7, and Cl(swell)--comprise a network that performs functions vital for ongoing cellular homeostasis and for T-cell activation, offering potential targets for immunomodulation. Most recently, the roles of STIM1 and Orai1 have been revealed in triggering and forming the CRAC channel following T-cell receptor engagement. Kv1.3, KCa3.1, STIM1, and Orai1 have been found to cluster at the immunological synapse following contact with an antigen-presenting cell; we discuss how channels at the synapse might function to modulate local signaling. Immuno-imaging approaches are beginning to shed light on ion channel function in vivo. Importantly, the expression pattern of Ca2+ and K+ channels and hence the functional network can adapt depending upon the state of differentiation and activation, and this allows for different stages of an immune response to be targeted specifically.

A sodium channel opener inhibits stimulation of human peripheral blood mononuclear cells

The role of membrane potential changes in T cell activation was studied on human peripheral blood lymphocytes stimulated with phytohemagglutinin. Addition of bretylium tosylate, a sodium channels opener, to PHA treated lymphocytes modified the membrane potential and consequently blocked cell activation in a dose-dependent fashion. BT was non-toxic even in long-term (72 hr) incubations. It was reversibly removable, and the removal restored the stimulatory effect of PHA. 3H-thymidine incorporation was blocked if BT was present during the first 20-24 hr of the mitogenic activation. The later BT was added after PHA, the less inhibition of proliferation was observed. BT hyperpolarized the lymphocytes also in the presence of PHA. BT hindered the depolarizing effect of high extracellular potassium concns. The sustained polarized state of the lymphocytes did not influence the intracellular calcium increase upon PHA treatment. IL-2 and transferrin receptor expression was not hindered by BT during PHA stimulation of lymphocytes. Addition of rIL-2 did not abolish the inhibitory effect of BT. According to cell-cycle analysis BT arrested the majority of the cells in G1 phase. It is suggested that cell activation demands the flexible maintenance of a relatively narrow membrane potential "window". Any sustained and significant hyper-, or depolarization, may dramatically decrease the effectivity of transmembrane signalling.

Transmembrane electrical potential of lymphocytes in ageing mice. Flow cytometric analysis of mitogen-stimulated cells

The changes in transmembrane electrical potential (TMP) of Concanavalin A (Con-A)-stimulated lymphocytes from young adult and aged CBA/Ca mice were studied with a potential-sensitive fluorescent oxonol probe. The initial effect of Con-A was to depolarise lymphocytes from young mice and abrogated in the presence of tetraethylammonium chloride (TEA), an inhibitor of K(+)-selective channels. Young and old T lymphocytes both responded to the calcium ionophore A23187 by becoming hyperpolarized, but this occurred more slowly in the old cells. While treated with the ionophore, old B cells appeared to be limited in their ability to depolarize in the presence of high external K+ concentrations, which did not hold for T cells of old animals. One or more defects in the mechanisms of monovalent ion transport across the membrane of old lymphocytes are probably responsible for these differences and may be associated with the known age-related dysfunction of the immune system.

Effects of cyclosporin A on induced HIT cell alkalinization

We studied whether therapeutic doses of cyclosporin A (CsA) modify the effects of nutrient and non-nutrient stimuli on pHi, in the insulin-secreting beta-cell line HIT-T15. Glucose caused a transient acidification, followed by alkalinization. CsA failed to block this alkalinization. PMA elicited a gradual alkalinization by a protein kinase C mediated mechanism which is not inhibited by CsA. The depolarization with high K+ was associated with a rise in pHi. CsA was able to completely block this increase in pHi. Ionomycin induced a rapid cytosolic alkalinization partially inhibited by CsA. We conclude that in HIT-T15 cells, therapeutical doses of CsA inhibit the Ca(2+)-dependent pathway of Na+/H+ antiport activation but not protein kinase C activation of this exchanger.

Oscillating and triggering properties of T cell membrane potential

Using the patch-clamp technique, membrane potential (MP) behaviour under different electrogenic stimuli for both resting and Con A-activated T lymphocytes was studied. The voltage-gated K+ channels stabilize MP at the level of their threshold of activation (-44 +/- 5 mV, n = 27). Upon depolarization of the cell membrane by external current pulse (in the current-clamp mode), MP can oscillate with a high amplitude of 20-50 mV. The amplitude depends on the number of K+ channels per cell and the external current value. After current pulse termination, MP did not return to its initial value, but continued to oscillate. However, the cells first activated by Con A did not display this triggering effect. Thus, the properties of T cell membrane revealed appear to be associated with the functional state of the cell.

