Effects of calcium on potassium and water transport in human erythrocyte ghosts

Bulk water transport in reconstituted ghosts is statistically comparable to that in the parent red cells, and is unaffected by incorporation of Ca²⁺ over the range of 0.01 to 1 mM. Brief exposure of ghosts to p-chloromercuribenzene sulfonate results in a supression of osmotic water flow but leaves K⁺ permeability unchanged. Incorporation of p-chloromercuribenzene sulfonate provokes extremely rapid K⁺ loss which can be counteracted by simultaneous inclusion of Ca²⁺.Erythrocyte ghosts, when prepared with a small amount of Ca²⁺, demonstrate recovery of normal impermeability to choline, sucrose, Na⁺ and inulin and have an improved K⁺ retention over Ca²⁺-free preparations.The rate of passive transport of K⁺ from unwashed erythrocyte ghosts was measured during the initial few minutes of efflux. The initial rates vary in a bimodal fashion with the concentration of Ca²⁺ incorporated at the time of hemolysis. In low concentrations (0.01–0.1 mM), Ca²⁺ protects the K⁺ barrier while at higher concentrations (0.1–1.0 mM) it provokes a K⁺ leakage ranging from 7 to 50 times the normal rate of passive K⁺ loss. The Ca²⁺-induced K⁺ leak is thus a graded response rather than a discrete membrane transport state. The transition from a Ca²⁺-protected to a Ca²⁺-damaged membrane occurs upon an increase in Ca²⁺ concentration of less than 50 μmoles/l.     

Interaction of dichlone with human erythrocytes. I. Changes in cell permeability

The uptake of the fungicide dichlone (2,3-dichloro-1,4-naphthoquinone) by human erythrocytes was extremely rapid, reaching a maximum within 5 min of treatment. Most of the dichlone taken up was present in the interior of the cell; only a small fraction of the pesticide (less than 5%) was bound to the cell membrane. Dichlone (3 · 10^?5M-10^?4M) induced a rapid loss of intracellular potassium from the erythrocytes; the leakage of K⁺ varied with the fungicide concentration as well as with cell concentration. Pretreatment of the cells with glutathione was able to reduce potassium loss. Cells exposed to dichlone showed increased osmotic fragility. Dichlone also inhibited Na⁺-K⁺ ATPase, which is associated with active ion transport. However, the leakage of potassium in dichlone-treated cells does not appear to be related to the interference with active ion transport. An extensive loss of potassium within a relatively short time after treatment suggests that dichlone produces its effect by increasing passive cation permeability, probably as a result of direct action on the membrane structure. Dichlone was able to induce hemolysis, but only at concentrations higher than those which resulted in K⁺ loss. The loss of hemoglobin appeared to be mainly due to osmotic swelling of the treated cells. Exposure of red cells to dichlone also resulted in a rapid and extensive formation of methemoglobin as well as a denaturation of hemoglobin. Thus, dichlone not only may be capable of lowering the capacity of erythrocytes to transport oxygen but also alters their permeability.     

Inhibition of anion permeability of sarcoplasmic reticulum vesicles by 4-acetoamido-4′-isothiocyanostilbene-2,2′-disulfonate

The permeabilities of sarcoplasmic reticulum vesicle membrane for various ions and neutral molecules were measured by following the change in light scattering intensity due to the osmotic volume change of the vesicles. 4-Acetoamido-4′-isothiocyanostilbene-2,2′-disulfonate (SITS), which is a potent inhibitor for the anion permeability of red blood cells membrane, inhibited the permeability of sarcoplasmic reticulum for anions such as Cl^?, P_i and methanesulfonate, while it slightly increased that for cations and neutral molecules such as Na⁺, K⁺, choline and glycerol. Binding of 5μmol SITS/g protein was necessary for the inhibition of anion permeability. These results suggest the existence of a similar anion transport system in sarcoplasmic reticulum membrane as revealed in red blood cell membrane.     

