Effect of membrane potential on divalent cation transport catalyzed by the "electroneutral" ionophores A23187 and ionomycin

Depolarization of plasma membrane potential has a potent inhibitory effect on divalent cation influx catalyzed by the carboxylic ionophores ionomycin and A23187. This effect is observed in different cell models and does not depend on either inhibition of Ca2+-activated cation channels or activation of Ca2+ extrusion mechanisms as suggested previously. A dependence of divalent cation influx on the magnitude of membrane potential is observed also in artificial liposomes. The inhibition of ionophore-dependent divalent cation transport by membrane potential depolarization can be modified varying the ionophore concentration and the external pH. These findings suggest that both neutral and positively charged ionophore-cation complexes can cross the plasma membrane and that their contribution to the overall transport process can be varied according to the experimental conditions.     

Electrical measurement of electroneutral fluxes of divalent cations through charged planar phospholipid membranes

The voltage-sensitive channel-former monazomycin is used as a conductance probe to monitor changes in the trans electrostatic surface potentials of negatively-charged planar phospholipid bilayers. Cis-to-trans electroneutral fluxes of divalent cations mediated by ionophores A23187 and X537A are sensed via the effect of transported divalent cations on the trans surface potentials. Quantitative determinations of neutral Ca2+ and Mg2+ fluxes are made and related to ionophore function.     

The activation of sea urchin eggs by the divalent ionophores A23187 and X-537A

The divalent ionophores A23187 and X-537A induce parthenogenesis in sea urchin eggs. This results from their ability to mobilize intracellular Ca²⁺, which is implicated in both artificial parthenogenesis as well as the natural fertilization process. A23187 causes expulsion of cortical granules and elevation of the fertilization membrane within 0.5–9 min followed by an initiation of cell cleavage. The broader spectrum ionophore X-537A is less potent, but the production of cytoplasmic aberrations are more apparent. In contrast to the sperm-activated egg, the initial phase of ionophore induced activation is accompanied either by relatively insignificant changes in membrane resistance, or an increase.     

The release of dopamine from synaptosomes from rat striatum by the ionophores X 537A and A 23187

The antibiotics X 537A and A 23187 are negatively charged divalent cation ionophores. X 537A may, in addition, be an ionophore for amines including catecholamines. The effects of these ionophores were examined on the uptake and release of dopamine by synaptosomes prepared from rat corpus striatum. Both X 537A and A 23187, at concentrations less than 0.5 μM, release both endogenous and [³H]-dopamine from synaptosomes. They had virtually no effect on the uptake of exogenous dopamine. These compounds act by different mechanisms. X 537A causes divalent ion-independent release in which a large fraction of the effluent consists of deaminated products. X 537A, in addition, releases [³H]dopamine from rat adrenal medullary chromaffin granules. The results suggest that X 537A causes release of dopamine from intrasynaptosomal storage vesicles and perhaps is acting as a catecholamine carrier across the vesicular membrane. A 23187, on the other hand, causes a Ca²⁺-dependent release in which only a small fraction of the catechol in the effluent is deaminated. A 23187 has little effect on the release of [³H]dopamine from chromaffin granules. These results suggest that A 23187 carries Ca²⁺ into the synaptosomes and thereby initiates exocytotic release.     

Calcium ionophores A23187 and X537A affect cell agglutination by lectins and capping of lymphocyte surface immunoglobulins

The microtubule-disruptive drugs colchicine and vinblastine alter ligand-induced redistribution of cell surface immunoglobulins and lectin receptors. These effects can be duplicated by treatment of cells with the divalent cation ionophores A23187 and X537A. Ionophore activity was dependent upon the presence of Ca²⁺ (1.8·10^?3?4·10^?4 M) in the culture medium. The K⁺-selective ionophore valinomycin had no effect on ligand-induced redistribution of surface receptors. It is suggested that A23187 and X537A impair membrane-associated microtubules involved in transmembrane control of receptor mobility and topography. In contrast to the action of colchicine and vinblastine that bind directly to microtubules, it is proposed that ionophores indirectly affect microtubules by raising the concentration of Ca²⁺ in the cytoplasm to levels that favor microtubule depolymerization and inhibit microtubule assembly.     

Metabolic characteristics of pancreatic beta-cells exposed to calcium-transporting ionophores.