Bretylium causes a K(+)-Na+ pump activation that is independent of Na+/H+ exchange in depolarized rat, mouse and human lymphocytes

We have studied a bretylium tosylate induced increase of the membrane potentials of partially depolarized rat, mouse and human lymphocytes, using the potential sensitive dye, bis [1,3, dibutylbarbituric acid-(5) trimethine oxonol]. The extent of this repolarization is dose-dependent and decreased in magnitude as the temp was reduced from 37 degrees C to room temp. The repolarizing effect is inhibited by K(+)-Na(+)-pump blockers or lack of extracellular Na+. Sodium ion channel blockers are effective in abolishing repolarization only if applied prior to, or simultaneously with, bretylium. Activation of Na+/H+ exchange is not involved in the mechanism of the phenomenon as the latter is completely eliminated in the presence of 10 microM amiloride (concn of the diuretics having no measurable inhibition on the action of the exchanger). These data suggest that bretylium opens ligand- and voltage-gated Na+ channels, and repolarization occurs due to higher activity of the K(+)-Na(+)-pump stimulated by the enhanced intracellular Na+ accumulation.

Early membrane potential and cytoplasmic calcium changes during mitogenic stimulation of WEHI 231 cell line by polyene antibiotics, lipopolysaccharide and anti-immunoglobulin

Changes in free cytosolic calcium concentration and in membrane voltage are thought to be important initiating events in lymphocyte activation. The antifungal agent amphotericin B (AmB) holds interesting immunomodulating properties and its N-thiopropionyl derivative (AmBSH) is a potent polyclonal B-cell activator. These molecules may then exert their stimulating activity through the production of early ionic signals similar to those delivered by the classical activators lipopolysaccharide (LPS) and anti-immunoglobulin (anti-Ig). We addressed this question in a B-cell line (WEHI 231) which has previously been shown to exhibit characteristic response to LPS and anti-Ig. AmBSH protected these cells against anti-Ig-induced cell growth inhibition, providing a LPS-like response. In contrast, the parental compound AmB did not. The two polyene antibiotics did not modify the resting Ca2+i level of the cells, neither did LPS, whereas anti-Ig induced a rapid increase in the cytosolic calcium concentration. On the other hand, polyene antibiotics and LPS promoted membrane depolarization, whereas membrane voltage remained unchanged after anti-Ig treatment. Polyene antibiotics-induced depolarization originated from the increase of membrane permeability to Na+ ions and occurred independently of Ca2+i changes. The relationship between membrane potential and Ca2+i changes in lymphocyte activation are discussed on the basis of these results. Our conclusion was that constitutive Ca2+(-)dependent K+ channels are absent in the WEHI 231 cell line.

Interactive effects of Na and K in killing by human natural killer cells

Contact-mediated lysis by human natural killer cells is inhibited by a number of drugs that block the predominant K channel. In this study we have further examined the role of the K channel and the interactions between passive K and Na transport in killing. Low external Na-inhibited killing and inhibition were not due to reduce inward current through the Na channels in the target cell. A role for the Na/H antiport is suggested since amiloride inhibited killing in a dose-dependent manner that was competitive with external Na. Depolarizing the killer cell with elevated external K did not inhibit killing. On the contrary, high K0 reduced the inhibition caused by low Na0 and by the K-channel blockers quinidine, verapamil, and retinoic acid. Hyperpolarizing the killer cell with low K0 or valinomycin inhibited killing. Valinomycin, which should prevent the depolarization caused by K-channel block, did not reverse the effect of the blockers quinidine, verapamil, and 4-aminopyridine. Hence, the primary role of the K channels during killing is not maintain the negative membrane potential. On the contrary, depolarization may promote killing under conditions where killing is submaximal.