Antibodies to pig kidney (Na++K+)-ATPase inhibit the Na+ pump in human red cells provided they have access to the inner surface of the cell membrane

Antisera from rabbits that had been immunized with a highly active membrane preparation of (Na⁺ + K⁺)-ATPase from the outer medulla of pig kidney strongly inhibited (Na⁺ + K⁺)-ATPase activity in various tissues. When the antiserum was incorporated into released human red cell ghosts, the ouabain-sensitive efflux of Na⁺ into both 15 mM K⁺ and K⁺-free high Na⁺ media was completely abolished. This effect was not observed when non-immune serum was used, or when the immune serum was allowed access only to the outer surface of the red cell membranes.     

Ion transport by heart mitochondria: XXVII. The relation of mercurial-dependent adenosine triphosphatase activity to ion movements

The properties of a mercurial-dependent adenosine triphosphatase activity have been examined in isolated beef heart mitochondria. The reaction differs from that induced by uncouplers in that it is associated with extensive ion uptake and osmotic swelling, is highly specific for K⁺ over Na⁺, and is enhanced by respiration. Evidence is presented which suggests that the following events can account for the observations: (1) The mercurial blocks the phosphate transporter so that phosphate hydrolyzed from ATP is trapped in the matrix. (2) This interior negative potential causes cations to move inward and swelling results. (3) Permeability to K⁺ but not to Na⁺ is enhanced greatly by the reaction of the mercurial with the membrane. The inward movement of K⁺ closely resembles that produced by valinomycin, in that it is accompanied by proton ejection into the medium and it rapidly establishes a condition in which ion gradients cannot be maintained. This marked increase in permeability may be related to the pH gradient and is manifest as additional passive swelling in the absence of sucrose and passive contraction when sucrose is present. A comparison of the kinetics of swelling and of ATP hydrolysis shows that the elevated rates of ATPase are correlated with this condition of high permeability. When a corresponding condition of high permeability to Na⁺ is established by treatment with gramicidin or EDTA, the mercurial-dependent ATPase is nearly as rapid in Na⁺ as in the K⁺ medium. It appears, therefore, that the K⁺ specificity resides at the level of membrane permeability and is not a feature of the ATPase reaction per se. (4) Respiration appears to affect the ATPase reaction by virtue of its ability to extrude ions from the matrix in the presence of the mercurial. p-Chloromercuriphenyl sulfonate causes a switch from respiration-dependent ion accumulation to respiration-dependent ion extrusion to occur. A model to explain these reactions is presented.     

Sulfatide role in the sodium pump

Summary Sodium efflux was studied in²²Na-loaded red blood cells in the presence of arylsulfatase, an enzyme that specifically hydrolyzes sulfatide. Sodium efflux was inhibited in proportion to the amount of arylsulfatase present. Maximum inhibition was almost as high as the efflux obtained in medium with K⁺ absent. At maximum inhibition 83.2% of the sulfatide content of the fragmented red blood cell membranes was hydrolyzed and ouabain-sensitive (Na⁺+K⁺)-ATPase activity was inhibited by 100%. Sodium efflux, sulfatide content, and (Na⁺+K⁺)-ATPase activity were unaffected with arylsulfatase in the presence of a high concentration of sulfatide. These results indicate that sulfatide plays a specific role in sodium and potassium ion transport. They also suggest that most sulfatide is localized externally in the red blood cell membrane.     

Effect of anisotonic media on cell volume and electrolyte fluxes in slices of the dogfish (Squalus acanthias) rectal gland

