Effect of intracellular magnesium and oxygen tension on K+-Cl- cotransport in normal and sickle human red cells.

In red cells from normal individuals (HbA cells), the K+-Cl- cotransporter (KCC) is inactivated by low O2 tension whilst in those from sickle cell patients (HbS cells), it remains fully active. Changes in free intracellular [Mg2+] have been proposed as a mechanism. In HbA cells, KCC activity was stimulated by Mg2+ depletion and inhibited by Mg2+ loading but the effect of O2 was independent of Mg2+. At all [Mg2+]is, the transporter was stimulated in oxygenated cells, minimally active in deoxygenated ones. By contrast, the stimulatory effects of O2 was abolished by inhibitors of protein (de)phosphorylation. HbS cells had elevated KCC activity, which was of similar magnitude in oxygenated and deoxygenated cells, regardless of Mg2+ clamping. In deoxygenated cells, the antisickling agent dimethyl adipimidate inhibited sickling, Psickle and KCC. Results indicate a role for protein phosphorylation in O2 dependence of KCC, with different activities of the relevant enzymes in HbA and HbS cells, probably dependent on Hb.     

Homooligomeric and heterooligomeric associations between K+-Cl- cotransporter isoforms and between K+-Cl- and Na+-K+-Cl- cotransporters

Little is known regarding the quaternary structure of cation-Cl- cotransporters (CCCs) except that the Na+-dependent CCCs can exist as homooligomeric units. Given that each of the CCCs exhibits unique functional properties and that several of these carriers coexist in various cell types, it would be of interest to determine whether the four K+-Cl- cotransporter (KCC) isoforms and their splice variants can also assemble into such units and, more importantly, whether they can form heterooligomers by interacting with each other or with the secretory Na+-K+-Cl- cotransporter (NKCC1). In the present work, we have addressed these questions by conducting two groups of analyses: 1) yeast two-hybrid and pull-down assays in which CCC-derived protein segments were used as both bait and prey and 2) coimmunoprecipitation and functional studies of intact CCCs coexpressed in Xenopus laevis oocytes. Through a combination of such analyses, we have found that KCC2 and KCC4 could adopt various oligomeric states (in the form of KCC2-KCC2, KCC4-KCC4, KCC2-KCC4, and even KCC4-NKCC1 complexes), that their carboxyl termini were probably involved in carrier assembly, and that the KCC4-NKCC1 oligomers, more specifically, could deploy unique functional features. Through additional coimmunoprecipitation studies, we have also found that KCC1 and KCC3 had the potential of assembling into various types of CCC-CCC oligomers as well, although the interactions uncovered were not characterized as extensively, and the protein segments involved were not identified in yeast two-hybrid assays. Taken together, these findings could change our views on how CCCs operate or are regulated in animal cells by suggesting, in particular, that cation-Cl- cotransport achieves higher levels of functional diversity than foreseen.     

Peroxynitrite activates K+-Cl- cotransport in human erythrocytes

Peroxynitrite was found to induce the release of K+ via the Na+/Cl- cotransport system, as do other oxidants. Since peroxynitrite is formed in vivo, its presence could contribute to a pathological dehydration of red blood cells.     

Phosphate transport in human red blood cells: Concentration dependence and pH dependence of the unidirectional phosphate flux at equilibrium conditions

Summary The concentration dependence and the pH dependence of the phosphate transport across the red cell membrane were investigated. The unidirectional phosphate fluxes were determined by measuring the³²P-phosphate self-exchange in amphotericin B (5 mol/liter) treated erythrocytes at 25°C.The flux/concentration curves display anS-shaped increase at low phosphate concentrations, a concentration optimum in the range of 150 to 200mm phosphate and a self-inhibition at high phosphate concentrations. The apparent half-saturation concentrations,P _(0.5), range from 50 to 70mm and are little affected by pH. The self-inhibition constants, as far as they can be estimated, range from 400 to 600mm. The observed maximal phosphate fluxes exhibit a strong pH dependence. At pH 7.2, the actual maximal flux is 2.1×10^–6 moles·min^–1·g cells^–1. The ascending branches of the flux/concentration curves were fitted to the Hill equation. The apparent Hill coefficients were always in the range of 1.5–2.0. The descending branches of the flux/concentration curves appear to follow the same pattern of concentration response.The flux/pH curves were bell-shaped and symmetric with regard to their pH dependence. The pH optimum is at approximately pH 6.5–6.7. The apparent pK of the activator site is in the range of 7.0 to 7.2, while the apparent pK for the inactivating site is in the range of 6.2 to 6.5. The pK-values were not appreciably affected by the phosphate concentration.According to our studies, the transport system possesses two transport sites and probably two modifier sites as indicated by the apparent Hill coefficients. In addition, the transport system has two proton binding sites, one with a higher pK that activates and one with a lower pK that inactivates the transport system. Since our experiments were executed under self-exchange conditions, they do not provide any information concerning the location of these sites at the membrane surfaces.     