Blocking of human T lymphocyte activation by channel antagonists

It has been established that early events in lymphocyte activation involve a rise in intracellular Ca++ as well as changes in the flux of other ions. Although a Ca++ channel has been postulated to participate in the early Ca++ rise, its presence in lymphocytes remains controversial. Also although yet undetected, electrophysiological data suggest the presence of a Ca++ activated K+ channel on human peripheral blood lymphocytes (HPBL). Here we report on the effect of specific channel blockers as an approach to the identification of these channels on HPBL. At 40 nM nifedipine, an inhibitor of voltage-gated Ca++ channels, fully inhibits the PHA-promoted activation of HPBL. This effect is concentration dependent with a half maximum effect at approximately 10 nM and is demonstrable whether the drug is added at the same time as or up to 18 h after the addition of the mitogen. This inhibition of activation is not seen if the lymphocytes are activated using IL-2 instead of PHA. Charybdotoxin a toxin which blocks a Ca++ activated K+ channel of muscle cells also blocks to almost 100 per cent the PHA-induced activation of HPBL. This inhibition can be demonstrated regardless of whether the blocker is added together with or up to 4 h after PHA. As opposed to nifedipine charybdotoxin shows no effect if added 18 h after the initiation of the activation process. When nifedipine and charybdotoxin were tested on mice splenocytes we found that nifedipine fully inhibits the LPS-promoted activation of these cells while charybdotoxin has no effect on their activation.(ABSTRACT TRUNCATED AT 250 WORDS)

Luminescence spectroscopic approaches in studying cell surface dynamics

The major elements of membranes, such as proteins, lipids and polysaccharides, are in dynamic interaction with each other (Albertset al.1983). Protein diffusion in the lipid matrix of the membrane, the lipid diffusion and dynamic domain formation below and above their transition temperature from gel to fluid state, have many functional implications. This type of behaviour of membranes is often summarized in one frequently used word membrane fluidity (coined by Shinitzky & Henkart, 1979). The dynamic behaviour of the cell membrane includes rotational, translational and segmental movements of membrane elements (or their domain-like associations) in the plane of, and perpendicular to the membrane. The ever changing proximity relationships form a dynamic pattern of lipids, proteins and saccharide moieties and are usually described as ‘cell-surface dynamics’ (Damjanovichet al.1981). The knowledge about the above defined behaviour originates from experiments performed mostly on cytoplasmic membranes of eukaryotic cells. Nevertheless numerous data are available also on the mitochondrial and nuclear membranes, as well as endo (sarco-)plasmic reticulum (Martonosi, 1982; Slater, 1981; Siekevitz, 1981).

Heterogeneity of lymphocyte calcium metabolism is caused by T cell-specific calcium-sensitive potassium channel and sensitivity of the calcium ATPase pump to membrane potential

Calcium management differs in T and B lymphocytes. [Ca2+]i elevation in response to calcium ionophores is up to 10 times greater in T cells than B cells. There is no difference between them in ionophore uptake. T cells, but not B cells, possess a calcium-sensitive potassium channel which produces membrane hyperpolarization at [Ca2+]i above 200 nM. This alters T cell density providing a rapid and easy method of cell separation. In contrast, B cells depolarize when [Ca2+]i is increased. Isolated B cell membrane vesicle ATP-dependent calcium pump activity is higher than T cell vesicles. Membrane depolarization reduces the [Ca2+]i response to ionomycin, most dramatically in T cells because they are hyperpolarized by increased [Ca2+]i. The most likely basis of this behavior is an effect of membrane potential on lymphocyte membrane calcium pump activity. This mechanism provides an explanation of the inhibitory effect of membrane depolarization on T lymphocyte responses.

Comparison of ion channels in multidrug-resistant and -sensitive human leukemic cells

Tumor cell lines selected to grow in the presence of one "natural product" antineoplastic drug often develop cross-resistance to others. This multidrug resistance (MDR) is believed to be a major problem in cancer therapy. Organic Ca2+-channel blockers, such as verapamil, can reverse this resistance and render MDR cells in culture nearly as sensitive to the antineoplastic drugs as the drug-sensitive cells from which they were derived. It has therefore been suggested that Ca2+ channels may play a role in MDR. To determine directly whether there are electrophysiological correlates of MDR, we used whole-cell and single-channel patch-clamp techniques to survey the ion channels in a drug-sensitive human T-cell leukemia line, CCRF-CEM, and a MDR variant, CEM/VLB100. We found no evidence for a voltage-gated Ca2+ channel. However, we did identify three other current/channel types: a voltage-gated tetrodotoxin-sensitive inward current carried by Na+, a voltage-gated labile outward current carried by K+, and a nonselective cation channel reversing at 0 mV. Drug-sensitive and -resistant cells were the same with respect to the level of expression of these channels.

