Anion-dependent cation transport in erythrocytes

A selective survey of the literature reveals at least three major anion-dependent cation transport systems, defined as Na+ + Cl-, K+ + Cl- and Na+ + K+ + Cl- respectively. In human red cells, kinetic data on the fraction of K+ and Na+ influx inhibitable by bumetanide are presented to indicate an Na+:K+ stoichiometry of 1:2. For LK sheep red cells the large Cl- -dependent K+ leak induced by swelling is shown to share many characteristics with that induced by N-ethylmaleimide (NEM) treatment. NEM has complex effects, both inhibiting and then activating Cl- -dependent K+ fluxes dependent on NEM concentration. The alloantibody anti-L can prevent the action of NEM. In human red cells NEM induces a large Cl- -dependent specific K+ flux, which shows saturation kinetics. Its anion preference is Cl- greater than Br- greater than SCN- greater than I- greater than NO3- greater than MeSO4-. This transport pathway is not inhibited by oligomycin or SITS, although phloretin and high concentrations of furosemide and bumetanide (over 0.3 mM) do inhibit. Quinine (0.5 mM) is also an inhibitor. It is concluded that at least two distinct Cl- -dependent transport pathways for K+ are inducible in mammalian red cells, although the evidence for their separation is not absolute.     

Decreased deformability in aging erythrocytes

Deformability of bovine erythrocytes separated according to density (and age) was estimated by a modified Teitel's filterability test, the centrifugational test of Sirs, and viscosity measurements of cell suspensions. Both youngest and oldest erythrocytes were found to be less deformable than middle-aged cells, a result speaking against any chief role for deformability in the recognition of senescent erythrocytes and their removal from the circulation.     

Monensin-induced cation movements in bovine erythrocytes

Monensin is a carboxylic ionophore that has been observed to increase cation permeability across the membrane of several cell types. Additionally, it is used commercially as an anticoccidial agent and has been found to increase feed efficiency in cattle. The objectives of these experiments were to determine the ability of monensin to stimulate cation (Na and K) transport across the bovine erythrocyte membrane and determine the effects of anion substitution on the action of the compound. Erythrocyte cation analyses revealed that all of the animals used in this study were low potassium (LK). Red cells were incubated in an artificial medium in the presence or absence of monensin, and cell sodium, potassium and water were determined at several time periods. It was observed that monensin stimulated the movement of sodium and potassium down their respective concentration gradients. Cell water content ("D") was observed to increase in response to an elevation in cell cation content. In synthetic media containing acetate, sulfate, citrate, thiocynate and gluconate substituted for chloride as the anion specie in the presence of monensin, there were measureable differences in intracellular sodium and water during the incubation period. The addition of DIDS to the control media containing chloride was observed to inhibit from 60 to 80 percent of the monensin-stimulated sodium movements. The results of this study show that monensin stimulates cation movements in bovine erythrocytes and anion substitutes may alter the action of this ionophore. Additionally, it was demonstrated that the action of monensin can be modified by inhibition of Band 3.     

Non-selective cation channel activity is required for lysophosphatidylcholine-induced monocyte migration

Lysophosphatidylcholine (LPC) is a major atherogenic lipid which stimulates the recruitment of monocytes to atherosclerotic lesions. The physiological mechanisms underlying LPC-induced monocyte migration are poorly understood. Here we demonstrate that LPC activates non-selective cation channels, which are significantly involved in LPC-induced chemotaxis of monocytes. External LPC elicited the activation of non-selective cation currents in THP-1 monocytes, which occurred in a G protein and phospholipase C-independent manner. LPC-activated currents were almost completely inhibited by Gd³⁺, La³⁺, and TRAM-34. Furthermore, currents were partially reduced by either 2-aminoethoxydiphenyl borate (2-APB) or ruthenium red, while combined application of 2-APB and ruthenium red abolished LPC-activated currents. The 2-APB-sensitive current component was potentiated by flufenamic acid and Ca²⁺-free extracellular solution, while the ruthenium red-sensitive current component was abolished by capsazepine. This pharmacological profile suggests that LPC simultaneously activates TRPC6 and TRPV1 channels in monocytes. Furthermore, in the presence of Gd³⁺, La³⁺, TRAM-34, 2-APB, ruthenium red or capsazepine, LPC-induced chemotaxis of monocytes was substantially inhibited, indicating that activation of both channel types is required for optimal migration of LPC-stimulated monocytes. Thus, ion channel inhibition may represent a powerful strategy to attenuate the progression of atherosclerosis by reducing monocyte infiltration. J. Cell. Physiol. 221: 325–334, 2009. © 2009 Wiley-Liss, Inc.     

