Some effects of low pH on chloride exchange in human red blood cells

In order to test the range of pH values over which the titratable carried model for inorganic anion exchange is valid, chloride self-exchange across human red blood cells was examined between pH 4.75 and 5.7 at 0 decrees c. It was found that chloride self-exchange flux had a minimum near pH 5 and increased again with further increase in hydrogen ion activity. The Arrhenius activation energy for chloride exchange was greatly reduced at low pH values. The chloride flux at pH 5.1 did not show the saturation kinetics reported at higher pH values but was proportional to the value of the chloride concentration squared. In addition, the extent of inhibition of chloride self-exchange flux by phloretin was reduced at low pH. Our interpretation of these findings is that the carrier-mediated flux becomes a progressively smaller fraction of the total flux at lower pH values and that a different transport mode requiring two chloride ions to form the permeant species and having a low specificity and temperature dependence becomes significant below pH5. A possible mechanism for this transport is that chloride crosses red cell membranes as dimers of HCl at these very low pH values.     

Mechanism of activation by anions of phosphoglycolate phosphatases from spinach and human red blood cells

Phosphoglycolate phosphatases from spinach and human red blood cells show a number of common features not often found in enzymes. Both enzymes are activated more than 50-fold by millimolar concentrations of Cl-. Other inorganic anions and a number of carboxylic acids also activate. Each enzyme has limited substrate specificity yet each hydrolyzes P-glycolate and ethyl-P with the same maximal velocity. L-P-lactate is only a good substrate for the red cell enzyme. With both enzymes initial rate data obtained by varying both the P-glycolate and Cl- give parallel line double reciprocal plots. Similar experiments with ethyl-P as substrate give intersecting lines with both enzymes. The likelihood that both classes of substrates are acting at the same site is strengthened by the results of inhibition studies with alternative substrates and the constancy of inhibition constants for glycolate with all substrates for a given enzyme. For each substrate the experimentally observed variation in V/Km with different activators is small, suggesting that the enzyme has an ordered mechanism with the phosphorylated substrate reacting first. A mechanism that is consistent with all of the data is presented.     

Quantitation of the in vitro free cholesterol exchange of human red cells and lipoproteins

The exchange of free cholesterol in vitro between human red blood cells and low density lipoproteins (LDL) was quantified. The flux of sterol between LDL and red cells was relatively constant over a wide range of concentrations of free cholesterol in lipoproteins. In a system containing a suspension of red blood cells in a mixed solution of high density lipoproteins (HDL) and LDL, the fractional rate of exchange of HDL cholesterol was most rapid followed by LDL and lastly, by red cells. Increasing the ionic strength of the incubation media had no effect on the exchange of cholesterol between LDL and red cells. However, when both HDL and LDL were incubated with red cells in a buffer of increased ionic strength, total red cell cholesterol exchange was unaltered, but proportionately more exchange occurred with HDL and less with LDL. Addition of acetone to the buffer increased the exchange of cholesterol between LDL and red cells but produced no increment in red cell-HDL exchange.     

The effect of anions on Mg-ATPase in red blood cells.

Anions exert an influence on the passive permeability of Na+ and K+ in erythrocytes. THE EFFECT ON Mg-ATPase activity has been studied in human erythrocytes. 40 mM bicarbonate increased the activity as compared to the effect of 40 mM chloride; 20 mM sulphate inhibited it. Salicylate acted first as an activator then as an inhibitor of Mg-ATPase; maximum activity was reached at 60 mM CONCENTRATION. Thiocyanate inhibited saponin-stimulated Mg-ATPase, Ki = 1.85 X 10(-2)M. The probable mechanisms of action of the above anions on Mg-ATPase and possible relation to passive permeability of Na+ and K+ ions are discussed.     

Non-pumped sodium fluxes in human red blood cells. Evidence for facilitated diffusion.