Purine nucleotide metabolism in phytohemagglutinin-induced human T lymphocytes

The comprehensive studies of purine nucleotide metabolism were done in nonstimulated and phytohemagglutinin (PHA)-stimulated human peripheral blood T lymphocytes. Nonstimulated lymphocytes synthesize nucleotides in two alternative pathways: via biosynthesis de novo and salvage pathways. Although synthesis of triphosphonucleosides in unstimulated lymphocytes was the predominant pathway, interconversion of monophosphonucleosides was also active. Exposure of cells to PHA affects differently various pathways of nucleotide metabolism. The most marked changes observed were rapid activation of purine salvage within minutes after exposure to PHA, and significant increase of 5-phosphoribosyl-1-pyrophosphate levels. In addition, significant increases were found in de novo purine biosynthesis, nucleotide interconversions, and RNA and DNA synthesis, whereas catabolism of nucleotides remained unchanged. These results indicate that PHA activation of T lymphocytes causes a rapid synthesis of nucleotides which may be required immediately for increases in energy metabolism and later as the precursors of nucleic acid synthesis.

Transmembrane ion fluxes during activation of human T lymphocytes: role of Ca2+, Na+/H+ exchange and phospholipid turnover

The importance of increases in [Ca2+]i, stimulation of Na+/H+ exchange, and turnover of membrane phospholipids as signals for mitogen-induced activation of human T cells has been reviewed. In the presence of optimal concentrations of lectin and appropriately presented antigen, T cells increase [Ca2+]i, secrete IL2, express IL2 receptors and later divide. An increase in [Ca2+]i is critical for IL2 secretion in contrast to the requirements for IL2 receptor expression and IL2-IL2 receptor interaction. Treatment of T cells with TPA appears to bypass the requirement for an increase in [Ca2+]i for IL2 secretion and cell proliferation, indicating that various mitogens can trigger T cells through both [Ca2+]i-dependent and [Ca2+]i-independent pathways. Influx of Ca2+ from the extracellular milieu appears essential for the induced increase in [Ca2+]i associated with IL2 secretion. These increases in [Ca2+]i, which are correlated with the degree of lymphoproliferation and IL2 secretion, are sensitive to changes in membrane potential. The changes in [Ca2+]i are not mediated by the opening of voltage-gated K+ channels but the nature of the potential-sensitive event remains to be determined. The membrane potential effects may be mediated through the gating of a putative Ca2+ channel or by affecting the inward electrochemical Ca2+ gradient. It is clear that lymphoid cells of both T and B lineage possess a functional Na+/H+ antiport, which plays a central role in the regulation of pHi. It is also generally agreed that the antiport can be stimulated by mitogens, co-mitogens and by agents that induce differentiation. The meaning of this stimulation is not, however, entirely understood. It may be an essential signal or link in the series of events triggered by the binding of ligands to their membrane receptors. Alternatively, it may represent an ancillary event, intended to increase H+ ejection in anticipation of an increased metabolic rate. Finally, a third possible reason for the stimulation of Na+/H+ exchange could be to increase the osmotic content of the cells, inducing cell swelling that may be an early requirement for cellular growth. Indeed, amiloride-sensitive cellular swelling has been detected electronically following treatment of T lymphocytes with TPA (Grinstein et al. 1985a). PHA is a potent activator of phosphatidylinositol hydrolysis. In other cell types, receptors are coupled to phospholipase C by a G protein(s). However, the transducing mechanism in human peripheral blood lymphocytes does not appear to be a pertussis toxin-sensitive G protein(s).(ABSTRACT TRUNCATED AT 400 WORDS)

Cyclosporine A inhibits Ca2+-dependent stimulation of the Na+/H+ antiport in human T cells

