Cation pretreatment effects on nitrate uptake, xylem exudate, and malate levels in wheat seedlings

Week-old wheat seedlings absorbed at least 40% NO₃⁻ from NaNO₃ when preloaded with K⁺ than when preloaded with Na⁺ or Ca²⁺. Cultures of Triticum vulgare L. cv. Arthur were grown for 5 days on 0.2 mm CaSO₄, pretreated for 48 hours with either 1 mm CaSO₄, K₂SO₄, or Na₂SO₄, and then transferred to 1 mm NaNO₃. All solutions contained 0.2 mm CaSO₄. Shoots of K⁺-preloaded plants accumulated three times more NO₃⁻ than shoots of the other two treatments. Initially, the K⁺-preloaded plants contained 10-fold more malate than either Na⁺- or Ca²⁺-preloaded seedlings. During the 48-hour treatment with NaNO₃, malate in both roots and shoots of the K⁺-preloaded seedlings decreased. Seedlings preloaded with K⁺ reduced 25% more NO₃⁻ than those preloaded with either Na⁺ or Ca²⁺. These experiments indicate that K⁺ enhanced NO₃⁻ uptake and reduction even though the absorption of K⁺ and NO₃⁻ were separated in time. Xylem exudate of K⁺-pretreated plants contained roughly equivalent concentrations of K⁺ and NO₃⁻, but exudate from Na⁺ and Ca²⁺-pretreated plants contained two to four times more NO₃⁻ than K⁺. Therefore K⁺ is not an obligatory counterion for NO₃⁻ transport in xylem.     

Fluxes of Ca2+, Sr2+ and Mg2+ in synaptosomes.

Synaptosomes isolated from sheep brain cortex accumulate Ca²⁺, Sr²⁺ and Mg²⁺ when incubated in isosmotic sucrose media containing 5 mM of either of these cations. The maximal levels of cations retained per mg of protein are 100 nmol of Ca²⁺, 85 nmol of Mg²⁺ and 80 nmol of Sr²⁺. The loss of Ca²⁺ or Sr²⁺ from the preloaded synaptosomes is increased by monovalent cations in the following order: Na⁺> K⁺ > Li⁺> choline, whereas for the loss of Mg²⁺ this order is different: K⁺ > Na⁺ > Li ～ choline. The efflux of Ca²⁺ or Sr²⁺ induced by monovalent cations decreases as the temperature is lowered and it is nearly abolished at 0°C, whereas the efflux of Mg²⁺ is much less influenced by temperature. The results suggest that the mechanism of exchange of Ca²⁺ for Na⁺ in synaptosomes operates similarly for Sr²⁺, but not for Mg²⁺.     

Adaptation of barley roots to low oxygen supply and its relation to potassium and sodium uptake

The uptake of Na⁺ and K⁺ by barley seedlings grown on aerated or non-aerated solutions was studied. Plants growing in culture solution took up K⁺ with high selectivity whether the solution was aerated or not. Roots of plants grown on aerated CaSO₄ and transferred to a solution of KCl and NaCl had a lower preference for K⁺ than roots of plants grown on non-aerated CaSO₄. Both kinds of low-salt roots were much less able to discriminate between K⁺ and Na⁺ than high-salt roots grown on a culture solution. The different levels of K⁺ selectivity are suggested to be related to H⁺ release from the tissue.     

Rapid calcium exchange for protons and potassium in cell walls of Chara

Net fluxes of Ca²⁺, H⁺ and K⁺ were measured from intact Chara australis cells and from isolated cell walls, using ion-selective microelectrodes. In both systems, a stimulation in Ca²⁺ efflux (up to 100 nmol m^?2 s^?1, from an influx of ～40 nmol m^?2 s^?1) was detected as the H⁺ or K⁺ concentration was progressively increased in the bathing solution (pH 7.0 to 4.6 or K⁺ 0.2 to 10mol m^?3, respectively). A Ca²⁺ influx of similar size occurred following the reverse changes. These fluxes decayed exponentially with a time constant of about 10 min. The threshold pH for Ca²⁺ efflux (pH 5.2) is similar to a reported pH threshold for acid-induced wall extensibility in a closely related characean species. Application of NH₄⁺ to intact cells caused prolonged H⁺ efflux and also transient Ca²⁺ efflux. We attribute all these net Ca²⁺ fluxes to exchange in the wall with H⁺ or K⁺. A theoretical treatment of the cell wall ion exchanges, using the ‘weak acid Donnan Manning’ (WADM) model, is given and it agrees well with the data. The role of Ca²⁺ in the cell wall and the effect of Ca²⁺ exchanges on the measured fluxes of other ions, including bathing medium acidification by H⁺ efflux, are discussed.     