Protein kinase C activity in erythrocytes in primary hypertension: regulation of cell shape and cation transport

Protein kinase C activity in the lysate of erythrocytes of patients with essential hypertension (EH) and spontaneously hypertensive rats (SHR) was found to be increased by 1.6-2.0 times as compared with normotensive controls. Membrane cytoskeleton alterations observed in the erythrocytes of patients with EH and SHR were revealed in decreased average erythrocyte volume, increase of cup-shaped cell formation, and increase of basal phosphorylation of band 4.9 protein. In addition, the rate of Na(+)-H+ exchange in erythrocytes of EH patients and SHR was increased by 1.9-fold. In vitro treatment of erythrocytes of healthy donors and Wistar-Kyoto rats (WKY) with protein kinase C activator (12-O-tetradecanoylphorbol-13-acetate) leads to similar changes of cell shape, cell volume, band 4.9 protein phosphorylation and Na(+)-H+ exchange, as well as to an increase of diS-C3-(5) fluorescence. It may be assumed that alterations of these parameters revealed in primary hypertension are caused by increased activity of protein kinase C.     

Voltage dependence and pH regulation of human polycystin-2-mediated cation channel activity

Polycystin-2, the product of the human PKD2 gene, whose mutations cause autosomal dominant polycystic kidney disease, is a large conductance, Ca(2+)-permeable non-selective cation channel. Polycystin-2 is functionally expressed in the apical membrane of the human syncytiotrophoblast, where it may play a role in the control of fetal electrolyte homeostasis. Little is known, however, about the mechanisms that regulate polycystin-2 channel function. In this study, the role of pH in the regulation of polycystin-2 was assessed by ion channel reconstitution of both apical membranes of human syncytiotrophoblast and the purified FLAG-tagged protein from in vitro transcribed/translated material. A kinetic analysis of single channel currents, including dwell time histograms, confirmed two open and two close states for spontaneous channel behavior and a strong voltage dependence of the open probability of the channel (P(o)). A reduction of cis pH (pH(cis)) decreased P(o) and shifted the voltage dependence of channel function but had no effect on the single channel conductance. An increase in pH(cis), in contrast, increased NP(o) (channel number times P(o)). Elimination of the H(+) chemical gradient did not reverse the low pH(cis) inhibition of polycystin-2. Similar findings confirmed the pH effect on the in vitro translated, FLAG-tagged purified polycystin-2. The data indicate the presence of an H(+) ion regulatory site in the channel protein, which is accessible from the cytoplasmic side of the protein. This protonation site controls polycystin-2 cation-selective channel activity.     

The connexion between active cation transport and metabolism in erythrocytes

1. A study has been made of the dependence on the concentrations of internal Na(+) and external K(+) of lactate and phosphate production in human erythrocytes. 2. Lactate production was stimulated by Na(+) and K(+) but only when they were internal and external respectively. The stimulation was counteracted by ouabain. The production of phosphate was affected in the same way. 3. There is a quantitative correlation between these effects and those previously found for cation movements and the membrane adenosine triphosphatase. 4. It is concluded that the rate of energy production in glycolysis is partly controlled by the magnitude of active transport; the extent of this regulation is shown to vary from 25 to 75% of a basal rate that is independent of active transport. 5. The activity of the membrane adenosine triphosphatase was also compared with rates of Na(+) and K(+) transport. The latter were varied by altering the concentrations of internal Na(+) and external K(+), and by inhibiting with ouabain. 6. A threefold variation of active transport rate was accompanied by a parallel change in the membrane adenosine-triphosphatase activity. The results show a constant stoicheiometry for the number of ions moved/mol. of ATP hydrolysed, independent of the electrochemical gradient against which the ions were moved. 7. Calculations show that the amount of ATP hydrolysed would provide enough energy for the osmotic work. The results are discussed in relation to possible mechanisms for active transport.     

