Inhibition of phosphate transport in human erythrocytes by water-soluble carbodiimides

Phosphate entry into human erythrocytes is irreversibly inhibited by treatment of the cells with the water-soluble carbodiimides 1-ethy1-3-(3-dimethylaminopropyl)carbodiimide hydrochloride (EDC) and 1-cyclohexyl-3-(2-morpholinoethyl)-carbodiimide metho-p-toluene sulfonate (CMC) in the absence of added nucleophile. EDC is the more potent inhibitor (40% inhibition, 2 mM EDC, 5 min, 37°C, 50% hematocrit, pH 6.9), while more than 20 mM CMC is required to give the same inhibition under identical conditions. EDC inhibition is temperature-dependent, being complete in 5 min at 37°C, and sensitive to extracellular pH. At pH 6.9 only 50% of transport is rapidly inhibited by EDC, but at alkaline pH over 80% of transport is inhibited. Inhibition is not prevented by modification of membrane sulfhydryl groups but is decreased in the presence of 4,4′-dinitrostilbene-2,2′-disulfonic acid (DNDS), a reversible competitive inhibitor of anion transport. EDC treatment leads to crosslinking of erythrocyte membrane proteins, but differences between the time course of this action and inhibition of transport indicate that most transport inhibition is not due to crosslinking of membrane proteins.     

Inhibition of phosphate transport in human erythrocytes by water-soluble carbodiimides

Phosphate entry into human erythrocytes is irreversibly inhibited by treatment of the cells with the water-soluble carbodiimides 1-ethyl-3-(3-dimethylaminopropyl)carbodiimide hydrochloride (EDC) and 1-cyclohexyl-3-(2-morpholinoethyl)-carbodiimide metho-p-toluene sulfonate (CMC) in the absence of added nucleophile. EDC is the more potent inhibitor (40% inhibition, 2 mM EDC, 5 min, 37 degrees C, 50% hematocrit, pH 6.9), while more than 20 mM CMC is required to give the same inhibition under identical conditions. EDC inhibition is temperature-dependent, being complete in 5 min at 37 degrees C, and sensitive to extracellular pH. At pH 6.9 only 50% of transport is rapidly inhibited by EDC, but at alkaline pH over 80% of transport is inhibited. Inhibition is not prevented by modification of membrane sulfhydryl groups but is decreased in the presence of 4,4'-dinitrostilbene-2,2'-disulfonic acid (DNDS), a reversible competitive inhibitor of anion transport. EDC treatment leads to crosslinking of erythrocyte membrane proteins, but differences between the time course of this action and inhibition of transport indicate that most transport inhibition is not due to crosslinking of membrane proteins.     

Glucose transport inhibition in human erythrocytes by calmodulin antagonists

Calmodulin antagonists (tryphtazin, lidocaine, dykain, palmitate) inhibit glucose transport from human erythrocytes. Glucose efflux inhibition is proportional to the concentration of antagonists in the medium and is of uncompetitive character. It is accompanied by a decrease in the maximum transport rate with the unchanged constant of dissociation in the complex: carrier-sugar. Calcium ionophores A23187 and divaleryldibenzo-18-crown-6 eliminated the inhibiting effect of pharmacological agents on glucose transport. The authors think that the glucose transport inhibition under the influence of calmodulin antagonists may be realized through the calmodulin-dependent chain inhibition under the influence of calmodulin antagonists in the carbohydrate transport system.     

p-(Chloromercuri)benzenesulfonate binding by membrane proteins and the inhibition of water transport in human erythrocytes

The binding of [203Hg]-p-(chloromercuri)benzenesulfonate to the membrane proteins of human erythrocytes and erythrocyte ghosts was examined under conditions where binding to the bulk of membrane sulfhydryl groups was blocked by N-ethylmaleimide. Binding was essentially complete within 90 min when approximately 40 nmol was bound per milligram of membrane protein. This binding was correlated with the inhibition of water transport measured by an NMR technique. Maximal inhibition was observed with the binding of approximately 10 nmol of p-(chloromercuri)benzenesulfonate/mg of membrane protein. Under these conditions, both band 3 and band 4.5 bound 1 mol of inhibitor/mol of protein. In contrast to previous experiments, these results indicate that band 4.5 proteins as well as band 3 have to be considered as playing a role in water transport.     

The inhibition of hexose transport by permeant and impermeant sulfhydryl agents in rat adipocytes

