Na+-ATPase of mammalian erythrocyte membranes: kinetic changes associated with postnatal development and following active erythropoiesis

L antigens of sheep red blood cell membranes and modulation of ion transport

Sheep are polymorphic with respect to the intracellular Na+ and K+ concentrations of their erythrocytes. Erythrocytes of sheep of the high-K+ (HK) phenotype have high K+ and low Na+ concentrations; erythrocytes from sheep of the allelic low-K+ (LK) phenotype have abnormally low K+ and high Na+ concentrations. The difference is due to differences in rates of cation transport: higher Na+-K+ pump flux in HK cells and higher K+-Cl- cotransport in LK cells. The HK/LK polymorphism is associated with a polymorphism of red blood cell antigens: the L antigen is only on LK cells, and HK cells have only the M antigen. There are two classes of L antigen that assort together: Lp, which is associated with Na+-K+ pumps, and Ll, which is associated with K+-Cl- cotransporters. There are functional consequences of these associations: anti-Lp antibody stimulates the pump and anti-Ll antibody inhibits cotransport. The use of these antibodies has permitted delineation of the roles of the antigens in modulating the function of the transporters. In this review, we summarize the evidence that these antigens are entities distinct from the pump. The Lp antigen reacts reversibly with the Na+-K+ pump; the antigen inhibits the pump, mainly by promoting nonspecific inhibition by intracellular K+. The antigen also modulates pump differentiation in immature cells. In contrast, the Ll antigen stimulates K+-Cl- cotransport. The evidence suggests that the two polymorphisms are controlled by a single genetic locus and that all of the distinct properties of ion transporters in LK cells are attributable to interactions with L antigens.

Decline in number of Na-K pumps on low-K+ sheep reticulocytes during maturation is modulated by Lp antigen

The number of the Na-K pumps on sheep red blood cells declines markedly during cell maturation. In addition, in red blood cells of the low-K+ (LK) phenotype, there is an increase during maturation in the affinity of the pumps for intracellular K+. This increase does not occur in cells of the high-K+ (HK) phenotype. This HK/LK polymorphism is associated with the M/L blood group antigen system. The Lp antigen, which is on only LK cells, promotes the increase in affinity for K+ [Am. J. Physiol. 265 (Cell Physiol. 34): C99-C105, 1993]. Mature LK cells have fewer pumps than mature HK cells. The present study shows that the Lp antigen also promotes the loss of pumps in LK cells. The evidence was that modification of the Lp antigen of immature LK red blood cells either with anti-Lp antibody or by trypsinization diminished the loss of pumps during culture in vitro (numbers determined from [3H]ouabain binding). Confirmation came from demonstration of the decline during maturation of the amount of the alpha-subunit of the Na-K pump (measured by immunoblotting), which was also retarded by pretreatment with anti-Lp or trypsin. Comparisons of the relative amounts of Lp antigen on immature and mature LK cells showed that there is little decline in number of antigens during maturation. Therefore there is an increase in the antigen-to-pump ratio during maturation even though an association between pumps and antigens is necessary for the loss of pumps.

Cell volume and K+ transport during differentiation of mouse erythroleukemia cells

In the present study, we evaluated the changes in cell volume, water content, and K+ transport in mouse erythroleukemia (MEL) cells during the transition from proerythroblast to young reticulocyte. When MEL cells were exposed to 1.8% dimethyl sulfoxide (DMSO) for a maximum of 7 days, they synthesized hemoglobin and reduced their volume by 66% while maintaining their water content. The total protein content decreased by 50%. We therefore concluded that the volume reduction was due to a loss of cellular material, water, and osmolytes. To evaluate the changes in pump and leak pathways, we performed 86Rb uptakes in the presence or absence of selected inhibitors. In undifferentiated cells, the uptake was mainly represented by the Na-K-2Cl cotransport (51%) and by the Na(+)-K+ pump (34%). A small portion of the uptake was mediated by barium- and quinidine-sensitive K+ channels (8%) and by the furosemide-sensitive K-Cl cotransporter (5%). After 4 days in DMSO, the 86Rb uptake was reduced by 57%, mainly due to a substantial (90%) decrease in Na-K-2Cl cotransport activity. The Na(+)-independent K-Cl cotransport activity also dramatically decreased by a factor of 10. In contrast, the Na(+)-K+ pump activity did not change after 4 days in DMSO. These results demonstrate a marked reduction in the activities of inorganic ion cotransport systems as red blood cells differentiate to reticulocytes. Our study also demonstrates that a strong correlation exists between cell volume reduction and a decrease in the main inward leak pathway for K+: the Na-K-2Cl cotransporter.