Summary Osmotic responses of slices of dogfish rectal gland to hypotonic (urea-free) and hypertonic media were studied. Transfer of tissue from isotonic (890 mosM) to hypotonic (550 mosM) saline produced an osmotic swelling associated with a slow net uptake of cell K⁺ (and Cl^–) and a slow, two-component efflux of urea. Media made hypertonic (1180 mosM) by addition of urea or mannitol produced osmotic shrinkage with a net loss of KCl. The cell osmotic responses in hypotonic media were lower than predicted for an ideal osmometer. No volume regulatory responses were seen subsequent to the initial osmotic effects. The cation influx in hypotonic media lacked specificity: in the presence of 0.5 mM ouabain or in K⁺-free media a net influx of Na⁺ was found. At steady state, the cell membrane potential evaluated from the Nernst potentials of K⁺ and triphenylmethyl phosphonium⁺, was independent of medium tonicity, suggesting the membrane potential as a determinant in the cellular osmotic response. Zero-time⁸⁶Rb⁺ fluxes were measured:⁸⁶Rb⁺ influx was not affected by hypotonicity, implying an unchanged operation of the Na⁺–K⁺-ATPase. On the other hand,⁸⁶Rb⁺ efflux was significantly reduced at hypotonicity; this effect was transient, the efflux returning to the control value once the new steady state of cell volume had been reached. A controlled efflux system is therefore involved in the cell osmotic response. The absence of the volume regulatory phenomenon suggests that the cells are not equipped with a volume-sensing mechanism.Abbreviations and symbols DW dry weight - E extracellular (polyethylene glycol) space - E Nernst potential - H₂O_e H₂O_i tissue water, extra- and intracellular - TPMP ⁺ triphenyl methyl phosphonium salt - WW wet weight     

Evidence of voltage-induced channel opening in Na/K ATPase of human erythrocyte membrane

Summary Previous studies have shown that human erythrocytes when subjected to a high voltage pulsation, in the microsecond time range, lysed in an isotonic medium. The hemolysis was the result of the colloid osmotic swelling, which, in turn, was caused by the voltage perforation of the red cell membranes. In this work we demonstrate that in a low ionic medium at least 35% of the pores was related to the opening of Na⁺/K⁺ ATPase channels. The membrane conductance generated by the externally applied electric field could be partially blocked by a specific inhibitor, ouabain, or by a specific cross-linking reagent, Cu⁺⁺-phenanthroline, of the ATPase. The effect of ouabain was saturable and had a mid-point of saturation at 0.15 m. This value agrees with the physiological inhibition constant of the drug. K⁺ ion in the external medium suppressed the effect of ouabain, as has also been demonstrated in physiological studies. Experiment presented in this communication also suggests that the Na⁺/K⁺ ATPase was not perforable in a high ionic medium, and that a large fraction of the voltage-induced pores occurred at as yet unidentified sites.     

Inactivation of Mitochondrial Permeability Transition Pore by Octylguanidine and Octylamine

Mitochondrial permeability transition occurs through a Ca²⁺-dependent opening of atransmembrane pore, whose identity has been attributed to that of the adenine nucleotide translocase(ANT). In this work, we induced permeability transition by adding 0.5 M carboxyatractyloside.The process was evaluated analyzing Ca²⁺ efflux, a drop in transmembrane electric gradient,and swelling. We found that the amphiphyllic cations octylguanidine and octylamine, at theconcentration of 100 M, inhibited, almost completely, nonspecific membrane permeability.Hexylguanidine, hexylamine, as well as guanidine chloride and hydroxylamine failed to doso. The inhibition was reversed after the addition of 40 mM Li⁺, Na⁺ K⁺,Rb⁺, or Cs⁺; K⁺ wasthe most effective. We propose that the positive charge of the amines interact with negativecharges of membrane proteins, more likely the ADP/ATP carrier, while the alkyl chain penetratesinto the hydrophobic milieu of the inner membrane, fixing the reagent.     

Effects of quinine on K+ transport in heart mitochondria

Quinine inhibits the respiration-dependent extrusion of K⁺ from Mg²⁺-depleted heart mitochondria and the passive osmotic swelling of these mitochondria in K⁺ and Na⁺ acetate at alkaline pH. These observations concur with those of Nakashima and Garlid (J. Biol. Chem. 257, 9252, 1982) using rat liver mitochondria. Quinine also inhibits the respiration-dependent contraction of heart mitochondria swollen passively in Na⁺ or K⁺ nitrate and the increment of elevated respiration associated with the extrusion of ions from these mitochondria. Quinine, at concentrations up to 0.5 mM, inhibits the respiration-dependent⁴²K⁺/K⁺ exchange seen in the presence of mersalyl, but higher levels of the drug produce increased membrane permeability and net K⁺ loss from the matrix. These results are all consistent with an inhibition of the putative mitochondrial K⁺/H⁺ antiport by quinine. However, quinine has other effects on the mitochondrial membrane, and possible alternatives to this interpretation are discussed.     