The importance of exofacial sulfhydryl groups for hexose transport and its regulation was studied by comparing the effects of plasma membrane-permeant maleimide (N-ethylmaleimide) to an impermeant maleimide (glutathione-maleimide I) on 3-O-methylglucose transport into isolated rat adipocytes. The impermeant nature of glutathione-maleimide was confirmed by the finding that after a 15-min incubation, concentrations as high as 10 mM had no effect on intracellular glutathione content, while 1.7 mM N-ethylmaleimide decreased intracellular glutathione by 61%. Although N-ethylmaleimide appeared to be a more potent inhibitor of transport below 5 mM and at incubation times of less than 5 min, neither agent at concentrations which did not cause significant cell breakage inhibited basal transport rates more than 60-70%. The inhibition of transport by both agents was unaffected by extensive washing, suggesting a possible covalent interaction with the carrier. Preincubation with p-chloromercuribenzenesulfonic acid protected against the transport inhibition induced by both agents. However, only the transport inhibition induced by glutathione-maleimide was prevented by preincubation with D-glucose (50 mM) and maltose (50 mM). Transport in cells pretreated with insulin was inhibited by both agents to a similar extent as basal transport. However, treatment of cells with the maleimides before insulin caused a greater degree of inhibition. Thus, the insulin-induced increase in transport was inhibited half-maximally by 1 mM glutathione-maleimide. These results show that exofacial sulfhydryl groups, perhaps on the hexose-binding site of the carrier, are important for both the function and regulation of hexose transport.     

Reversible inhibition of anion exchange in human erythrocytes by an inorganic disulfonate,tetrathionate

Summary Tetrathionate (S₄O ₆ ^–– ) markedly inhibits anion exchange across the human erythrocyte membrane. This phenomenon has been studied in order to obtain further insight into the mechanism of action of reversible inhibitors, in particular disulfonate inhibitors, of anion exchange. Anion fluxes were measured by tracer techniques at equilibrium. The following results were obtained: Tetrathionate, although an inorganic compound, inhibits the self-exchange of sulfate and of divalent organic anions (oxalate, malonate) noncompetitively atK _i values (0.5mm) as yet only observed for amphiphilic inhibitors. The inhibitor is effective only from the outside of the cell. The inhibition is temperature-dependent,K _i increasing by a factor of 5 between 5 and 35°C, and instantaneously and fully reversible. The presence of small monovalent anions (fluoride, bromide, chloride, nitrate, acetate) counteracts inhibition by tetrathionate to a varying and concentration-dependent extent, divalent anions have only a minor effect at high concentrations. Chloride exchange is also inhibited, while glycolate and lactate fluxes are much less sensitive or almost insensitive, in agreement with their alleged transfer by a different transport system. Tetrathionate is unique in its inhibitory action, its structural congeners, peroxodisulfate (S₂O ₈ ^–– ) and ethanedisulfonate (C₂H₄S₂O ₆ ^–– ) are much less effective.The results can be interpreted by assuming that tetrathionate inhibits the movement of anions via the inorganic anion exchange system by binding-in a 11 stoichiometry-to inhibitory modifier sites, for which it competes with other anions. These sites are located only on the exofacial surface of the membrane. The high affinity of tetrathionate is probably due to a local excess of electrons in the region of its central disulfide bond. These may stabilize the binding by their ability to form electron donor-acceptor complexes with membrane sites, thus compensating for the absence of a hydrophobic binding domain in tetrathionate.     

Reversible and irreversible modification of erythrocyte membrane permeability by electric field

Electric fields of a few kV/cm and of duration in microseconds are known to implant pores of limited size in cell membranes. We report here a study of kinetics of pore formation and reversibility of pores. Loading of biologically active molecules was also attempted. For human erythrocytes in an isotonic saline, pores allowed passive Rb+ entry formed within 0.5 microsecond when a 4 kV/cm electric pulse was used. Pores that admitted oligosaccharides were introduced with an electric pulse of a longer duration in an isosmotic mixture of NaCl and sucrose. These pores were irreversible under most circumstances, but they could be resealed in an osmotically balanced medium. A complete resealing of pores that admitted Rb+ took approximately 40 min at 37 degrees C. Resealing of pores that admitted sucrose took much longer, 20 h, under similar conditions. In other cell types, resealing step may be omitted due to stronger membrane structures. Experimental protocols for loading small molecules into cells without losing cytoplasmic macromolecules are discussed.     

Reversible inhibition of RNA synthesis and irreversible inhibition of protein synthesis by D-galactosamine in isolated mouse hepatocytes

Summary The inhibition of RNA synthesis of isolated mouse liver parenchymal cells caused by 10 mM D-galactosamine was reversible, while the inhibition of protein synthesis remained unaltered after the removal of galactosamine. 10^–5 M epinephrine and 10^–7 M glucagon have been shown to decrease aminoglycogen formation and thus to reduce the inhibitory effect of galactosamine on protein synthesis (11). However, these hormones did not decrease the inhibition of RNA synthesis. 10 mM D-galactosamine did not effect the nucleoside and amino acid incorporation of isolated non-parenchymal mouse liver cells. The predominant role of aminoglycogen in the inhibition of protein synthesis in galactosamine induced liver injury is discussed.     

