Staining of Plasmodium yoelii-infected mouse erythrocytes with the fluorescent dye rhodamine 123

The cationic permeant fluorescent dye rhodamine 123 (R123) was used to stain Plasmodium yoelii-infected mouse erythrocytes. Fluorescence microscopic observations demonstrated that the parasite, but not the matrix of the infected erythrocyte, accumulated the dye. Differences in fluorescence intensity could not be found at the various developmental stages of the parasite; however, quantitation of the cell-associated dye revealed an increase in R123 uptake with parasite development. The retention of the parasite-associated dye, as measured by fluorescence microscopy and spectrophotometry after extraction of R123 with butanol, was markedly reduced by treatment of the infected erythrocytes with a proton ionophore, carbonyl cyanide m-chlorophenylhydrazone (CCCP), and an inhibitor of proton ATPase, dicyclohexylcarbodiimide (DCCD). These results indicate that the accumulation and retention of R123 in P. yoelii reflect the parasite membrane potential and suggest that the parasite plasma membrane has a membrane potential-generating proton pump.     

Le ionophore A23187

The acrosomic status of spermatozoa prepared for IVF has been evaluated by means of immunofluorescence test from Fenichel and Hsi using calcium A 23187 ionophore as inductor of acrosome reaction (AR). The spontaneous AR remains slight, even after 6 hour-incubation in Menezo B2 (6,8+2,7%). The response to ionophore, moderate before (11,2+9%), frankly increases after a 6h-capacitation (28,9+8,3%) in a group of 25 IVF couples (tubal indication, normal semen, positive fertilization). Nevertheless, it remains slight or null in 4 cases of unexplained repeated failure of fertilization. The response to ionophore A 23187 allows to explore the kinetics of capacitation of spermatozoa and their ability to perform AR. Its significance in terms of fecondance remains to be precised.     

Reaction of the cell center to exposure to the calcium ionophore A-23187

Calcium ionophore A23187, taken at a concentration of 0.1 microgram/ml, quickly uncouples mitochondria in PE culture cells in medium 199. The cell ultrastructure undergoes reversible changes (especially that of mitochondria): maximum changes occur 2 hours after the start of the treatment; in 8 hours they become less pronounced. The adaptation of cells does not involve the ionophore inactivation in the medium. 10 micrograms/ml of A23187 induces gradual but irreversible alterations. Microtubules in PE cells are not destroyed when incubated in medium 199 containing 10 micrograms/ml of A23187 and 11 mM Ca2+. The addition of 10 micrograms/ml ionophore to the normal 199 medium (1.26 mM Ca2+) results in the formation of electron dense bodies in the cell center 30 minutes after the start of incubation. These bodies disappear in the course of a subsequent incubation. The number of cells with primary cilia decreases. The percentage of centrioles located perpendicularly to the substrate increases 30 minutes following treatment with 0.1 microgram/ml A23187 in medium 199. 2 hours after the start of treatment with 0.1 microgram/ml ionophore no such changes are detected; an electron dense halo appears around the centriolar cylinders. 8 hours after the start of treatment the structure of the cell center does not differ from the normal one.     

The effect of calcium ionophore A23187 on the ATP level of human erythrocytes

Incubation of red cells at 37° with the ionophore A23187 results in a loss of ATP that is dependent on the concentrations of A23187 and Ca²⁺ in the medium. ATP hydrolysis is greatest at micromolar concentrations of Ca²⁺ and decreases as Ca²⁺ in the medium is raised to millimolar levels. The ATP depletion is due to stimulation of calcium ATPase by A23187-mediated Ca²⁺ influx into the cell. The biphasic nature of Ca²⁺-stimulated ATP depletion in whole cells reflects the activity of Ca²⁺-ATPase in membrane preparations at varying Ca²⁺ concentrations. The ionophore can be removed by washing the cells with plasma or bovine serum albumin-containing medium and the ATP levels restored to normal by reincubating with 5 mM adenosine for 1 hr.     

Effects of divalent cation ionophore A23187 on potassium permeability of rat erythrocytes.