Differentiation of Na(+)-K+ pumps of low-K+ sheep red blood cells is promoted by Lp membrane antigens

Na(+)-K+ pumps of red blood cells from sheep of the low-K+ (LK) phenotype undergo differentiation during circulation, manifested in part by a striking increase in sensitivity to inhibition by intracellular K+ (Ki). Pumps of red blood cells from sheep from the allelic phenotype, high K+ (HK), do not undergo this type of maturation. The hypothesis was tested that the Lp antigen, found on LK but not HK cells, is responsible for the maturation of LK pumps. Lp antigens have been shown to inhibit LK pumps because anti-Lp antibody stimulates the pumps by relieving inhibition by the antigen. Lp antigens were recently shown to be molecular entities separate from Na(+)-K+ pumps [Xu, Z.-C., P. Dunham, J. Munzer, J. Silvius, and R. Blostein. Am. J. Physiol. 263 (Cell Physiol. 32): C1007-C1014, 1992]. The test of the hypothesis was to modify the Lp antigens of immature LK red blood cells with two kinds of treatments, anti-Lp antibody and trypsinization (which cleaves Lp), and to observe the effects of these treatments on maturation of pumps during culture of the cells in vitro. Both of these treatments prevented the maturation of the kinetics of the pumps to the Ki-sensitive pattern, supporting the hypothesis that interaction of the pumps with Lp antigens is responsible for the maturation of the pumps. Strong supportive evidence came from experiments on Na(+)-K+ pumps from rat kidney delivered into immature LK sheep red blood cells by microsome fusion.(ABSTRACT TRUNCATED AT 250 WORDS)

Decrease in Na(+)-K(+)-ATPase associated with maturation of sheep reticulocytes

Na(+)-K(+)-ATPase of immature and mature sheep red blood cells of both the high-K+ and low-K+ genotype and of immature cells matured in vitro was detected using polyclonal antiserum to purified sheep kidney Na(+)-K(+)-ATPase. This antiserum detects both alpha (alpha 1)- and alpha + (alpha 2 and/or alpha 3)-isoforms of the catalytic subunit as well as the beta-subunit of brain and kidney Na(+)-K(+)-ATPase. After sodium dodecyl sulfate-polyacrylamide gel electrophoresis and immunoblotting, a single major immunologically reactive component corresponding to the alpha-subunit was detected in membranes of immature and mature cells from sheep of both genotypes. Cells separated according to increasing density showed a corresponding decrease in ouabain binding sites on the cells and Na(+)-activated ATP hydrolysis of membranes isolated from the cells. A progressive decrease in immunologically reactive alpha-subunit was also observed. After in vitro culture of reticulocytes, reduction in ouabain binding to the cells was also associated with loss in alpha-subunit. As well, appearance of immunologically reactive alpha-subunit was detected in membranous material shed into the incubation medium, accounting for a fraction (less than or equal to 30%) of the material lost from the cells. Proteolytic sensitivity of the alpha-subunit indicates that, in this material, the cytoplasmic surface of the enzyme is exposed to the medium. The shed material was largely devoid of function as evidenced in little, if any, Na(+)-dependent phosphorylation of Na(+)-K(+)-ATPase. The existence in reticulocytes of an intracellular pool of ouabain binding sites was indicated by the transient appearance on the cell surface of ouabain binding sites after rapid ATP depletion and also after addition of chloroquine to cells during culture. Taken together, these findings indicate that the maturation-associated loss of sodium pump protein involves, at least partly, energy-dependent endocytosis and, presumably, processing whereby inactivation of function occurs as well as release of pump protein into the extracellular milieu.