Inhibition of 86Rb+ and 22Na+ efflux of Ehrlich lettré tumor cells by Ca2+.

The mechanism of the protective effect of Ca²⁺ on cellular K⁺ content was studied by examination of the effect of Ca²⁺ on efflux of the K⁺ analog, ⁸⁶Rb⁺, from preloaded cells with the use of compounds which interfere with monovalent cation movements. Ca²⁺ decreased ⁸⁶Rb⁺ efflux to the same extent in the presence and absence of ouabain, suggesting that Ca²⁺ did not alter the activity of the (Na⁺ + K⁺)-adenosine triphosphatase pump. Ca²⁺ exerted a similar protective effect in the presence of furosemide, an inhibitor of K⁺-K⁺ exchange, indicative that Ca²⁺ was not inhibiting this pathway. Since Ca²⁺ did not influence these pathways, it is concluded that Ca²⁺ exerts its primary effect by slowing passive diffusion. In support of this, Ca²⁺ also slowed ²²Na⁺ efflux. In addition, ethanol-induced leakage of ⁸⁶Rb⁺ was reversed by extracellular Ca²⁺, suggestive of a Ca²⁺-membrane phospholipid interaction.     

Activation by calcium of membrane channels for potassium in exocrine gland cells

In the rat parotid salivary gland, fluid secretion is regulated by alterations in fluxes of monovalent ions. , stimulation of muscarinic, α-adrenergic or substance P receptors provokes a biphasic increase in membrane permeability to K⁺ which can be conveniently assayed as efflux of ⁸⁶Rb. The increased ⁸⁶Rb flux is thought to arise in response to a receptor mediated elevation in [Ca²⁺]_i which activates Ca²⁺-activated K⁺-channels. The biphasic nature of the response is presumably due to a biphasic mode of Ca²⁺ mobilization by secretagogues; a transient response reflects release of a finite pool of Ca from an intracellular store while a more sustained phase results from Ca entry through receptor operated Ca channels or gates. Calcium also mediates an increased Na⁺ entry which in turn activates the Na⁺, K⁺-pump. The mechanism involved in the regulation of monovalent ion channels by Ca²⁺ is not understood.     

Ionic and osmotic components of salt stress specifically modulate net ion fluxes from bean leaf mesophyll

Ionic mechanisms of salt stress perception were investigated by non‐invasive measurements of net H⁺, K⁺, Ca²⁺, Na⁺, and Cl^? fluxes from leaf mesophyll of broad bean (Vicia faba L.) plants using vibrating ion‐selective microelectrodes (the MIFE technique). Treatment with 90 m M NaCl led to a significant increase in the net K⁺ efflux and enhanced activity of the plasma membrane H⁺‐pump. Both these events were effectively prevented by high (10 m M ) Ca²⁺ concentrations in the bath. At the same time, no significant difference in the net Na⁺ flux has been found between low‐ and high‐calcium treatments. It is likely that plasma membrane K⁺ and H⁺ transporters, but not the VIC channels, play the key role in the amelioration of negative salt effects by Ca²⁺ in the bean mesophyll. Experiments with isotonic mannitol application showed that cell ionic responses to hyperosmotic treatment are highly stress‐specific. The most striking difference in response was shown by K⁺ fluxes, which varied from an increased net K⁺ efflux (NaCl treatment) to a net K⁺ influx (mannitol treatment). It is concluded that different ionic mechanisms are involved in the perception of the ‘ionic’ and ‘osmotic’ components of salt stress.     

Involvement of cation channels and NH4+-sensitive K+ transporters in Na+ uptake by cowpea roots under salinity

Na⁺ accumulation was investigated in the roots of 11-d-old cowpea [Vigna unguiculata (L.) Walp.] plants. The relative contribution of different membrane transporters on Na⁺ uptake was estimated by applying Ca²⁺, K⁺, NH₄ ⁺, and pharmacological inhibitors. Na⁺ accumulation into the root symplast was decreased by half in the presence of 1 mM Ca²⁺ and it was almost abolished by 100 mM K⁺. The inhibitory effect of external NH⁴⁺ on Na⁺ accumulation was more pronounced in the roots of NH₄ ⁺-free growing plants. Na⁺ accumulation was reduced about 73 % by 0.1 mM flufenamate and it was almost blocked by 2 mM quinine. In addition, 20 mM tetraethylammonium and 1.0 mM Cs⁺ decreased Na⁺ accumulation by 28 and 30 %, respectively. These results evidenced that low-affinity Na⁺ uptake by cowpea roots depends on Ca²⁺-sensitive and Ca²⁺-insensitive pathways. The Ca²⁺-sensitive pathway is probably mediated by nonselective cation channels and the Ca²⁺-insensitive one may involve K⁺ channels and to a lesser extent NH₄ ⁺-sensitive K⁺ transporters.     