A23187 transports calcium rapidly into rat erythrocytes, apparently by an electroneutral exchange for intracellular magnesium and protons. When red cells are incubated in the absence of any added divalent cations, A23187 transports internal magnesium out of the cells, in exchange for extracellular protons. Magnesium uptake into erythrocytes is produced by A23187, providing the extracellular concentration of this cation exceeds intracellular levels, and the ionophore also transports strontium, but not barium, into red cells. A23187 produces a rapid and extensive loss of intracellular potassium from erythrocytes during uptake of calcium or strontium, but not magnesium. When red cells are incubated in the absence of any exogenous divalent cations, A23187 still produces a potassium efflux and this is inhibited completely by small amounts of ethylene glycol bis(beta-aminoethyl ether)-N,N'-tetraacetic acid and restored by the addition of calcium in excess of the chelator. Although EDTA enhances the extent of magnesium release from erythrocytes incubated with A23187, it prevents the potassium efflux. Dipyridamole and 4-acetamid-4'-isothiocyano-stilbene-2,5'-disulfonic acid, which decrease chloride premeability of erythrocytes, inhibit the A23187-induced potassium loss from red cells. Rutamycin, peliomycin, venturicidin, and A23668B also inhibit potassium efflux from intact cells incubated with A23187, but this effect is not correlated with their abilities to inhibit various ATPases in red cell membrane preparations. It is concluded that A23187 does not transport potassium directly across the erythrocyte plasma membrane, but permits small amounts of endogenous calcium to interact with some membrane component to enhance potassium permeability of the cell.     

The effects of ionophore A23187 on erythrocytes relationship of ATP and 2,3-diphosphoglycerate to calcium-binding capacity

The divalent cation ionophore, A23187, was employed as a means to load fresh human erythrocytes with calcium, and the capacity for accumulation was characterized. Erythrocytes exposed to A23187 in calcium-containing media rapidly accumulated calcium in millimolar quantities. The final cellular concentration was dependent upon medium calcium concentration and the size of the cellular organophosphate pool. When ATP and 2,3-diphosphoglycerate contents were depleted or repleted, the cellular calcium content changed proportionally. Calcium loading of fresh erythrocytes produced no discernible change in the cellular concentrations of ATP or 2,3-diphosphoglycerate. Calcium accumulation was also accompanied by loss of cellular potassium and H₂O, deterioration of cell filterability, and spheroechinocytic transformation.     

Calcium and ionophore A23187 induce the sickle cell membrane phosphorylation pattern in normal erythrocytes

Pre-treatment of normal erythrocytes with micromolar Ca²⁺ and ionophore A23187 induces abnormal phosphorylation of membrane polypeptides, as determined by labeling with exogenous ³²P_i. The Ca²⁺-induced effects, which include increased incorporation of ³²P into acid-stable linkages and increased labeling in the Band 3 and 4.5–4.9 regions of SDS gels, are similar to those seen in untreated sickle erythrocytes. Part of the abnormal phosphorylation of sickle cells may be caused by their elevated intracellular Ca²⁺ levels.     

Effect of ionophore A23187 upon membrane function and ion movement in human and toad erythrocytes

Summary Addition of 0.1–0.3 m A23187, a divalent cation ionophore, to human erythrocytes suspended in a 1.0mm ⁴⁵Ca²⁺-containing buffer results in a small ( two fold) increase in [Ca²⁺] _i , a significant decrease in osmotic fragility, and a decrease in intracellular K⁺ (100 mmoles/liter of cells to 70 mmoles/liter cells) without significant alteration of intracellular [Na⁺]. This decrease in [K⁺] _i is associated with a significant decrease in packed cell volume and correlates directly with the observed alteration is osmotic fragility. Increasing extracellular K⁺ to 125mm prevents the A23187-induced changes in osmotic fragility, K⁺ content and cell volume, but does not prevent the ionophore-induced uptake of⁴⁵Ca²⁺. Addition of 0.1–0.3 m A23187 to toad erythrocytes leads to an increase in⁴⁵Ca²⁺ uptake comparable to that observed in human erythrocytes, but does not alter osmotic fragility, cell volume or K⁺ content. Higher concentrations of ionophore (3.0–10.0 m) cause a 30- to 50-fold increase in⁴⁵Ca²⁺ uptake and concomitant change in K⁺ content, cell volume and osmotic fragility. These changes in cell properties can be prevented by increasing extracellular [K⁺] to 90mm. The difference in sensitivity of the two cell types to A23187 is attributed to the presence of additional intracellular calcium pools within toad erythrocytes that prevent an increase in cytoplasmic Ca²⁺ until Ca²⁺ uptake is increased substantially at the higher concentrations of A23187.     