The cyclic undecapeptide cyclosporine A (CsA) is a potent immunosuppressive agent that inhibits the initial activation of T lymphocytes. This agent appears to be most effective in blocking the action of mitogens such as concanavalin A and the calcium ionophore A23187, which cause an influx of Ca2+, but not those that may act by alternate mechanisms. These observations suggest that CsA may block a Ca2+-dependent step in T cell activation. We have shown that stimulation of the T3-T cell receptor complex-associated Ca2+ transporter activates the Na+/H+ antiport (Rosoff, P. M., and L. C. Cantley, 1985, J. Biol. Chem., 260: 14053-14059). The tumor-promoting phorbol esters, which are co-mitogenic for T cells, activate the exchanger by a separate pathway which is mediated by protein kinase C. Both the rise in intracellular Ca2+ and intracellular pH may be necessary for the successful triggering of cellular activation. In this report we show that CsA blocks the T3-T cell receptor-stimulated, Ca2+ influx-dependent activation of Na+/H+ exchange, but not the phorbol ester-mediated pathway in a transformed human T cell line. CsA inhibited mitogen-stimulation of interleukin-2 production in a separate cell line. CsA also inhibited vasopressin stimulation of the antiporter in normal rat kidney fibroblasts, but had no effect on serum or 12-O-tetradecanoyl phorbol 13-acetate stimulation. CsA did not affect serum or vasopressin or serum stimulation of normal rat kidney cell proliferation. CsA also had no effect on lipopolysaccharide or phorbol ester stimulation of Na+/H+ exchange activity or induction of differentiation in 70Z/3 pre-B lymphocytes in which these events are initiated by the protein kinase C pathway. These data suggest that mechanisms of activation of Na+/H+ exchange that involve an elevation in cytosolic Ca2+ are blocked by CsA but that C kinase-mediated regulation is unaffected. The importance of the Na+/H+ antiport in the regulation of growth and differentiation of T cells is discussed.

Increased voltage-gated potassium conductance during interleukin 2-stimulated proliferation of a mouse helper T lymphocyte clone

Recent work has demonstrated the presence of voltage-gated potassium channels in human peripheral blood T lymphocytes (Matteson, R., and C. Deutsch, 1984, Nature (Lond.), 307:468-471; DeCoursey T. E., T. G. Chandy, S. Gupta, and M. D. Cahalan, 1984, Nature (Lond.), 307:465-468) and a murine cytolytic T-cell clone (Fukushima, Y., S. Hagiwara, and M. Henkart, 1984, J. Physiol., 351:645-656). Using the whole cell patch clamp, we have found a potassium conductance with similar properties in a murine noncytolytic T lymphocyte clone, L2. Under voltage clamp, a step from a holding potential of -70 mV to +50 mV produces an average outward current of 100-150 pA in "quiescent" L2 cells at the end of their weekly maintenance cycle. When these cells are stimulated with human recombinant interleukin 2 (rIL2, 100 U/ml), they grow in size and initiate DNA synthesis at approximately 24 h. Potassium conductance is increased as early as 8 h after stimulation with rIL2 and rises to a level 3-4 times that of excipient controls by 24 h. The level remains elevated through 72 h, but as the cells begin to leave the cell cycle at 72-96 h, the conductance decreases quickly to a value only slightly higher than the initial one. Quinine, a blocker of this conductance, markedly reduces the rate at which L2 cells traverse the cell cycle, while also reducing the rate of stimulated protein synthesis. The regulation of potassium conductance in L2 cells during rIL2-stimulated proliferation suggests that potassium channel function may play a role in support of the proliferative response.

Voltage-gated potassium conductance in human T lymphocytes stimulated with phorbol ester