Effect of peroxynitrite on passive K+ transport in human red blood cells.

Peroxynitrite is generated in vivo by the reaction between nitric oxide, from endothelial and other cells, and the superoxide anion. It is therefore pertinent to examine its effects on the membrane permeability of red blood cells. Treatment of human red blood cells with peroxynitrite (nominally 1 mM) markedly stimulated passive K+ permeability. The main effect was on a Cl(-)-independent K+ pathway, which remains unidentified. Although K+-Cl- cotransport (KCC) was stimulated, this was dependent on saline composition, being inhibited by physiological levels of glucose (IC50 4 mM), and also by sucrose and MOPS. Effects on the Cl(-)-independent K+ pathway were less dependent on saline composition, and were not inhibited by amiloride, ethylisopropylamiloride, dimethylamiloride or gadolinium. Na+-K+-2Cl- cotransporter was inhibited whilst there was little effect on the Gardos channel (Ca2+-activated K+ channel). Peroxynitrite was markedly more effective in oxygenated cells than deoxygenated ones. Treatment with peroxynitrite per se did not affect initial cell volume. Anisotonic swelling modestly increased the Cl(-)-independent K+ influx, but did not affect peroxynitrite-stimulated KCC. Decreasing extracellular pH from 7.4 to 7.2 or 7.0 increased KCC stimulation, whilst the Cl(-)-independent component of K+ transport was lowest at pH 7.2. Finally, protein phosphatase inhibition with calyculin A (100 nM) inhibited KCC, implying that, as with other KCC stimuli, peroxynitrite acts via decreased protein phosphorylation; pre-treatment with calyculin A also inhibited the Cl(-)-independent component of K+ transport. These findings are relevant to the actions of peroxynitrite in vivo.     

Influences of cell volume and adrenalectomy on cation flux in dog red blood cells

Rates of ²⁴Na and ⁴²K entry into dog red blood cells were found to be strongly influenced by cell volume. The kinetics of isotope movement were complex, and the cells were not in a steady state. By applying a simple, two-compartment equation to the early times points, values for flux were calculated and corrected for the changes in surface/volume ratio which occur when cells are shrunken or swollen. Curves were thus generated showing Na and K influx as functions of cell water content. A reinvestigation of the effects of adrenalectomy showed that all the observd changes in Na flux could be explained on the basis of alterations in red cell volume.     

The influence of pH and membrane potential on passive Na+ and K+ fluxes in human red blood cells

Passive (ouabain-insensitive) Na+ and K+ effluxes from human red blood cells were measured over the range pHo 6.2-8.5. On raising pHo, Na+ efflux increased and this was mainly attributable to the piretanide-sensitive component: K+ efflux likewise but attributable to both piretanide-sensitive and piretanide-insensitive components. On replacing Cl- with non-penetrating anions (mainly gluconate), Na+ and K+ effluxes increased, mostly attributable to the piretanide-insensitive components. On restoring pHi either by reducing pHo or by applying DIDS, the influence of pHo on Na+ and K+ effluxes was diminished. These results suggest that pHi rather than Em is the dominant influence. Passive Na+ and K+ effluxes and influxes in the presence of bumetanide were tested fro conformity to the Ussing independence relationship. For K+, the calculated and observed ratios agreed, indicating that the sodium pump, 'cotransport' and leak wholly account for K+ fluxes in human red blood cells. For Na+, the ratios did not agree and a 1:1 Na+/Na+ exchange did not account for the discrepancy. Pathways for Na+ appear to be more numerous than for K+.     