Cation transport systems in mitochondria: Na+ and K+ uniports and exchangers

It is now well established that mitochondria contain three antiporters that transport monovalent cations. A latent, allosterically regulated K⁺/H⁺ antiport appears to serve as a cation-extruding device that helps maintain mitochondrial volume homeostasis. An apparently unregulated Na⁺/H⁺ antiport keeps matrix [Na⁺] low and the Na⁺-gradient equal to the H⁺-gradient. A Na⁺/Ca²⁺ antiport provides a Ca²⁺-extruding mechanism that permits the mitochondrion to regulate matrix [Ca²⁺] by balancing Ca²⁺ efflux against influx on the Ca²⁺-uniport. All three antiports have well-defined physiological roles and their molecular properties and regulatory features are now being determined. Mitochondria also contain monovalent cation uniports, such as the recently described ATP- and glibenclamide-sensitive K⁺ channel and ruthenium red-sensitive uniports for Na⁺ and K⁺. A physiological role of such uniports has not been established and their properties are just beginning to be defined.     

Herbivore exposure alters ion fluxes and improves salt tolerance in a desert shrub

Plants have evolved complex mechanisms that allow them to withstand multiple environmental stresses, including biotic and abiotic stresses. Here, we investigated the interaction between herbivore exposure and salt stress of Ammopiptanthus nanus, a desert shrub. We found that jasmonic acid (JA) was involved in plant responses to both herbivore attack and salt stress, leading to an increased NaCl stress tolerance for herbivore-pretreated plants and increase in K⁺/Na⁺ ratio in roots. Further evidence revealed the mechanism by which herbivore improved plant NaCl tolerance. Herbivore pretreatment reduced K⁺ efflux and increased Na⁺ efflux in plants subjected to long-term, short-term, or transient NaCl stress. Moreover, herbivore pretreatment promoted H⁺ efflux by increasing plasma membrane H⁺-adenosine triphosphate (ATP)ase activity. This H⁺ efflux creates a transmembrane proton motive force that drives the Na⁺/H⁺ antiporter to expel excess Na⁺ into the external medium. In addition, high cytosolic Ca²⁺ was observed in the roots of herbivore-treated plants exposed to NaCl, and this effect may be regulated by H⁺-ATPase. Taken together, herbivore exposure enhance s A. nanus tolerance to salt stress by activating the JA-signalling pathway, increasing plasma membrane H ⁺ - ATPase activity, promoting cytosolic Ca²⁺ accumulation, and then restricting K⁺ leakage and reducing Na⁺ accumulation in the cytosol.     

Wirkung von K+ auf die Fluxe und den Transport von Na+ in Gerstenwurzeln,K+-stimulierter Na+-Efflux in der Wurzelrinde

Summary Barley roots grown on a nutrient solution containing 1 mM Na⁺ but no K⁺ are capable of a considerable Na⁺ transport via the symplasm of the root and the xylem vessels. K⁺ added to the medium surrounding the root cortex severely inhibits this transport after a lag period at a high rate constant (Fig. 3).It is likely that the fluxes of Na⁺ are changed drastically during this transition from low to high K⁺ status. Although originally limited to steady state fluxes, the extended method of efflux analysis for excised roots (Pitman, 1971) has been applied to the non-steady fluxes which occur upon the addition of K⁺ to the roots. It is shown that besides other changes the efflux of ²²Na⁺ through the cortex of barley roots is stimulated instantaneously (Fig. 5) by the addition of K⁺ and presumably by an influx of K⁺ ions. From this a transient, K⁺-stimulated Na⁺ efflux at the plasmalemma of the cortical cells can be estimated. It amounts to 10.9 moles/g fw · h compared to the control efflux of 3.3 moles/g fw · h without K⁺.The stimulated efflux is attributed to a Na⁺ efflux pump at the plasmalemma and is thus related to the K-Na-selectivity of barley plants. The inhibition of the Na⁺ transport by K⁺ is probably a consequence of this increased efflux of Na⁺ from the symplasm through the root cortex.     