Calcium-induced oscillations in K+ conductance and membrane potential of human erythrocytes mediated by the ionophore A23187

The time-dependence of ionophore A23187-induced changes in the conductance of the Ca2+-sensitive K+ channels of the human red cell has been monitored with ion-specific electrodes. The membrane potential was reflected in CCCP-mediated pH changes in a buffer-free extracellular medium, and changes in extracellular K+ activity and electrode potential of an extracellular Ca2+-electrode were recorded. Within a narrow range of ionophore-mediated Ca2+ influx, the above-mentioned parameters were found to oscillate when ionophore was added to a suspension of glucose-fed cells. The period of oscillation was about 2 min/cycle depending on ionophore concentration, and the amplitude of hyperpolarization was about 60 mV, corresponding to a maximal gK+ of the same magnitude as gCl-. Without CCCP present no oscillation in K+ conductance was observed. The Ca2+ affinity for the opening process was in the micromolar range. The closing of the K+ channels was a spontaneous process in that the depolarization was well under way before the Ca2+-ATPase-mediated Ca2+ net efflux started. Below the Ca2+ influx range for oscillations, no response was observed for up to 20 min after the addition of ionophore. Above the upper limit, a permanent hyperpolarization resulted with an extracellular K+ activity increasing monotonically as a function of time. In experiments with ATP-depleted cells, responses of the latter type ensued at all ionophore concentrations above the lower limit. Addition of surplus EGTA to suspensions of hyperpolarized cells restores the normal membrane potential in the case of glucose-fed cells, whereas the K+-channels in ATP-depleted cells remained open.     

Isolation of inner cell masses from mouse blastocysts by immunosurgery or exposure to the calcium ionophore A23187.

Two techniques have been evaluated for their use in routinely isolating inner cell masses from mouse blastocysts by destroying the trophectoderm. The most efficient method of immunosurgery was a 15-min incubation in a 1:50 dilution of rabbit anti-mouse spleen antiserum followed by a 30--60-min incubation in guinea pig complement (1:10). Alternatively, inner cell masses were isolated by incubating blastocysts in 10(-5) M calcium ionophore A23187 in medium devoid of calcium and magnesium ions. Inner cell masses re-exposed to immunosurgery or the ionophore were less susceptible to lysis than the trophectoderm had been. The presence of the zona pellucida reduced trophectoderm lysis by immunosurgery in antiserum dilutions greater than 1:100, but had no effect when in the presence of ionophore. Inner cell masses were consistently isolated from expanded blastocysts which had been collected 78 h after ovulation and cultured in vitro for 24 h before exposure to ionophore or immunosurgery, whereas blastocysts which had developed for the full 102 h in vivo were frequently unaffected.     

Production of 1,2-diacylglycerol and phosphatidate in human erythrocytes treated with calcium ions and ionophore A23187.

1. When the ionophore A23187 and Ca2+ were added to normal human erythrocytes, the incorporation of 32P into phosphatidate was enhanced within 1 min, but there was only slight labelling of other phospholipids. 2. Labelling of phosphatidate in these cells did not continue to increase after about 20min at 37 degrees C; by this time, radioactivity in phosphatidate was about ten times higher inionophore A23187-treated cells than in controls. A net synthesis of phosphatidate was measured in response to the increase in intracellular Ca2+ concentration; the content of this phospholipid in the cell was increased by approximately 50%. 3. In the presence of 2.5 mM-Ca2+ a maximum effect was seen with about 0.5 mug of ionophore/ml. 4. The concentration of Ca2+ giving half-maximal labelling of phosphatidate in the presence of 10 mug of ionophore A23187/ml was about 10 muM. 5. A rapid decrease of ATP content in the cell occurred in ionophore-treated cells. 6. Labelling of phosphatidate appeared to be secondary to the production of 1,2-diacylglycerol in the cells; accumulation of 1,2-diacylglycerol was only seen after about 15 min. After 60 min, the 1,2-diacylglycerol content of the cells was five to seven times that of untreated control cells. 7. The change in the shape of erythrocytes treated with Ca2+ and ionophore appeared to be related to accumulation of 1,2-diacylglycerol. 8. The source of 1,2-diacylglycerol has not been definitely identified, but its fatty acid compositon was similar to that of phosphatidylcholine. However, it has an unusually high content of hexadecenoic acid, a fatty acid not common in the major erythrocyte phospholipids. 9. Accumulation of 1,2-diacyglycerol also occurred in energy-starved cells, even in the absence of calcium; in this case it appeared to be produced by phosphatidate breakdown.     