Unidirectional and net Na+ fluxes modified by changes in internal Na+ concentration ([Na+]i) were studied in human red blood cells incubated in K+-free solutions containing 10-minus 4 m ouabain. An increase in [Na+]i brought about (a) a reduction in net Na+ gain, (b) no change in Na+ influx, (c) a reduction in the rate constant for Na+ effux and (d) an increase in Na+ efflux. Similar reductions in net Na+ gain were observed when the changes in [Na+]i were carried out at constant [K+]i. In addition, the rate constant for 42K+ efflux was not affected by changes in [Na+]i. The electrical membrane potential (as determined from the chloride distribution ratio) was also constnat. Furosemide (10-minus 3 M) increased the net Na+ gain in concentration reduced Na+ efflux and increased Na+ influx: the magnitude of these effects was dependent onthe intracellular Na+. The reduction in the net Na+ gain as [Na+]i increased was unaffected by depletion of cellular ATP to values below 10 mumol/1 cells, and this effect was independent of the depletion method used     

K-Permeabilized human red cells lose an alkaline,hypertonic fluid containing excess K over diffusible anions

Summary Experiments were performed to test specific predictions of an integrated red cell model developed by Lew and Bookchin [Lew, V.L., Bookchin, R.M.J. Membrane Biol. 92:57–74 (1986)], that K-permeabilized human red cells suspended in low-K media would dehydrate and lose an alkaline, hypertonic fluid with excess K over accompanying anions, and that cell dehydration would precede medium alkalinization. Red cells were suspended at about 30% hematocrit in an initially K-free Na-saline and permeabilized to K by the addition of valinomycin. The results showed that by the time a quasi-steady state had been reached the cells had lost the equivalent of a hypertonic fluid containing about 180 mM KCl (SCN) and 10 mM KOH, and that cell dehydration did precede alkalinization of the medium, in good agreement with the theoretical predictions. Since these experiments critically test the interaction between transport, pH and volume regulatory functions in the human red cell, the observed agreement validates the basic assumptions and structure of the integrated model. The functional implications of these results are discussed.     

Effects on water diffusion of inhibitors affecting various transport processes in human red blood cells.

The water permeability of human red blood cells has been monitored by nuclear magnetic resonance (NMR) following exposure to inhibitors of various transport processes across their membranes. No significant inhibition of water diffusion could be detected after the treatment of red blood cells with the anion exchange transport inhibitor dihydro-4,4'-diisothiocyano-stilbene-2,2'-disulfonate (H2DIDS) or the glucose transport inhibitors diallyl-diethyl-stilbestrol (DADES), cytochalasin B, or 30 mM iodoacetamide. It is for the first time that the effects of glucose transport inhibitors has been studied in detail by the NMR approach. A special case proved to be phloretin, an inhibitor of anion, nonelectrolyte and glucose permeability. A small but statistically significant inhibition of water permeability (around 12% at 20 degrees C) was induced by exposure to 2 mM phloretin (for 60 min at 37 degrees C); after a pretreatment of cells with 12 mM N-ethylmaleimide (NEM), for 60 min at 37 degrees C, the degree of inhibition induced by phloretin increased (becoming 17% at 20 degrees C). None of the inhibitors prevented or potentiated the strong inhibitory effect on water diffusion of a mercurial, p-chloromercuribenzene sulfonate (PCMBS). No increase in the activation energy of water diffusion occurred by treatment with the reagents used (exception the effect of PCMBS). The present results clarify some conflicting reports concerning the effects on water permeability of inhibitors of various transport processes in red blood cells and indicate that in addition to the drastic inhibition induced by mercurials other reagents may also have inhibitory effects.     

Chemical modification of membrane proteins in relation to inhibition of anion exchange in human red blood cells