The effects of the ionophores A-23187 and X-537 A on glucose metabolism, ATP content and sucrose permeability in pancreatic islets microdissected from obese-hyperglycemic mice were studied. The formation of 14CO2 from 10 mM D-[U-14C] GLUCOSE WAS INHIBITED BY OMISSION OF Ca2+ from the medium. A-23187 (10 muM) induced a further decrease of 14CO2 formation whereas X-537 A (10 muM) had no effect. At 20 mM glucose both A-23187 (48 muM) and X-537 A (43 muM) decreased the 14CO2 formation in the absence of Ca2+ whereas only X-537 A inhibited in the presence of Ca2+. X-537 A (43 muM) also decreased the formation of 3H2O from 20 mM D-[5-3H] glucose. The islet content of ATP was not changed after incubation in media deficient in either Mg2+ or Ca2+. However, omission of both Mg2+ and Ca2+ resulted in about 50% decrease of the ATP content. A-23187 and X-537 A induced dose-dependent decreases of the islet ATP content. X-537 A was much more potent than A-23187. Both ionophores induced stronger depression of the ATP content when Ca2+ was omitted. X-537 A (43 muM) but not A-23187 (48 muM) increased the beta-cell membrane permeability as indicated by an increased sucrose space in relation to the urea space of islets. Such an effect was not obtained with X-537 A at 1 muM or by omission of Ca2+. It is suggested that the marked metabolic effects of the ionophores reflect an impaired mitochondrial metabolism. These metabolic changes should be considered in interpretations of ionophore action on insulin secretion.     

Leucocyte locomotion and chemotaxis : The influence of divalent cations and cation ionophores

Human blood neutrophil leucocytes and monocytes incubated in the absence of Ca²⁺ and Mg²⁺ showed reduced, but still substantial migration into micropore filters towards chemotactic agents, compared with cells migrating in a divalent cation-rich medium. This reduction in migration could be reversed by adding low doses of divalent cation ionophores (X537A or A23187) to the Ca²⁺- and Mg²⁺-free medium which suggests that migrating leucocytes in media depleted of extracellular divalent cations can make use of intracellular divalent cations and that the intracellular cation exchange necessary for locomotion is facilitated by the ionophores. At higher doses, the ionophores inhibited locomotion, as did procaine which reduces membrane permeability to cations. Little effect of K⁺ depletion or of ouabain on leucocyte locomotion was noted.     

Mobilization of intracellular calcium by extracellular ATP and by calcium ionophores in the Ehrlich ascites-tumour cell

We have studied the changes of the intracellular free calcium concentration ([Ca2+]i) effected by external ATP, which induces formation of inositol trisphosphate, and by the divalent cation ionophores ionomycin and A23187. Both, ATP (40 microM) and ionophores (1-80 mumol/l cells ionomycin; 20-400 mumol/l cells A23187), produced a transient rise of [Ca2+]i which reached its maximum within 15-30 s and declined near resting values (about 200 nM) within 1-3 min. When the [Ca2+]i peak surpassed 500 nM a transient cell shrinkage due to simultaneous activation of Ca2+-dependent K+ and Cl- channels was also observed. The cell response was similar in medium containing 1 mM Ca2+ and in Ca2+-free medium, suggesting that the Ca mobilized to the cytosol comes preferently from the intracellular stores. Treatment with low doses of ionophore (1 mumol/l cells for ionomycin; 20 mumol/l cells for A23187) depressed the response to a subsequent treatment, either with ionophore or with ATP. Treatment with ATP did also inhibit the subsequent response to ionophore, but in this case the inhibition was dependent on time, the stronger the shorter the interval between both treatments. This result suggests that the permeabilization of Ca stores by ATP is transient and that Ca can be taken up again by the intracellular stores. Refill was most efficient when Ca2+ was present in the incubation medium. Addition of either ATP or ionomycin (1-25 mumol/l cells) to cells incubated in medium containing 1 mM Ca2+ decreased drastically the total cell Ca content during the following 3 min of incubation. In the case of ATP the total cell levels of Ca returned to the initial values after 7-15 min, whereas in the case of the ionophore they remained decreased during the whole incubation period. These results indicate that Ca released from the intracellular stores by either ATP or ionophores is quickly extruded by active mechanisms located at the plasma membrane. They also suggest that, under the conditions studied here, with 1 mM Ca2+ outside, the Ca-mobilizing effect of ionophores is stronger in endomembranes than in the plasma membrane.     