The whole-cell patch-clamp method was used to study the voltage-gated K+ conductance of human peripheral blood T lymphocytes. After entry into whole-cell recording mode, there are time-dependent changes in some properties of the conductance. Over the first 10-30 min, the threshold for activation shifts about 10 mV more negative, and the rates of activation and inactivation increase. Inactivation is less strongly voltage dependent than activation or deactivation. Lymphocytes were stimulated to proliferate in culture with the tumour promoter 12-O-tetradecanoylphorbol-13-acetate (TPA). No changes in K+ conductance were observed in the first few hours of TPA stimulation. At 24 h after mitogen addition, TPA-treated cells were found to have 1.7-fold greater average voltage-gated K+ conductance than unstimulated control cells. At 48 h, TPA-stimulated cells had the same average K+ conductance as at 24 h, even though the cells were now much increased in size, as measured by cell capacitance. DNA synthesis by cultures stimulated with TPA, phytohaemagglutinin or succinyl concanavalin A was depressed by the addition of 0.1 mM-quinine at any point in the culture period. In the first 20 h after mitogen addition, DNA synthesis was more effectively inhibited by quinine than if the drug were added later. Cell proliferation was equally sensitive to quinine regardless of mitogen.

Voltage-dependent ion channels in T-lymphocytes

The gigaohm seal 'patch-clamp' technique has recently enabled exploration of the electrical properties of cells of the immune system. In this paper we review progress made to date in cataloguing the ion channels present in the cell membranes of T-lymphocytes and present new data on the types of ion channels present in a number of human and murine T-cell-derived cell lines. The ion channels thus far described in these cells are strikingly similar to those found in nerve and muscle cells. Voltage-gated potassium channels resembling delayed rectifier potassium channels in excitable cells are present in most T-lymphocytes, T-lymphocyte-derived cell lines and macrophages. Sodium channels indistinguishable from those in excitable cells are present in a small fraction of T-cells and T-cell lines, and in some natural killer cells. Calcium channels have been reported in B-lymphocyte-derived cell lines, but have not been found in T-lymphocytes or in any T-cell-derived cell line. Potassium channels are required for activation of T-lymphocytes by mitogen, allogeneic cells, or by antigen, for lysis of target cells by natural killer cells, and may be involved in the triggering mechanism for activation of T-cells. The prevailing conception of early events in T-lymphocyte activation, the 'calcium hypothesis', involves an elevation of cytoplasmic free calcium levels as the proposed 'second messenger' in activation, giving rise to a cascade of subsequent events resulting eventually in cell division. A major focus of this paper is to evaluate specific mechanisms which have been proposed to account for experimental evidence, both in the literature and also presented here, pertaining to the calcium hypothesis. One such mechanism involves calcium channels, which have been postulated to account for the early calcium influx in activated T-lymphocytes. Since calcium channels have not been detected in T-cells, we explore the possibility that existing data can be accounted for without calcium channels. In particular, we show that many of the effects of 'calcium channel antagonists' such as verapamil, nifedipine, diltiazem and some polyvalent cations, can be accounted for by their blocking of voltage-gated potassium channels.

Lymphocyte membrane potential and Ca2+-sensitive potassium channels described by oxonol dye fluorescence measurements

A method is described for quantitative measurement of lymphocyte transmembrane electrical potential difference (psi) by flow cytometric recording of the oxonol dye fluorescence of single cells. Both the simultaneous collection and analysis of multiple optical parameters and the use of a negatively charged oxonol probe allowed more accurate measurement of psi than may be obtained by bulk cell suspension techniques employing cationic voltage indicators. Mouse spleen and human blood lymphocyte psi was calculated to be -70 mV. T and B lymphocytes maintain a constant psi as extracellular K+ is varied from 2 to 10 mM and the deviation from K+ equilibrium potentials (EK) is shown to result from Na+ permeability. At [K+]o values greater than 10 mM, lymphocytes behave as K+ electrodes. Examination of lymphocyte subsets showed that hyperpolarization induced by the Ca2+ ionophore A23187 occurs only in T cells. This response was identified as activation of a Ca2+-sensitive K+ channel by pharmacologic manipulations. Hence, T cells depolarized by 4-aminopyridine (4-AP, 10 mM) were observed to return to resting psi by A23187-induced elevation of [Ca2+]i. Cells depolarized by quinine (100 microM) were unaffected by A23187. The Ca2+-activated channel does not contribute to resting psi in T cells since it may be selectively blocked by quinine (20 microM) or modulated by calmodulin antagonists (5 microM trifluperazine) without affecting resting psi.

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.