Sodium and potassium fluxes and compartmentation in roots of atriplex and oat

K⁺ and Na⁺ fluxes and ion content have been studied in roots of Atriplex nummularia Lindl. and Avena sativa L. cv Goodfield grown in 3 millimolar K⁺ with or without 3 or 50 millimolar NaCl. Compartmental analysis was carried out with entire root systems under steady-state conditions.

Increasing ambient Na⁺ concentrations from 0 to 50 millimolar altered K⁺, in Atriplex, as follows: slightly decreased the cytoplasmic content (Q_c), the vacuolar content (Q_v), and the plasma membrane influx and efflux. Xylem transport for K⁺ decreased by 63% in Atriplex. For oat roots, similar increases in Na⁺ altered K⁺ parameters as follows: plasma membrane influx and efflux decreased by about 80%. Q_c decreased by 65%, and xylem transport decreased by 91%. No change, however, was observed in Q_v for K⁺. Increasing ambient Na⁺ resulted in higher (3 to 5-fold) Na⁺ fluxes across the plasma membrane and in Q_c of both species. In Atriplex, Na⁺ fluxes across the tonoplast and Q_v increased as external Na⁺ was increased. In oat, however, no significant change was observed in Na⁺ flux across the tonoplast or in Q_v as external Na⁺ was increased. In oat roots, Na⁺ reduced K⁺ uptake markedly; in Atriplex, this was not as pronounced. However, even at high Na⁺ levels, the influx transport system at the plasma membrane of both species preferred K⁺ over Na⁺.

Based upon the Ussing-Teorell equation, it was concluded that active inward transport of K⁺ occurred across the plasma membrane, and passive movement of K⁺ occurred across the tonoplast in both species. Na⁺, in oat roots, was actively pumped out of the cytoplasm to the exterior, whereas, in Atriplex, Na⁺ was passively distributed between the free space, cytoplasm, and vacuole.

     

Requirement of monovalent cations in the acrosome reaction of guinea pig spermatozoa

The majority of the spermatozoa precapacitated in Ca²⁺-free medium underwent the acrosome raction rapidly when they were transferred to Ca²⁺-containing medium. The presence of Na⁺ and Ca²⁺ in the medium was essential for the acrosome reaction. The vast majority of spermatozoa failed to undergo the reaction in Ca²⁺ medium lacking monovalent ions, although they remained motile. At the concentration of 140 mM, Na⁺, K⁺, Rb⁺, and Cs⁺ all supported the reaction at the maximum level, but at 50 mM the latter three ions were not as effective as Na⁺. Li⁺ was least effective in supporting the reaction. Virtually no acrosome reactions took place when precapacitated spermatozoa were first exposed to Na⁺ medium (no Ca²⁺) and then to Ca²⁺ medium (no Na⁺). On the other hand, a considerably higher proportion of spermatozoa acrosome reacted when they were exposed to these media in the reverse order. The most efficient acrosome reactions took place when the medium contained both a monovalent ion (Na⁺) and Ca²⁺ simultaneously. Possible mechanisms by which monovalent and divalent cations participate in the acrosome reaction are discussed.     

Improved measurements of Na+ fluxes in plants using calixarene-based microelectrodes

Ion-selective microelectrodes are a powerful tool in studying adaptive responses of plant cells and tissues to various abiotic stresses. However, application of this technique in Na⁺ flux measurements was limited due to poor selectivity for Na⁺ ions of commercially available Na⁺ cocktails. Often, these cocktails cannot discriminate between Na⁺ and other interfering ions such as K⁺ and Ca²⁺, leading to inaccurate measurements of Na⁺ concentration and, consequently, inaccurate Na⁺ flux calculations. To overcome this problem, three Na⁺-selective cocktail mixtures were prepared using tetramethoxyethyl ester derivative of p-t-butyl calix[4]arene. These cocktail mixtures were compared with commercially available ETH 227-based Na⁺ cocktail for selectivity for Na⁺ ions over other ions (particularly K⁺ and Ca²⁺). Among the three calixarene-based Na⁺ cocktails tested, cocktail 2 [in % w/w: Na⁺ ionophore (4-tert-butylcalix[4]arene-tetra acetic acid tetraethyl ester) 3.5, the plasticizer (2-nitrophenyl octyl ether) 95.9 and lipophilic anion (potassium tetrakis (4-chlorophenyl) borate) 0.6] showed the best selectivity for Na⁺ ions over K⁺ and Ca²⁺ ions and was highly stable over time (up to 10 h). Na⁺ flux measurements under a wide range of NaCl concentrations (25-150 mM) using Na⁺ cocktail 2 established a clear dose-response relationship between severity of salt stress and magnitude of Na⁺ influx at the distal elongation and mature zones of Arabidopsis thaliana roots. Furthermore, Na⁺ cocktail 2 was compared with commercially available ETH 227-based Na⁺ cocktail by measuring Na⁺ fluxes at the two Arabidopsis root zones in response to 100 mM NaCl treatment. With calixarene-based Na⁺ cocktail 2, a large decreasing Na⁺ influx (0-15 min) followed by small Na⁺ influx (15-45 min) was measured, whereas with ETH-based Na⁺ cocktail Na⁺ influx was short-lived (1-3 min) and was followed by Na⁺ efflux (3-45 min) that might have been due to K⁺ and Ca²⁺ efflux measured together with Na⁺ influx. In conclusion, Na⁺-selective calixarene-based microelectrodes have excellent potential to be used in real-time Na⁺ flux measurements in plants.     