Effects of pH conditions on Ca2+ transport catalyzed by ionophores A23187, 4-BrA23187, and ionomycin suggest problems with common applications of these compounds in biological systems.

Phospholipid vesicles loaded with Quin-2 and 2'',7''-bis(2-carboxyethyl)-5(6)-carboxyfluorescein (BCECF) have been used to investigate the effects of pH conditions on Ca2+ transport catalyzed by ionophores A23187, 4-BrA23187, and ionomycin. At an external pH of 7.0, a delta pH (inside basic) of 0.4-0.6 U decreases the rate of Ca2+ transport into the vesicles by severalfold under some conditions. The apparent extent of transport is also decreased. In contrast, raising the pH by 0.4-0.6 U in the absence of a delta pH increases both of these parameters, although by smaller factors. The relatively large effects of a delta pH on the transport properties of Ca2+ ionophores seem to reflect a partial equilibration of the transmembrane ionophore distribution with the H+ concentration gradient across the vesicle membrane. This unequal distribution of ionophore can cause a very slow or incomplete ionophore-dependent equilibration of delta pCa with delta pH. A second factor of less certain origin retards full equilibration of delta pCa when delta pH = 0. These findings call into question several ionophore-based methods that are used to investigate the regulatory activities of Ca2+ and other divalent cations in biological systems. Notable among these are the null-point titration method for determining the concentration of free cations within cells and the use of ionophores plus external cation buffers to calibrate intracellular cation indicators. The present findings also indicate that the transport mode of Ca2+ ionophores is more strictly electroneutral than was thought, based upon previous studies.     

Fluorescence study of the divalent cation-transport mechanism of ionophore A23187 in phospholipid membranes

The mechanism for transport of divalent cations across phospholipid bilayers by the ionophore A23187 was investigated. The intrinsic fluorescence of the ionophore was used in equilibrium and rapid-mixing experiments as an indicator of ionophore environment and complexation with divalent cations. The neutral (protonated) form of the ionophore binds strongly to the membrane, with a high quantum yield relative to that in the aqueous phase. The negatively charged form of the ionophore binds somewhat less strongly, with a lower quantum yield, and does not move across the membrane. Complexation of the negatively charged form with divalent cations was measured by the decrease in fluorescence. An apparent rate constant (kapp) for transport of the ionophore across the membrane was determined from the rate of fluorescence changes observed in stopped-flow rapid kinetic experiments. The variation of kapp was studied as a function of pH, temperature, ionophore concentration, membrane lipid composition, and divalent cation concentration and type. Analysis and comparison with equilibrium constants for protonation and complexation show that A23187 and its metal:ionophore complexes bind near the membrane-water interface in the lipid polar-head region. The interfacial reactions occur rapidly, compared with the transmembrane reactions, and are thus in equilibrium during transport. The transport cycle can be described as follows: a 1:1 complex is formed between the membrane bound A23187-(Am-) and the aqueous divalent cation with dissociation constant K1 approximately 4.6 x 10(-4) M. This is in equilibrium with a 1:2 (metal:ionophore) complex (K2 approximately 3.0 x 10(-4) [ionophore/lipid]) that is responsible for transporting the divalent cations across the membrane. The rate constant for translocation of the 1:2 complex is 0.1-0.3 s-1. Dissociation of the complex of the trans side and protonation occur rapidly. The rate constant for translocation of H+ . A23187- is 28 s-1. A theory is presented that is capable of reproducing the kinetic data at any calcium concentration. The cation specificity for ionophore complex transport (kapp), determined at low ionophore concentration for a series of divalent cations, was found to be proportional to the equilibrium constant for 1:1 complexation. The order of ion specificity for these processes was found to be Ca2+ greater than Mg2+ greater Sr2+ greater than Ba2+. Interactions with Na+ were not observed. Maximal values of kapp were observed for vesicles prepared from pure dimyristoyl phosphatidylcholine. Inclusion of phosphatidyl ethanolamine, phosphatidic acid, or dipalmatoyl phosphatidylcholine resulted in lower values of kapp. Calcium transport by A23187 is compared with that of X537A, and it is shown that the former is 67-fold faster. The difference in rates is due to differences in the ability of each ionophore to form a 1:2 complex from a 1:1 complex.     