Calcium-induced heterogeneous changes in membrane potential detected by flow cytofluorimetry

Ionophore-induced changes in the cell-associated fluorescence of samples of approx. 50000 individual murine L1210 leukemia cells which had been incubated with the voltage-sensitive dye 3,3'-dihexyloctacarbocyanine iodide (DiOC6(3] were monitored by flow cytometry. The K+ ionophore valinomycin (1 microM) produced homogeneous changes in the fluorescence of the entire population, the magnitude of which was dependent upon the concentration of extracellular K+. These changes allowed the estimation of the potassium equilibrium potential of the cells, by the null-point method, to be -11.9 mV. The Ca2+ ionophore A23187 (500 nM) produced heterogeneous changes in fluorescence, with populations of both hyperpolarised and depolarised cells. In addition, the depolarised population underwent an apparent size change, with a reduction in cell volume. This heterogeneity of response resulted in a minimal change in the median fluorescence value for the whole population, which suggests that it would not have been detectable by methods dependent upon net population-averaged changes in fluorescence. Removal of extracellular Na+ or preincubation of cells with amiloride (500 microM) effectively eliminated the depolarised population. Removal of extracellular K+ increased the hyperpolarised population. These findings provide evidence for the presence of Ca2+-induced Na+ exchange and Ca2+-induced K+ efflux mechanisms in these cells which may be expressed simultaneously in the cell population.

Role of membrane potential in the regulation of lectin-induced calcium uptake

Incubation of lymphocytes with mitogenic lectins triggers Ca2+ uptake. This increase in free cytoplasmic Ca2+ is postulated to be an important signal in the initiation of DNA synthesis. Transmembrane fluxes of monovalent ions and changes in membrane potential are also associated with lectin-induced activation of lymphocytes. We have examined the relationship between extra-cellular monovalent ion substitution, the associated electrical potential changes (measured with cyanine dyes), phytohemagglutinin-induced Ca2+ uptake (measured with Quin-2) and proliferation in human T cells. The results show that (1) the magnitude of the increase in free cytoplasmic Ca2+ concentration is correlated with the extent of the lymphoproliferative response, (2) lectin-induced Ca2+ fluxes are sensitive to membrane potential, decreasing with depolarization, and are likely conductive, and (3) the presence of extra-cellular Na+ during incubation with phytohemagglutinin is not essential to mitogenic triggering.

pH homeostasis in human lymphocytes: modulation by ions and mitogen

Quiescent human peripheral blood lymphocytes have been shown to maintain a relatively constant intracellular pH of 7.0-7.2 over an extracellular pH range of 6.9-7.4. Two methods of measuring intracellular pH were used in these studies, 19F nuclear magnetic resonance and [14C]5,5-dimethyloxazolidine-2,4-dione (DMO) equilibrium distributions. When ATP levels were decreased in these cells, actively maintained pH regulation was abolished and cells exhibited a constant pH gradient of 0.2 pH unit (acid inside relative to outside). Possible mechanisms for pH regulation are discussed. The effects of the Na+ and K+ composition of the medium on pH regulation showed no correlation with their effects on mitogen-induced proliferative response, which we have previously determined (Deutsch, C., and M. Price, 1982, J. Cell. Physiol., 111:73-79). In low-Na+ mannitol medium, pH regulation was similar to that observed for lymphocytes in normal medium, whereas mitogen-induced proliferation was severely inhibited in low-Na+ mannitol. In contrast, high-K+, low Na+ medium caused loss of pH homeostasis, whereas it restored the proliferative response. Loss of pH homeostasis was also observed on prolonged exposure of lymphocytes to mitogen (greater than 6 h in culture). However, mitogen stimulation led to little or no change in intracellular pH in the first few hours of cell culture. Therefore, a shift in intracellular pH is not a necessary or general event in mitogen-stimulated proliferation of lymphocytes.

The Na+-ionophore monensin enhances glucose uptake in mouse thymocytes

Monensin enhanced 2-deoxyglucose uptake and 3-O-methyl glucose transport in mouse thymocytes, but had no effect on L-glucose transport. Cytochalasin B inhibited monensin induced as well as basal glucose uptake. The enhanced 2-deoxyglucose uptake was time and dose-dependent. The increase in the rate of 2-deoxyglucose uptake induced by monensin was more rapid than that of Na+ uptake. Ouabain did not inhibit monensin-enhanced 2-deoxyglucose uptake. Monensin failed to stimulate 2-deoxyglucose uptake at low concentrations of Na+ (13 mM) or K+ (17 mM), higher concentrations of either cation were required for stimulation. Monensin enhanced glucose uptake also in Ca2+-free medium. The data indicate that the stimulation of 2-deoxyglucose uptake by monensin results from activation of carrier-mediated transport.