Comparison of the active calcium extrusion, calcium buffering capacity and ATPase activity in rabbit reticulocytes and mature red cells

The purpose of the present work was to study the changes in the pattern of calcium homeostasis following the loss of intracellular organella during red cell maturation. Reticulocytes and mature red cells were prepared from anaemic rabbits blood after daily bleeding. Experimental protocols were designed to study the calcium buffering capacity in intact and digitonin-disrupted cells, the calcium pumping rate and, the Ca2+-translocating ATPase activity in the aforementioned red cells subpopulations. In digitonin-disrupted cells, a vesicular calcium pool, sharing the properties of mitochondria, could be detected in reticulocytes but no in mature red cells. Calcium content and calcium buffering capacity were significantly lower in reticulocytes than in mature red cells. The pattern of active calcium extrusion was quite similar in the two cell subpopulations, although reticulocytes had somewhat higher calcium affinity. Besides, an estimation of the calcium pumping rate gave higher values in reticulocytes than in mature erythrocytes. These values were 21 and 9 mmol/l cells per h, respectively. Maximal activities of the high-affinity (Ca2+ + Mg2+)-ATPase and basal Mg2+-ATPase were significantly higher in reticulocytes than in mature red cells, but no differences were observed regarding calcium affinity. The results show that changes in the properties of the Ca2+-translocating ATPase and intracellular calcium buffering systems are mechanisms involved in the process of red cell maturation.

Energy depletion retards the loss of membrane transport during reticulocyte maturation

The effect of metabolic depletion on the maturation-associated loss of membrane functions has been studied by using sheep reticulocytes incubated in vitro at 37 degrees C for periods up to 41 hr. ATP was either maintained with glucose, adenosine plus inosine, or depleted with 2-deoxyglucose plus arsenate. Two membrane transport systems were studied: Na+-dependent glycine transport activity and the sodium pump, estimated from measurements of the number of [3H]ouabain binding sites per cell. Both transport systems were decreased during maturation. However, the decrease was much less in ATP-depleted cells compared to ATP-replete cells. It is concluded that the loss of certain functions during reticulocyte maturation is retarded by metabolic depletion.

Bilirubin adsorption in vitro by foetal and adult human erythrocytes

Adsorption of bilirubin in vitro by human foetal erythrocytes from umbilical cords was significantly greater than the binding by adult erythrocytes. A difference in binding capacity was detected at 0.6 mmol/l bilirubin concentration (bilirubin/albumin ratio 2:1) immediately after mixing with the bilirubin solution. After 30 min incubation a further increase in bound bilirubin was found to be due only to binding in foetal cells. The results suggest that bilirubin from the medium was incorporated into at least two compartments in foetal erythrocytes. A possible role of human foetal erythrocytes in bilirubin distribution to tissues is stressed.

Enzymic characteristics of ecto-adenosine triphosphatase in rat epididymal intact spermatozoa

Ecto-ATPase in rat cauda-epididymal intact spermatozoa has a high degree of substrate specificity for the hydrolysis of ATP and dATP rather than of ADP, AMP, GTP, dGTP, CTP, dCTP, TTP and UTP. The enzyme is activated by bivalent metal ions in the order Mg2+ greater than Mn2+ greater than Co2+ greater than Ca2+. The apparent Km values of the enzyme for Mg2+, Mn2+, Co2+ and Ca2+ are approx. 80, 100, 100 and 150 microM respectively. Addition of Ca2+ (0.1 or 1 mM) gives no further stimulation of the Mg2+-activated ecto-ATPase activity. The apparent Km value of the enzyme for ATP is 95 microM. Pi (16 mM) inhibits the enzymic activity (by 25%), whereas Na+ (50 mM) or K+ (10 mM) alone or in combination, polyamines (spermine and spermidine; 1--12.5mM) and nucleic acids (yeast RNA and calf thymus DNA; 0.12 or 0.62 mg/ml) had no significant effect on the activity of the enzyme. Orthovanadate at a relatively low concentration (20 microM) strongly inhibits (approx. 50%) the ecto-ATPase activity. Vanadate inhibition can be reversed by noradrenaline (2.5 mM). The vanadate-sensitivity of the enzyme increases markedly during spermatozoal maturation in the epididymis. However, the activity of the spermatozoal ecto-ATPase decreases progressively during the epididymal transit of the testicular spermatozoa.