The stoichiometry of A23187- and X537A-mediated calcium ion transport across lipid bilayers

Initial rates of ionophore-mediated Ca2+ transport across egg phosphatidylcholine bilayers of large unilamellar vesicles were measured using the absorbance change of arsenazo III at 650 nm as an indicator of Ca2+ translocation. A23187 induced the movement of Ca2+ in a 2:1 ionophore: Ca2+ complex, whereas its methyl ester (CH3A23187) and X537A mediated Ca2+ movement in a 1:1 ionophore: Ca2+ complex. The relative potencies of these ionophores in transporting Ca2+ across lipid membranes were A23187 much greater than X537A greater than CH3A23187.     

Electrophysiology of phagocytic membranes. III. Evidence for a calcium-dependent potassium permeability change during slow hyperpolarizations of activated macrophages

The roles of potassium and calcium in the slow hyperpolarizations of membranes of activated macrophages are investigated using standard intracellular electrical recording techniques. The amplitude of spontaneous slow hyperpolarizations decreases as a logarithmic function of the external potassium concentration in the culture medium. Similar dependence on the potassium gradient is observed when different levels of membrane potentials are imposed by constant current injection. The reversal potential for electrically evoked slow hyperpolarizations is -90 mV. A 10-fold increase in external potassium concentration causes a 60 mV shift of the reversal potential towards zero. Divalent cation ionophores (A23187 and X537A) can induce slow hyperpolarization responses in quiescent cells or permanent hyperpolarization in spontaneously active cells. The amplitude of the ionophore-induced hyperpolarizations is reduced by an increase in external potassium concentration in a manner consistent with data on slow hyperpolarization responses in the absence of ionophore. The calcium antagonist, verapamil, depresses the slow hyperpolarization responses at the concentration of 10(-5) M. It is suggested that the development of the hyperpolarizing response is due to a calcium-dependent potassium channel. The data support the assumption that spontaneous and artificially elicited slow hyperpolarization responses share a common calcium-dependent mechanism.     

Electrophysiology of phagocytic membranes: III. Evidence for a calcium-dependent potassium permeability change during slow hyperpolarizations of activated macrophages

The roles of potassium and calcium in the slow hyperpolarizations of membranes of activated macrophages are investigated using standard intracellular electrical recording techniques.The amplitude of spontaneous slow hyperpolarizations decreases as a logarithmic function of the external potassium concentration in the culture medium. Similar dependence on the potassium gradient is observed when different levels of membrane potentials are imposed by constant current injection. The reversal potential for electrically evoked slow hyperpolarizations is ?90 mV. A 10-fold increase in external potassium concentration causes a 60 mV shift of the reversal potential towards zero.Divalent cation ionophores (A23187 and X537A) can induce slow hyperpolarization responses in quiescent cells or permanent hyperpolarization in spontaneously active cells. The amplitude of the ionophore-induced hyperpolarizations is reduced by an increase in external potassium concentration in a manner consistent with data on slow hyperpolarization responses in the absence of ionophore.The calcium antagonist, verapamil, depresses the slow hyperpolarization responses at the concentration of 10^?5 M.It is suggested that the development of the hyperpolarizing response is due to a calcium-dependent potassium channel. The data support the assumption that spontaneous and artificially elicited slow hyperpolarization responses share a common calcium-dependent mechanism.     

Modifying actions of calcium ionophores on insulin release.

Beta-Cell-rich pancreatic islets were microdissected from noninbred ob/obmice and exposed to the calcium ionophores X-537A and A-23187. X-537A differed from A-23187 in being a potent insulin secretagogue at non-stimulating glucose concentrations. Both ionophores inhibited the stimulation of insulin release obtained after adding 20 mM glucose to the incubation medium. The latter observation is consistent with the idea of a reduced beta-cell function when the Ca-2+ in the functionally important intracellular pool (s) exceeds a certain concentration. The ionophore inhibition of the glucose-stimulated insulin release may at least in part result from decreased formation of cyclic AMP, since X-537A proved to be as effective as L-epinephrine in reducing the islet content of this nucleotide in the presence of a phosphodiesterase inhibitor. The secretagogic action of X-537A at a low glucose concentration persisted when different ions were omitted from the incubation medium and was actually considerably enhanced in the absence of extracellular Ca-2+. The insulin-releasing action of X-537A was neither influenced by 3-O-methyglucose nor by drugs blocking the alpha or beta-adrenergic receptor sites. Exposure of the pancreatic beta-cells to metabolic inhibitors in concentrations which significantly reduced the secretory response to glucose, potentiated stimulation of insulin release by X-537A, suggesting that this effect may in part be accounted for by intracellular dissolution of secretory granules.     