Proteome analysis of erythrocytes lacking AMP-activated protein kinase reveals a role of PAK2 kinase in eryptosis

Activation of AMP-activated protein kinase (AMPK) upon energy depletion stimulates energy production and limits energy utilization. Erythrocytes lacking AMPK are susceptible to suicidal cell death (eryptosis). A hallmark of eryptosis is cell membrane scrambling with phosphatidylserine exposure at the erythrocyte surface, which can be identified from annexin V-binding. AMPKα1-deficient mice (ampk(-/-)) suffer from anemia due to accelerated clearance of erythrocytes from circulating blood. To determine the link between AMPK and the eryptotic phenotype, we performed a global proteome analysis of erythrocytes from ampk(-/-) mice and wild-type mice using high-accuracy mass spectrometry and label-free quantitation and measured changes of expression levels of 812 proteins. Notably, the p21-activated kinase 2 (PAK2), previously implicated in apoptosis, was detected as downregulated in erythrocytes of ampk(-/-) mice, pointing to its potential role in eryptosis. To validate this, we showed that specific inactivation of PAK2 with the inhibitor IPA3 in human and murine ampk(+/+) erythrocytes increases the binding of annexin V and augments the stimulating effect of glucose deprivation on annexin V-binding. Inhibition of PAK2 failed to significantly modify annexin V-binding in ampk(-/-) erythrocytes, showing that AMPK and PAK2 exert similar phenotypes upon inactivation in erythrocytes. This study presents the first large-scale analysis of protein expression in erythrocytes from AMPKα1-deficient mice and reveals a role of PAK2 kinase in eryptosis.     

Decreased catalase activity is the underlying mechanism of oxidant susceptibility in glucose-6-phosphate dehydrogenase-deficient erythrocytes

Historically, it has been theorized that the oxidant sensitivity of glucose-6-phosphate dehydrogenase (G6PD)-deficient erythrocytes arises as a direct consequence of an inability to maintain cellular gluthione (GSH) levels. This study alternatively hypothesizes that decreased NADPH concentration leads to impaired to catalase activity which, in turn, underlies the observed oxidant susceptibility. To investigate this hypothesis, normal and G6PD-deficient erythrocytes and hemolysates were challenged with a H₂O₂-generating agent. The results of this study demonstrated that catalase activity was severely impaired upon H₂O₂ challenge in the G6PD-deficient cell whiel only decrease was observed in normal cells. Supplmentation of either normal or G6PD-deficient hemolysates with purified NADPH was found to significantly (P < 0.001) inhibit catalase inactivation upon oxidant challenge while addition of NADP⁺ had no effect. Analysis of these results demonstrated direct correlation between NADPH concentration and catalase activity (r = 0.881) and an inverse correlation between catalase activity and erythrocyte oxidant sensitivity (r = 0.906). In contrast, no correlation was found to exist between glutathione concentration (r = 0.170) and oxidant sensitivity. Analysis of NADPH/NADPt ration in acatalasemic mouse erythrocytes demonstrated that NADPH maintenance alone was not sufficient to explain oxidant resistance, and that catalase activity was required. This study supports the hypothesis that impaired catalase activity underlies the enhanced oxidant sensitivity of G6PD-deficient erythrocytes and elucidates the importance of NADPH in the maintenance of normal catalase activity.     

Divalent cation effects on membrane bending in heated erythrocytes

The thermal fragmentation of human erythrocytes involves either surface wave growth and membrane externalization at the cell rim or membrane internalization at the cell dimple. In symmetrical monovalent electrolytes an increase in membrane internalization at the cell dimple correlates with the decrease in zeta potential arising from surface charge (sialic acid residue) depletion. The influence of divalent cations on thermal fragmentation is examined in this work. The erythrocyte zeta potential decreased when divalent cations replaced some Na⁺ in the cell-suspending phase. The incidence of membrane internalization increased in rank order Ca²⁺>Ba²⁺>Mg²⁺Sr²⁺. Calcium continued to influence the thermal fragmentation of cells highly depleted of sialic acid, suggesting that the ion also interacted with membrane sites other than sialic acid. The divalent cation influence on cell fragmentation was shown to be greater than that due to zeta potential decrease alone. This conclusion was supported by the observation that the divalent cation-induced changes in zeta potential showed much less cation specificity than did the changes induced in the thermal fragmentation pattern. The result implies that the specificity of the divalent cation effects was due to interactions within the erythrocyte shear layer. The possibility that the interaction is with membrane lipids is examined.     