Effect of sodium on potassium fluxes at the cell membrane and vacuole membrane of red beet

Slices of red beet (Beta vulgaris) washed for 5 to 6 days are known to accumulate Na⁺ in preference to K⁺ from solutions containing both ions. The present work, using ion concentrations of 1.0 mm or less, with Ca²⁺ added in some cases, shows that Na⁺ strongly inhibits K⁺ influx at the cell membrane (plasmalemma) while K⁺ efflux is increased to a lesser extent. This result from compartmental analysis is confirmed by short (15-minute) influx experiments, which indicate an immediate inhibitory effect of Na⁺ on K⁺ influx at the cell membrane. It is concluded that cation selectivity, even when Na⁺ is favored for uptake, is primarily determined at the cell membrane. Nevertheless, a high level of K⁺ in the cytoplasm is maintained during Na⁺ influx, by an inhibition of K⁺ transfer to the vacuole.     

Relation between red cell membrane (Na + K)-ATPase and band 3 protein

This study is designed to examine the participation of the major red cell membrane protein, band 3 protein, in the chain which transmits information from the cardiac glycoside site on the external face of the cell (Na⁺ + K⁺)-ATPase to the megadalton glycolytic enzyme complex within the cell. The experiments show that the anion transport inhibitor, 4,4′-diisothiocyano-2,2′-stilbenedisulfonic acid, affects the resonance of 2,3-diphosphoglycerate, as does the cardiac glycoside cation transport inhibitor, ouabain. Resonance shifts induced by the cardiac glycoside alone are modulated by addition of the anion transport inhibitor which indicates that there is coupling in the red cell between the (Na⁺ + K⁺)-ATPase and band 3 protein. Band 3 protein was separated from the membrane and partially purified following the technique of Yu and Steck ((1975) J. Biol. Chem. 250, 9170–9175). When glyceraldehyde-3-phosphate dehydrogenase was added to the separated band 3 protein preparation, addition of cardiac glycosides caused shifts in the ³¹P resonance of glyceraldehyde 3-phosphate. These experiments indicate that there is coupling between the (Na⁺ + K⁺)-ATPase and band 3 protein in the separated preparation and suggest that the anion and cation transport systems may be closely related spatially and functionally in the intact red cell.     

H+-dependent efflux of Ca2+ from heart mitochondria

A rapid loss of accumulated Ca²⁺ is produced by addition of H⁺ to isolated heart mitochondria. The H⁺-dependent Ca⁺ efflux requires that either (a) the NAD(P)H pool of the mitochondrion be oxidized, or (b) the endogenous adenine nucleotides be depleted. The loss of Ca²⁺ is accompanied by swelling and loss of endogenous Mg^2–. The rate of H⁺-dependent Ca²⁺ efflux depends on the amount of Ca²⁺ and P_i taken up and the extent of the pH drop imposed. In the absence of ruthenium red the H⁺-induced Ca²⁺-efflux is partially offset by a spontaneous re-accumulation of released Ca²⁺. The H⁺-induced Ca²⁺ efflux is inhibited when the P_i transporter is blocked withN-ethylmaleimide, is strongly opposed by oligomycin and exogenous adenine nucleotides (particularly ADP), and inhibited by nupercaine. The H⁺-dependent Ca²⁺ efflux is decreased markedly when Na⁺ replaces the K⁺ of the suspending medium or when the exogenous K⁺/H⁺ exchanger nigericin is present. These results suggest that the H⁺-dependent loss of accumulated Ca²⁺ results from relatively nonspecific changes in membrane permeability and is not a reflection of a Ca²⁺/H⁺ exchange reaction.     