Effects of the skin mitogens tumor-promotor 12-O-tetradecanoylphorbol 13-acetate and divalent-cation-ionophore A23187 on ion fluxes and membrane potential in a murine epidermal cell line (HEL30) and in 3T3 fibroblasts

The transmembrane potential of HEL30 keratinocytes and 3T3 fibroblasts has been determined by measuring the distribution of labelled triphenylmethylphosphonium bromide. The tumor-promotor 12-O-tetradecanoylphorbol 13-acetate (1-5 microM) induces hyperpolarization in 3T3 cells but does not exert any effect on the membrane potential of keratinocytes, whereas the divalent cation ionophore A23187 (0.5 - 1 microM) hyperpolarizes keratinocytes and probably also 3T3 cells. Studies on Na+ and Rb+ fluxes, as well as with different inhibitors, indicate that the hyperpolarizing effect is the consequence of an increased Na+ influx which in turn stimulates the Na+/K+-dependent ATPase. No causal relationship seems to exist between the change of the membrane potential and arachidonic acid release (and subsequent prostaglandin synthesis) which is induced by both drugs in both cell lines. Since the induction of the arachidonic cascade (by both agents) as well as the stimulation of Na+ influx (by A23187) are found to be critically dependent on extracellular Ca2+ and are inhibited by 'Ca2+-blockers', it is concluded that both reactions are triggered by the same event (Ca2+ translocation) but proceed independently of each other. The release of arachidonic acid is already stimulated under conditions where a measurable influx of Ca2+ is not yet observed. This indicates a local mobilization of Ca2+, perhaps across the plasma membrane. It is concluded that monovalent cation fluxes and changes of the membrane potential are not critically involved in the stimulation of the arachidonic acid cascade and cellular proliferation by agents which induce epidermal hyperplasia in vivo.

Increasing the intracellular Na+ concentration induces differentiation in a pre-B lymphocyte cell line

The ability of lipopolysaccharide (LPS), a polyclonal B-cell mitogen, to induce differentiation in the pre-B cell tumor line 70Z/3 can be mimicked by drugs that increase the intracellular Na+ concentration. Pharmacologically increasing the cellular Na+ content with monensin, a sodium ionophore, or ouabain, a specific inhibitor of Na+, K+-ATPase, induces surface IgM expression in these cells. We have shown that LPS stimulates uptake of Na+ through an amiloride-sensitive pathway. These results show that the essential action of LPS to induce surface IgM expression is activation of a Na+ uptake system.

Regulation of intracellular pH by human peripheral blood lymphocytes as measured by 19F NMR

We have measured the intracellular pH of human peripheral blood lymphocytes by means of high-resolution 19F NMR spectroscopy using D,L-2-amino-3,3-difluoro-2-methylpropanoic acid (F2MeAla) as a probe. Lymphocytes readily took up the methyl ester of F2MeAla, and endogenous esterase hydrolyzed the ester to the free amino acid inside the cell. This alpha-methyl amino acid is not metabolized by the cell, and its 19F NMR spectrum exhibits large pH-dependent shifts as the alpha-amino group is protonated. The size of the 19F shifts, the high sensitivity of 19F NMR, and the favorable pKa of the alpha-amino group of F2MeAla (pKa = 7.3) allowed us to measure intracellular pH of lymphocytes at 25-30 degrees C with approximately 5-min acquisition times. Measurements at various external pH values demonstrated that human peripheral blood lymphocytes regulate their internal pH, a process requiring expenditure of metabolic energy. In the pH range between 6.8 and 7.4, lymphocytes maintain a constant internal pH of 7.17 +/- 0.06 pH unit. Outside this range, intracellular pH changes with extracellular pH. The accuracy of this 19F pH probe has been confirmed by independent measurements of intracellular pH using equilibrium distributions of 5,5-dimethyloxazolidine-2,4-dione.