Calcium-dependent irreversible effect of ionophore A23187 on melanophores

The calcium ionophore, A231187, induces a Ca2+ -dependent movement (dispersion) of melanosomes within skin melanophores of the lizard, Anolis carolinensis, in vitro. The effects of A23187 are irreversible, since after repeated rinsing of the skins in the absence of the ionophore they will always darken in Ringer containing Ca2+ but will immediately lighten when transferred to Ca2+ -free Ringer. These results suggest that the ionophore is irreversibly localized to the melanophore membrane and that its melanosome-dispersing effect is continuously dependent upon extracellular calcium.     

Calcium-dependent interactions of an ionophore A23187 with calmodulin

We found that ionophore A23187 interacted reversibly with calmodulin (CaM), in a calcium-dependent fashion. It was found that A23187 interacts selectively with CaM, among calcium binding proteins (such as troponin C and S-100 protein) and other proteins. However, apparently differing from W-7, A23187 did not suppress CaM-dependent enzyme activity such as myosin light chain kinase and Ca2+-dependent cyclic nucleotide phosphodiesterase. Our observations suggest that there are novel calcium-dependent regions of CaM which can be monitored using ionophore A23187 and may not be related to enzyme activation.     

Dual action of ionophore A23187 on intact chloroplasts

1. Ionophore A23187 induces uncoupling of potassium ferricyanide-dependent O₂ evolution by envelope-free chloroplasts and oxaloacetate-dependent O₂ evolution by intact chloroplasts. The half maximal concentration ($\text{C}{}_{\mathrm{<mtext>1</mtext><mtext>2</mtext>}}$) for stimulation of oxygen evolution in both cases is approximately 4 μM · 100 μg chlorophyll · ml^?1.2. Ionophore A23187 also induces inhibition of CO₂ and 3-phosphoglycerate-dependent O₂ evolution by intact chloroplasts in the presence of 3 mM MgCl₂. The half maximal concentrations ($\text{C}{}_{\mathrm{<mtext>1</mtext><mtext>2</mtext>}}$) for inhibition of O₂ evolution are 3 μM and 5 μM respectively · 100 μg^?1 chlorophyll · ml^?1.3. A very high concentration of ionophore A23187 (10 μM · 20 μg^?1 chlorophyll · ml^?1) plus 0.1 mM EDTA lowers the fluorescence yield of intact chloroplasts suspended in a cation-free medium in the presence of 3-(3,4-dichlorophenyl)-1,1-dimethylurea, indicating loss of divalent cation from the diffuse double layers of the thylakoid membranes.4. These results are discussed in relation to ionophore A23187-induced divalent cation/proton exchange at both the thylakoid and the envelope membranes of intact chloroplasts.     

Solution conformation of the ionophore A23187 and its magnesium salt

The analysis of proton nmr spectra at 300 MHz in C₆D₆ and in CDCl₃ of the divalent cation ionophore A23187 and its magnesium salt are reported and discussed in terms of configurational and conformational behaviour. The conformation of the free acid in solution was found to be almost identical to that described previously (M. O. Chaney, P. V. Demarco, N. D. Jones, and J. L. Occolowitz, J. Amer. Chem. Soc.96, 1932 (1974)) for the solid state, except that in apolar solvents no head-to-tail interaction is observed, in that free rotation around certain bonds (e.g., C₁₅–C₁₉, structures 1 and 2) substantially prevents such quasi-cyclic forms. For the conformation of the magnesium salt, two monovalent units aggregate around the divalent cation, the two substructures displaying equivalent atoms in each of their corresponding positions. A compact sphere-like form having a C₂ axis and a cavity of about 3.5 Å is proposed, the cation being held in the middle by two carboxylate ions, carbonyl and N-benzoxazole units as the ligands. These conclusions result from consideration of the extracted parameters in the proton nmr spectrum and from model building. Thus, the most probable form of the Mg-salt in solution corresponds almost exactly to that of the Ca-salt in the solid state, as very recently revealed by the X-ray analysis of M. O. Chaney, N. D. Jones, and M. Debono (J. Antibiot, in press).