Role of membrane sialic acid and glycophorin protein in thorium induced aggregation and hemolysis of human erythrocytes

Thorium-232 (²³²Th), a natural radionuclide from the actinide family, is abundantly present in monazite and other ores. It is used as one of the prime fuel materials in nuclear industry and may pose an exposure risk to nuclear workers and members of the public. Human erythrocytes, as a classical cellular membrane model, were coincubated with ²³²Th in order to elucidate whether this naturally occurring important radionuclide produced perturbations to cell membrane. Present study revealed that erythrocytes underwent aggregation or lysis depending on the ratio of ²³²Th to cell. Scanning electron micrographs showed that erythrocytes transformed into equinocytes and/or spherocytes after ²³²Th treatment. Further examination of erythrocyte by atomic force microscopy suggested significant increase in surface roughness after ²³²Th treatment. Experiments on neuraminidase treated and/or anti-GpA antibody blocked erythrocytes suggested significant role of membrane sialic acid and glycophorin A (GpA) protein in aggregation or hemolytic effects of ²³²Th. Further results showed that ²³²Th caused hemolysis by colloid osmotic mechanism, as evidenced by potassium efflux, osmotic protection and osmotic fragility studies. Osmoprotection experiments indicated that hemolysis get elicited through the formation of membrane pores of ∼2.0 nm in size. Hemolysis studies in presence of inhibitors (TEA, bumetanide, DIDS and amiloride) revealed the role of K⁺ channel, Na⁺/K⁺/2Cl⁻ channel, Cl⁻/HCO₃⁻ anion exchanger and Na⁺/H⁺ antiporter in ²³²Th induced erythrolysis. Presence of non-diffusible cation (N-methyl d-glucasamine) or anion (gluconate) in erythrocyte suspending medium further confirm the role of Na⁺ and Cl⁻ influx in hemolytic effect of ²³²Th. These findings provide significant insight in structural, biochemical and osmotic toxic effects of ²³²Th on human erythrocytes.     

Erythrocyte membrane sulfhydryl groups and cation permeability

Reaction of the slowly penetrating organic mercurial compound parachloromercuribenzene sulfonate (PCMBS) with intact erythrocytes has been characterized. Addition of concentrations of PCMBS which result in binding within the interior of the membrane of more than 1.9 × 10^?18 moles/cell produces alterations in Na⁺ and K⁺ permeability, but does not affect choline permeability. However, the increased cation permeability is observed only after a lag period of over two hours. After ten hours, a spontaneous slow “recovery” to normal rates of K⁺ leakage occurs at 25°C but not at 2°C. Subsequent to the effects on cation balance, increasing degrees of hemolysis occur, interpreted as colloid osmotic lysis. The relationships between the binding of the agent and its effects are as follows: a small, rapid initial uptake does not affect cation permeability; the subsequent slower uptake is associated with increased leakage of K⁺ and Na⁺; and the recovery at 25°C is associated with desorption of about half of the PCMBS due to competition by soluble thiol substances released into the medium from the cells. Desorption and “recovery” can be mimicked at any time by addition of small amounts of protein in the medium. The half of the PCMBS that cannot be desorbed is assumed to be bound by the hemoglobin inside the cell. The sulfhydryl groups involved in control of cation permeability constitute only a fraction of the total within the membrane (4–18%). They are located within the interior of the membrane separated from the medium and from the interior of the cell by diffusion barriers to PCMBS.     

Charybdotoxin blocks with high affinity the Ca-activated K+ channel of Hb A and Hb S red cells: Individual differences in the number of channels