The effects of the ionophore A23187 on pattern formation in the alga Micrasterias

We have used the divalent cation ionophore A23187 to investigate the hypothesis that cytoplasmic localization of Ca2+ is responsible for localized growth in the alga Micrasterias. In a preliminary study we found that, of the major salts contained in the cell's medium, only CaCl2 was needed for normal development. In cells developing in the presence of A23187 and extracellular Ca2+, we postulated that the ionophore would induce a spatially uniform influx of Ca2+ that would overwhelm endogenous Ca2+ gradients. When developing cells were treated with A23187 and 2 mM CaCl2, we observed a delocalization of the cell's normal pattern of wall deposition. This effect was less pronounced when cells were exposed to A23187 and 2 mM MgCl2. These results support the hypothesis that localized regions of high Ca2+ concentration normally mediate localized expansion of tip-growing lobes in Micrasterias.     

Uridine uptake inhibition in Novikoff hepatoma cells by perturbants of intracellular Ca2+ and K+ levels

The rate of uptake of uridine into the acid-soluble fraction of Novikoff hepatoma cells is inhibited by low concentrations of the ionophores A23187 and gramicidin and other perturbants of intracellular cation levels. Inhibition of uridine uptake by A23187 is dependent on Ca2+ and is reduced by serum and high levels of Mg2+. The effectiveness of A23187 is dependent on the Ca2+/Mg2+ ratio rather than the absolute concentration of either ion. Inhibition of uridine uptake by gramicidin is not significantly affected by serum or divalent cations. Other effectors of monovalent cation flux such as ouabain and valinomycin also inhibit uridine uptake. These results indicate that net uptake of uridine may be influenced by intracellular levels of certain monovalent and divalent inorganic cations.     

The effect of ETH 1001 on ion fluxes across red blood cell membranes

The calcium selective ionophore, ETH 1001, and the divalent cation ionophore, A23187, promoted Ca2+ flux across RBC membranes under various experimental conditions. ETH 1001 did not promote the passive movement of Mg2+ whereas A23187 did. The results confirm the potential application of ETH 1001 as a Ca2+ selective ionophore for biological membranes.     

Control of blastema cell proliferation by possible interplay of calcium and cyclic nucleotides during newt limb regeneration

The effects of the divalent cation ionophore A23187, papaverine, and chlorpromazine on the mitotic index and cyclic nucleotide levels in newt limb regeneration blastemata (Notophthalmus viridescens) were assessed. The results of the experiments suggest that an intracellular increase in divalent cation (Ca2+) concentration results in elevated cGMP levels, suppressed cAMP levels, and a corresponding increase in blastema cell proliferation. The results also suggest that the converse conditions, namely, calcium efflux or inhibition of calmodulin activation (i.e., inhibition of Ca2+ binding), yields elevated cAMP levels, suppressed cGMP levels, and a corresponding decrease in blastema cell divisions.     

The dissociation of exocytosis and respiratory stimulation in leucocytes by ionophores.

By exploiting the unique characteristics of three ionophores, experimental conditions were found which permit the dissociation of respiratory stimulation from secretion in polymorphonuclear leucocytes. A marked stimulation of respiration was produced by ionophore X537A, which binds and transports both alkali-earth and alkali cations. The stimulatory activity of this ionophore was the same at either high or low Na+/K+ ratios in the medium and was virtually unaffected by extracellular Ca2+. A slight stimulation of oxygen consumption was also caused by the K+-selective ionophore valinomycin and by ionophore A23187, which complexes and transfers bivalent cations. Ionophore X537A and valinomycin were unable to stimulate selective release of granuleassociated beta-glucuronidase and gradually increased cell fragility, as monitored by increased leakage of lactate dehydrogenase. Ionophore A23187 slightly increased exocytosis of beta-glucuronidase. In a Mg2+-free medium, Ca2+, added simultaneously with ionophore A23187, greatly enhanced respiration and secretion of the granule enzyme. If Ca2+ was added a few minutes after the ionophore, exocytosis occurred, but no respiratory burst was observed. If the latter experiment was repeated in the presence of extracellular Mg2+, both secretion and respiration were stimulated. This effect was not produced by Mn2+ or Ba2+. It is proposed that Ca2+ is required for triggering selective secretion of granule enzymes from leucocytes is caused by an intracellular redistribution of cations, which may invovle Mg2+-dependent mechanisms.