Influx of na, k, and ca into roots of salt-stressed cotton seedlings : effects of supplemental ca

High Na⁺ concentrations may disrupt K⁺ and Ca²⁺ transport and interfere with growth of many plant species, cotton (Gossypium hirsutum L.) included. Elevated Ca²⁺ levels often counteract these consequences of salinity. The effect of supplemental Ca²⁺ on influx of Ca²⁺, K⁺, and Na⁺ in roots of intact, salt-stressed cotton seedlings was therefore investigated. Eight-day-old seedlings were exposed to treatments ranging from 0 to 250 millimolar NaCl in the presence of nutrient solutions containing 0.4 or 10 millimolar Ca²⁺. Sodium influx increased proportionally to increasing salinity. At high external Ca²⁺, Na⁺ influx was less than at low Ca²⁺. Calcium influx was complex and exhibited two different responses to salinity. At low salt concentrations, influx decreased curvilinearly with increasing salt concentration. At 150 to 250 millimolar NaCl, ⁴⁵Ca²⁺ influx increased in proportion to salt concentrations, especially with high Ca²⁺. Potassium influx declined significantly with increasing salinity, but was unaffected by external Ca²⁺. The rate of K⁺ uptake was dependent upon root weight, although influx was normalized for root weight. We conclude that the protection of root growth from salt stress by supplemental Ca²⁺ is related to improved Ca-status and maintenance of K⁺/Na⁺ selectivity.     

Glutamate activates cation currents in the plasma membrane of<Emphasis Type="Italic"> Arabidopsis</Emphasis> root cells

The effect of glutamate on plant plasma membrane cation transport was studied in roots of Arabidopsis thaliana (L.) Heynh. Patch-clamp experiments using root protoplasts, ²²Na⁺ unidirectional fluxes into intact roots and measurements of cytosolic Ca²⁺ activity using plants expressing cytosolically-targeted aequorin in specific cell types were carried out. It was demonstrated that low-millimolar concentrations of glutamate activate within seconds both Na⁺ and Ca²⁺ currents in patch-clamped protoplasts derived from roots. The probability of observing glutamate-activated currents increased with increasing glutamate concentration (up to 29% at 3 mM); half-maximal activation was seen at 0.2–0.5 mM glutamate. Glutamate-activated currents were voltage-insensitive, instantaneous (completely activated within 2–3 ms of a change in voltage) and non-selective for monovalent cations (Na⁺, Cs⁺ and K⁺). They also allowed the permeation of Ca²⁺. Half-maximal Na⁺ currents occurred at 20–30 mM Na⁺. Glutamate-activated currents were sensitive to non-specific blockers of cation channels (quinine, La³⁺, Gd³⁺). Although low-millimolar concentrations of glutamate did not usually stimulate unidirectional influx of ²²Na⁺ into intact roots, they reliably caused an increase in cytosolic Ca²⁺ activity in protoplasts isolated from the roots of aequorin-transformed Arabidopsis plants. The response of cytosolic Ca²⁺ activity revealed a two-phase development, with a rapid large transient increase (lasting minutes) and a prolonged subsequent stage (lasting hours). Use of plants expressing aequorin in specific cell types within the root suggested that the cell types most sensitive to glutamate were in the mature epidermis and cortex. The functional significance of these glutamate-activated currents for both cation uptake into plants and cell signaling remains the subject of speculation, requiring more knowledge about the dynamics of apoplastic glutamate in plants.Abbreviations GLR Gene in plants encoding glutamate receptor-like protein - iGluRs Ionotropic glutamate receptors     