Furosemide-sensitive sodium and potassium fluxes in human neonatal erythrocytes

During the course of incubation, in vitro, in a saline medium, we found an increase of cell volume and Na+ content in human neonatal erythrocytes (NNE), from the umbilical cord. The increased cell volume was dependent on the major anion in the medium in that replacement of Cl- by NO-3 abolished the cell volume increase. In erythrocytes from adults neither the cell volume nor the sodium content were altered under similar incubation conditions. Furosemide-sensitive Na+ and K+ fluxes were at variance from those reported from adult erythrocytes. The differences here presented between both cell types would be another instance of changes observed to occur in erythrocytes during the postnatal period.     

Hypertension: cation transport and the physical properties of erythrocytes

In recent years, many reports have appeared describing altered Na+ and K+ transport in erythrocytes of individuals with essential hypertension. Collectively, the interpretation of these results has been unclear. Our studies revealed that the active ouabain-sensitive K+ influx, the furosemide-sensitive K+ influx and the residual passive K+ influx in both human and rat erythrocytes can vary considerably among individual persons or rats and that these measurements alone can not be used to distinguish normotensive from hypertensive individuals. The only consistent cation transport difference observed was an increased Na+ permeability in spontaneously hypertensive rat (SHR) erythrocytes. We have also examined certain physical properties (equilibrium density distribution and sedimentation velocity) of erythrocytes from normotensive Wistar-Kyoto (WKY) and SHR rats, since these characteristics may be altered in response to abnormalities of ion transport. It was found that the erythrocytes from geographically, environmentally, and age-matched littermates of WKY and SHR rats have identical equilibrium density distributions. It was also found that the density distribution of erythrocytes can vary among geographically dispersed colonies of the same strain of rat, and even among successive litters of the same rat colony. However, the sedimentation time required for erythrocytes to reach their equilibrium density was always shorter in the normotensive WKY samples than in the matched SHR. Utilizing a simple centrifugation method, we were able to clearly show that for any population of erythrocytes with the same upper limit of cell density, normotensive WKY cells always sediment at a faster rate than those of the hypertensive SHR.(ABSTRACT TRUNCATED AT 250 WORDS)     

Decreased intracellular free magnesium in erythrocytes of spontaneously hypertensive rats

Using 31p-NMR (the phosphorus nuclear magnetic resonance) spectroscopy, we measured intracellular free Mg levels in the erythrocytes of untreated (n = 7) and diltiazem-treated spontaneously hypertensive rats (SHR) (n = 8), and compared them with age-matched Wistar-Kyoto rats (WKY) (n = 10). The intracellular free Mg levels were significantly (p less than 0.01) decreased in untreated SHR compared with those in control WKY. A successful antihypertensive treatment with diltiazem increased the intracellular free Mg levels compared with untreated SHR (p less than 0.05). Furthermore, an inverse correlation was observed between intracellular free Mg levels and blood pressure levels in all groups (r = -0.48, p less than 0.01, n = 25). These observations suggest that abnormalities of intracellular Mg metabolism may be, in part, related to the development or the maintenance of hypertension in SHR.     

Calcium-activated cation channel in rat thyroid follicular cells

Using the patch-clamp single-channel current recording technique, a cation channel in the contraluminal membrane of rat thyroid follicular cells has been characterized. The channel has a unit conductance of about 35 pS and is equally permeable to sodium and potassium. The pattern of channel opening and closing is independent of the membrane potential. The channel is only operational when the ionized calcium concentration in the fluid which is in contact with the inside of the membrane is at least 1 microM. This conductance pathway can be classified as a calcium dependent non-selective cation channel and could explain stimulant-evoked depolarizations in the thyroid follicular cells.