Mono-, di-, and trisulfonic acids, including 4,4′-diacetamido stilbene-2,2′-disulfonic acid (DAS) and 2-(4′-amino phenyl)-6-methylbenzene thiazol-3′,7-disulfonic acid (APMB) produce a reversible inhibition of sulfate equilibrium exchange in human red cells. A study of the sidedness of the action of a number of these sulfonic acids in red cell ghosts revealed that some, like DAS, inhibit only at the outer membrane surface while others, like APMB, inhibit at either surface. This finding suggests that at least two different types of membrane sites are involved in the control of anion permeability. The nature of the anion permeability controlling sites in the outer cell surface was investigated by studying the effects of DAS on the inhibition by dinitrofluoro-benzene (DNFB) of anion equilibrium exchange and on the binding of DNFB to the proteins of the red blood cell membrane. After exposure to DNFB in the presence of DAS for a certain period of time, there was a reduction of both the inhibitory effect of DNFB on sulfate exchange and the binding of DNFB to the protein in band 3 of SDS polyacrylamide gel electropherograms (nomenclature of Steck, J. Cell. Biol., 62: 1, 1974). Since binding to other membrane proteins was not affected, this observation supports the assumption that the protein in band 3 plays some role in anion transport. In accordance with the absence of an inhibitory effect at the inner membrane surface, internal DAS does not affect DNFB binding to the protein in band 3. DAS protected the anion exchange system not only against inhibition by DNFB but also by m-isothiocyanato benzene sulfonic acid. In contrast to DAS, the equally inhibitory phlorizin does not reduce the rate of dinitrophenylation of the protein in band 3. This suggests that either not all inhibitors of anion exchange exert their action by a combination with sites on the protein in band 3 or that in spite of the described evidence this protein is not involved in the control of anion movements. The effect of the irreversibly binding inhibitor 4-acetamido-4′-isothiocyanato-stilbene-2,2′-disulfonic acid (SITS) on DNFB binding to the protein in band 3 was studied in an attempt to differentiate DNFB binding related to inhibition of anion permeability from DNFB binding which is not involved. At least three distinguishable populations of DNFB binding sites were found: (1) binding sites common for DNFB and SITS which are probably related to inhibition, (2) other common sites which are not related to inhibition and (3) different sites whose dinitrophenylation is not affected by SITS. The number of sites in population (1) was estimated to be 0.8–1.2 ± 10⁶/cell. A study of the concentration dependence of the inhibition of anion equilibrium exchange with 4,4′-isothiocyanato-2,2′-stilbene disulfonic acid (DIDS) and APMB further suggests that among the sites in population (1) a major fraction is susceptible to modification by APMB and DIDS while the rest is only susceptible to DIDS. It remains undecided whether these differences of susceptibility reflect differences of accessibility or reactivity.     

Single-file diffusion through the Ca2+-activated K+ channel of human red cells

Summary We have examined the effect of internal and external pH on Na⁺ transport across toad bladder membrane vesicles. Vesicles prepared and assayed with a recently modified procedure (Garty & Asher, 1985) exhibit large, rheogenic, amiloridesensitive fluxes. Of the total²²Na uptake measured 0.5–2.0 min after introducing tracer, 80±4% (mean±se,n=9) is blocked by the diuretic with aK ₁ of 2×10^–8 m. Thus, this amiloridesensitive flux is mediated by the apical sodium-selective channels. Varying the internal (cytosolic) pH over the physiologic range 7.0–8.0 had no effect on sodium transport; this result suggests that variation of intracellular pHin vivo has no direct apical effect on modulating sodium uptake. On the other hand,²²Na was directly and monotonically dependent on external pH. External acidification also reduced the amiloride-sensitive efflux across the walls of the vesicles. This inhibition of²²Na efflux was noted at external Na⁺ concentrations of both 0.2 m and 53mm.These results are different from those reported with whole toad bladder. A number of possible bases for these differences are considered and discussed. We suggest that the natriferic response induced by mucosal acidification of whole toad urinary bladder appears to operate indirectly through one or more factors, presumably cytosolic, present in whole cells and absent from the vesicles.     

Alpha-mannosidase in human red cells.

1. A search for lysosomal hydrolases and related enzymes has been made in hemolysates from human and rabbit red cells. Apart from acid phosphatases, significant activities were found only for alpha-mannosidase, neutral alpha-glucosidase and beta-hexosaminidase. 2. alpha-Mannosidase (alpha-D-mannoside mannohydrolase, EC 3.2.1.24) activity per cell in human red blood cells was 200-times lower than in white cells. The optimal pH was 5.5--6.0. Electrophoresis on cellulose acetate showed three bands. Hemolysates from four patients with mannosidosis were not deficient in alpha-mannosidase. pH activity curves and elctrophoretic pattern were similar to those of controls. From its biochemical and genetic properties, it is concluded that red cell mannosidase differs from the lysosomal acid mannosidase.