Unidirectional Na(+) and Ca (2+) fluxes in two euryhaline teleost fishes, Fundulus heteroclitus and Oncorhynchus mykiss, acutely submitted to a progressive salinity increase

Na⁺ and Ca²⁺ regulation were compared in two euryhaline species, killifish (normally estuarine-resident) and rainbow trout (normally freshwater-resident) during an incremental salinity increase. Whole-body unidirectional fluxes of Na⁺ and Ca²⁺, whole body Na⁺ and Ca²⁺, and plasma concentrations (trout only), were measured over 1-h periods throughout a total 6-h protocol of increasing salinity meant to simulate a natural tidal flow. Killifish exhibited significant increases in both Na⁺ influx and efflux rates, with efflux slightly lagging behind efflux up to 60% SW, but net Na⁺ balance was restored by the time killifish reached 100% SW. Whole body Na⁺ did not change, in agreement with the capacity of this species to tolerate daily salinity fluctuations in its natural habitat. In contrast, rainbow trout experienced a dramatic increase in Na⁺ influx (50-fold relative to FW values), but not Na⁺ efflux between 40 and 60% SW, resulting in a large net loading of Na⁺ at higher salinities (60–100% SW), and increases in plasma Na⁺ and whole body Na⁺ at 100% SW. Killifish were in negative Ca²⁺ balance at all salinities, whereas trout were in positive Ca²⁺ balance throughout. Ca²⁺ influx rate increased two- to threefold in killifish at 80 and 100% SW, but there were no concomitant changes in Ca²⁺ efflux. Ca²⁺ flux rates were affected to a larger degree in trout, with twofold increases in Ca²⁺ influx at 40% SW and sevenfold increases at 100% SW. Again, there was no change in Ca²⁺ efflux with salinity, so plasma Ca²⁺ concentration increased in 100% SW. As the killifish is regularly submitted to increased salinity in its natural environment, it is able to rapidly activate changes in unidirectional fluxes in order to ensure ionic homeostasis, in contrast to the trout.     

Chemotactic factors activate differentiable permeation pathways for sodium and calcium in rabbit neutrophils. Effect of amiloride

The effects of the potassium-sparing diuretic amiloride on the chemotactic factor stimulated Na⁺ and Ca²⁺ fluxes in rabbit peritoneal neutrophils were investigated. Amiloride inhibits in a dose-dependent fashion the f-Met-Leu-Phe stimulated Na⁺ uptake (IC₅₀:1.1 × 10^?6 M) but did not affect the stimulated rate of Na⁺ efflux from preloaded cells. Amiloride did not inhibit the f-Met-Leu-Phe stimulated Ca²⁺ uptake. These results allow, for the first time, the differentiation between the Na⁺ and the Ca²⁺ permeation pathways and the investigation into the functional role of the stimulated Na⁺ uptake.     

Ionophore-induced efflux of sodium and potassium ions from sea urchin eggs

The efflux of K⁺ and Na⁺ from sea urchin eggs during Ca²⁺ ionophore A23187-induced parthenogenesis was studied in a K⁺ and Na⁺-free artificial seawater using extracellular ion-specific electrodes. We have probed this model system with monovalent cation-specific ionophores to determine if they affect K⁺ efflux in the unfertilized egg and whether any changes in ionophore sensitivity are observed during egg activation. In 500 mM choline chloride, 10 mM CaCl₂, 50 mM MgCl₂, 10 mM Tris-Cl pH 8.0, A23187 induced a rapid efflux of K⁺ and Na⁺ from the eggs after a short lag time (10–15 seconds). After the burst, the rate of K⁺ efflux remained higher than the pre-activation rate, but was lower than during the burst phase, while the rate of Na⁺ efflux became nearly zero. Monovalent cation-specific ionophores (valinomycin, gramicidin and nigericin) had no effect on K⁺ efflux from the unfertilized eggs in our model system. However, once the egg was activated by A23187, each of the above ionophores caused a prolongation of the burst phase for many minutes. These results show that the unfertilized egg plasma membrane (using our artificial conditions) is not susceptible to the monovalent cation-specific antibiotics and suggest that either the inserted cortical granule membrane or the developing fertilization envelope interacts with these ionophores to cause the change in rate-limiting step for K⁺ efflux observed egg activation.