Summary We have investigated the effect of a purified preparation of Charybdotoxin (CTX) on the Ca-activated K⁺ (Ca–K) channel of human red cells (RBC). Cytosolic Ca²⁺ was increased either by ATP depletion or by the Ca ionophore A23187 and incubation in Na⁺ media containing CaCl₂. The Ca–K efflux activated by metabolic depletion was partially (77%) inhibited from 15.8±2.4 mmol/liter cell · hr, to 3.7±1.0 mmol/liter cell · hr by 6nm CTX (n=3). The kinetic of Ca–K efflux was studied by increasing cell ionized Ca²⁺ using A23187 (60 mol/liter cell), and buffering with EGTA or citrate; initial rates of net K⁺ efflux (90 mmol/liter cell K⁺) into Na⁺ medium containing glucose, ouabain, bumetanide at pH 7.4 were measured. Ca–K efflux increased in a sigmoidal fashion (n of Hill 1.8) when Ca²⁺ was raised, with aK _m of 0.37 m and saturating between 2 and 10 m Ca²⁺. Ca–K efflux was partially blocked (71±7.8%, mean ±sd,n=17) by CTX with high affinity (IC₅₀0.8nm), a finding suggesting that is a high affinity ligand of Ca–K channels. CTX also blocked 72% of the Ca-activated K⁺ efflux into 75mm K⁺ medium, which counteracted membrane hyperpolarization, cell acidification and cell shrinkage produced by opening of the K⁺ channel in Na⁺ media. CTX did not block Valinomycin-activated K⁺ efflux into Na⁺ or K⁺ medium and therefore it does not inhibit K⁺ movement coupled to anion conductive permeability.TheV _max, but not theK _m–Ca of Ca–K efflux showed large individual differences varying between 4.8 and 15.8 mmol/liter cell · min (FU). In red cells with Hb A,V _max was 9.36±3.0 FU (mean ±sd,n=17). TheV _max of the CTX-sensitive, Ca–K efflux was 6.27±2.5 FU (range 3.4 to 16.4 FU) in Hb A red cells and it was not significantly different in Hb S (6.75±3.2 FU,n=8). Since there is larger fraction of reticulocytes in Hb S red cells, this finding indicates that cell age might not be an important determinant of theV _max of Ca–K⁺ efflux.Estimation of the number of CTX-sensitive Ca-activated K⁺ channels per cell indicate that there are 1 to 3 channels/per cell either in Hb A or Hb S red cells. The CTX-insensitive K⁺ efflux (2.7±0.9 FU) may reflect the activity of a different channel, nonspecific changes in permeability or coupling to an anion conductive pathway.     

Influence of monovalent ions on the activity of the (Ca2+ + Mg2+)-ATPase and Ca2+-transport of human red blood cells

In reconstituted human red blood cells a difference was found in (Ca²⁺ + Mg²⁺)-ATPase activity and in Ca²⁺ efflux at 37°C, depending on the side of the membrane at which the monovalent cations K⁺ and Na⁺ were placed. Under the conditions used, (Ca²⁺ + Mg²⁺)-ATPase activity and Ca²⁺ efflux was highest when K⁺ ($\text{35 ± 0.5}\text{mM (± S.E.)}$, mean of four experiments) was at the inside and Na⁺ (130 mM) at the outside of the ghost membrane.     

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.     

H2O2 and cytosolic Ca2+ signals triggered by the PM H+‐coupled transport system mediate K+/Na+ homeostasis in NaCl‐stressed Populus euphratica cells

Using confocal microscopy, X‐ray microanalysis and the scanning ion‐selective electrode technique, we investigated the signalling of H₂O₂, cytosolic Ca²⁺ ([Ca²⁺]_cyt) and the PM H⁺‐coupled transport system in K⁺/Na⁺ homeostasis control in NaCl‐stressed calluses of Populus euphratica. An obvious Na⁺/H⁺ antiport was seen in salinized cells; however, NaCl stress caused a net K⁺ efflux, because of the salt‐induced membrane depolarization. H₂O₂ levels, regulated upwards by salinity, contributed to ionic homeostasis, because H₂O₂ restrictions by DPI or DMTU caused enhanced K⁺ efflux and decreased Na⁺/H⁺ antiport activity. NaCl induced a net Ca²⁺ influx and a subsequent rise of [Ca²⁺]_cyt, which is involved in H₂O₂‐mediated K⁺/Na⁺ homeostasis in salinized P. euphratica cells. When callus cells were pretreated with inhibitors of the Na⁺/H⁺ antiport system, the NaCl‐induced elevation of H₂O₂ and [Ca²⁺]_cyt was correspondingly restricted, leading to a greater K⁺ efflux and a more pronounced reduction in Na⁺/H⁺ antiport activity. Results suggest that the PM H⁺‐coupled transport system mediates H⁺ translocation and triggers the stress signalling of H₂O₂ and Ca²⁺, which results in a K⁺/Na⁺ homeostasis via mediations of K⁺ channels and the Na⁺/H⁺ antiport system in the PM of NaCl‐stressed cells. Accordingly, a salt stress signalling pathway of P. euphratica cells is proposed.