Cation transport in different volume populations of genetically low K+ lamb red cells

During the first three months after birth lambs produce sequentially three erythrocyte populations of different mean volume as demonstrated by electric sizing methods (Valet, Franz, and Lauf, J. Cell. Physiol. 94 (1978) 215). We separated by centrifugal elutriation the small volume population (type II) red cells of a genotypically low K+ (LK) lamb from the population containing the larger volume type I and III cells, an admixture of fetal (I) and adult (III) erythrocytes. The cells were separated at various time intervals after birth and analyzed with respect to their volumes, cation contents, and cation flux properties by means of 86Rb uptake. The effect of anti-L on K+ pump and leak fluxes was ascertained in unseparated and separated red cells. It was found that the small red cells of population II, transiently present for several weeks, were fully developed LK cells with K+ pumps responding characteristically to the stimulatory action of anti-L. In constrast, the larger cells of population I and III were of high K+ (HK) nature at early time points, the K+ pump activities approximately ten times higher than adult LK cells. These cells constitute an admixture of type I fetal HK cells, and type III reticulocytes which are precursors for the final type III adult LK cells, since anti-L had a small stimulatory effect. At later times, however, only adult type III LK cells predominated. The data directly support our earlier finding that the HK-LK transition in genotypically LK lambs is primarily governed by cellular replacement.

LK sheep reticulocytosis: effect of anti-L on K influx and in vitro maturation

After massive hemorrhage, adult sheep with genotypically low potassium (LK) red cells temporarily produce high potassium (HK) cells with ouabain-sensitive K+ pump fluxes equivalent to mature HK red cells. In light of recent reports of different red cell volume populations accompanying the HK-LK transition also occurring in newborn LK sheep and the unresolved controversy over the effect of anti-L on K+ transport in these immature red cells, we have reexamined the K+ transport changes and the effect of anti-L in the newly formed HK cells at various times after anemic stress and under in vitro conditions. We found that approximately 7 d after bleeding, maximum reticulocytosis occurred in the peripheral blood. After separation by density centrifugation, the top 10% cell fraction contained 100% reticulocytes, with a mean cell volume 2.5 times larger than that of mature erythrocytes. These immature red cells were of HK type, and their K+ pump and leak fluxes were 30 and 10 times higher, respectively, than those found in mature LK cells. The new cells may possess HK- and LK-type pumps because K+ pump influx was significantly stimulated by anti-L. When separated by density centrifugation on days 9, 17, and 23 after bleeding, some of the cells apparently maintained their large size while gaining higher density. Large cells from day 9, kept in vitro for 22 h, showed anti-L-sensitive K+ pump and leak fluxes that declined within hours, paralleling the behavior of these cells in vivo, whereas cellular K+ levels changed much less. It is concluded that the newly formed red cells may belong to a stress-induced macrocytic cell population that does not acquire all of the characteristics of adult LK cells.

Active potassium transport in reticulocytes of high-K+ and low-K+ sheep

The kinetics of active K+ transport were studied in immature red blood cells cells from high-K+ and low-K+ sheep particulary with respect to the effects of varying intracellular K+ concentration, [K]i. Comparison was made with active transport, or pump, activity in mature high-K+ and low-K+ red cells. Reticulocytes from both types of sheep had much higher maximal active K+ influxes than did mature cells. In both types of reticulocytes, and in mature high-K+ cells as well, the pump was relatively insensitive to increasing [K]i. In contrast, intracellular K+ markedly inhibited the pump in mature low-K+ cells. Active K+ transport in low-K+ reticulocytes, however, as in mature low-K+ cells, is stimulated by specific isoimmune anti-L serum. Therefore the K+ pumps of high-K+ and low-K+ reticulocytes have similar kinetic properties. Maturation of the red cells, involving inactivation of most of the pump activity in both cell types, results in mature high-K+ and low-K+ cells with K+ pumps of very different kinetic characteristics.