The effect of cellular calcium on Na+/K+ cotransport in human red blood cells

The increase in Ca²⁺ permeability by addition of ionophore A23187 in the presence of external Ca²⁺ did not alter the bumetanide-sensitive Na⁺/K⁺ effluxes in human red blood cells. An inhibition of this pathway by cellular Ca²⁺ could be observed only under conditions in which the cellular ATP content was drastically depleted.     

Effects of quinine on Ca++-induced K+ efflux from human red blood cells

Summary The Ca⁺⁺-mediated increase in K⁺-permeability of intact red blood cells (Gardos effect) was initiated by exposing cells to known concentrations of Ca⁺⁺ (using EGTA buffers) in the presence of the ionophore A23187. The potency of quinine, an inhibitor of the response, was found to depend on the external K⁺ concentration. In K⁺-free solutions the concentration of quinine to achieve 50% inhibition (K ₅₀) was 5 m, but at 5mm K⁺ the required concentration was increased 20-fold to 100 m. An increase in internal Na⁺ had the opposite effect, allowing a high potency of quinine despite the presence of external K⁺. Alterations in the internal K⁺ level, on the other hand, were without effect on theK ₅₀, suggesting that the membrane potential is not a factor. This conclusion is supported by the lack of effect on quinine inhibition of substitution of Cl^– by NO ₃ ^– , a considerably more permeant anion. The data are consistent with the hypothesis that quinine inhibits by competitively displacing K⁺ from an external binding site, the reported K⁺-activation site for the Ca⁺⁺-mediated K⁺-permeability.     

Age decline in the activity of the Ca2+-sensitive K+ channel of human red blood cells

The Ca(2+)-sensitive K(+) channel of human red blood cells (RBCs) (Gardos channel, hIK1, hSK4) was implicated in the progressive densification of RBCs during normal senescence and in the mechanism of sickle cell dehydration. Saturating RBC Ca(2+) loads were shown before to induce rapid and homogeneous dehydration, suggesting that Gardos channel capacity was uniform among the RBCs, regardless of age. Using glycated hemoglobin as a reliable RBC age marker, we investigated the age-activity relation of Gardos channels by measuring the mean age of RBC subpopulations exceeding a set high density boundary during dehydration. When K(+) permeabilization was induced with valinomycin, the oldest and densest cells, which started nearest to the set density boundary, crossed it first, reflecting conservation of the normal age-density distribution pattern during dehydration. However, when Ca(2+) loads were used to induce maximal K(+) fluxes via Gardos channels in all RBCs (F(max)), the youngest RBCs passed the boundary first, ahead of the older RBCs, indicating that Gardos channel F(max) was highest in those young RBCs, and that the previously observed appearance of uniform dehydration concealed a substantial degree of age scrambling during the dehydration process. Further analysis of the Gardos channel age-activity relation revealed a monotonic decline in F(max) with cell age, with a broad quasi-Gaussian F(max) distribution among the RBCs.     

Sensitivity and reversibility of Ca-dependent inhibition of the (Na+ + K+)-ATPase of human red blood cells

The sensitivity of the (Na⁺ + K⁺)-ATPase to inhibition by Ca was increased 30-fold by a partially purified extract of human red cell hemolysate. The hemolysate fraction reduced the concentration of free Ca required for 50% inhibition from 30 μM to approx. 1 μM. Ca-dependent inhibition of the (Na⁺ + K⁺)-ATPase in the presence and absence of the hemolysate fraction was completely reversible. The hemolysate fraction also stimulated the Ca²⁺-ATPase and increased its affinity for Ca. In the presence of the hemolysate fraction, the concentration of free Ca that inhibited the (Na⁺ + K⁺)-ATPase by 50% was similar to that which half-maximally stimulated the Ca²⁺-ATPase. Boiling the fraction destroyed its effect on the (Na⁺ + K⁺)-ATPase, but did not impair its stimulation of the Ca²⁺-ATPase.