Transport and metabolism of adenosine in human erythrocytes: effect of transport inhibitors and regulation by phosphate

Rapid kinetic techniques were applied to determine the effect of transport inhibitors on the transport and metabolism of adenosine in human red cells. Dipyridamole inhibited the equilibrium exchange of 500 microM adenosine by deoxycoformycin-treated cells in a similar concentration dependent manner as the equilibrium exchange and zero-trans influx of uridine with 50% inhibition being observed at about 20 nM. Intracellular phosphorylation of adenosine at an extracellular concentration of 5 microM was inhibited only by dipyridamole concentrations greater than or equal to 100 nM, which inhibited transport about 95%. Lower concentrations of dipyridamole actually stimulated adenosine phosphorylation, because the reduced influx of adenosine lessened substrate inhibition of adenosine kinase. When the cells were not treated with deoxycoformycin, greater than 95% of the adenosine entering the cells at a concentration of 100 microM became deaminated. A 95-98% inhibition of adenosine transport by treatment with dipyridamole, dilazep, or nitrobenzylthioinosine inhibited its deamination practically completely, whereas adenosine phosphorylation was inhibited only 50-85%. Whether adenosine entering the cells is phosphorylated or deaminated is strictly based on the kinetic properties of the responsible enzymes, substrate inhibition of adenosine kinase, and the absolute intracellular steady state concentration of adenosine attained. The latter approaches the extracellular concentration of adenosine, since transport is not rate limiting, except when modulated by transport inhibitors. In spite of the extensive adenosine deamination in cells incubated with 100 microM adenosine, little IMP accumulated intracellularly when the medium phosphate concentration was 1 mM, but IMP formation increased progressively with increase in phosphate concentration to 80 mM. The intracellular phosphoribosylation of adenine and hypoxanthine were similarly dependent on phosphate concentration. The results indicate that adenosine is the main purine source for erythrocytes and is very efficiently taken up and converted to nucleotides under physiological conditions, whereas hypoxanthine and adenine are not significantly salvaged. Hypoxanthine resulting from nucleotide turnover in these cells is expected to be primarily released from the cells. Adenosine was also dephosphorylated in human red cells presumably by 5'-methylthioadenosine phosphorylase, but this reaction seems without physiological significance as it occurs only at high adenosine and phosphate concentrations and if deamination is inhibited.     

Effects of anesthetic alcohols on membrane transport processes in human erythrocytes

1. 1. Anesthetic alcohols (pentanol, hexanol and heptanol) were found to increase the fluidity of red cell membrane lipids as monitored by the fluorescence depolarization of diphenylhexatriene. The relative potency of the alcohols was found to be parallel to their relative membrane/water partition coefficients.

2. 2. Hexanol had biphasic effect on erythritol uptake by simple diffusion by red cells. At concentrations less than 9 mM, hexanol had no significant effect. At concentrations greater than 9 mM, there was an approximately linear increase in erythritol permeability with increasing alcohol concentration.

3. 3. The facilitated transport of uridine was markedly inhibited by hexanol. Hexanol at 6 mM produced a 65% inhibition of uridine (4 mM) uptake. Hexanol decreased both the apparent K_m and V values for the equilibrium exchange of uridine.

4. 4. The facilitated transport of galactose was only slightly inhibited by hexanol.

5. 5. Hexanol was without effect on the passive and active fluxes of Na⁺ and K⁺ in red cells with altered cation contents. Cells that were slightly depleted of K⁺ and cells that were highly K⁺-depleted were both insensitive to hexanol.

Thiamin transport by human erythrocytes and ghosts

Summary Thiamin transport in human erythrocytes and resealed pink ghosts was evaluated by incubating both preparations at 37 or 20°C in the presence of [³H]-thiamin of high specific activity. The rate of uptake was consistently higher in erythrocytes than in ghosts. In both preparations, the time course of uptake was independent from the presence of Na⁺ and did not reach equilibrium after 60 min incubation. At concentrations below 0.5 m and at 37°C, thiamin was taken up predominantly by a saturable mechanism in both erythrocytes and ghosts. Apparent kinetic constants were: for erythrocytes,K _m =0.12, 0.11 and 0.10 m andJ _max=0.01, 0.02 and 0.03 pmol·l^–1 intracellular water after 3, 15, and 30 min incubation times, respectively; for ghosts,K _m =0.16 and 0.51 m andJ _max=0.01 and 0.04 pmol·l^–1 intracellular water after 15 and 30 min incubation times, respectively. At 20°C, the saturable component disappeared in both preparations. Erythrocyte thiamin transport was not influenced by the presence ofd-glucose or metabolic inhibitors. In both preparations, thiamin transport was inhibited competitively by unlabeled thiamin, pyrithiamin, amprolium and, to a lesser extent, oxythiamin, the inhibiting effect being always more marked in erythrocytes than in ghosts. Only approximately 20% of the thiamin taken up by erythrocytes was protein-(probably membrane-) bound. A similar proportion was esterified to thiamin pyrophosphate. Separate experiments using valinomycin and SCN^– showed that the transport of thiamin, which is a cation at pH 7.4, is unaffected by changes in membrane potential in both preparations.     

Specific inhibition of phosphate transport in mitochondria by N-ethylmaleimide

N-ethylmaleimide (NEM), a reagent that alkylates free sulfhydryl groups, was shown to be a highly effective inhibitor of the following coupled mitochondrial processes: oxidative phosphorylation, ATP-³²Pi exchange, Pi-induced light scattering and configurational changes, State III respiration, valinomycin-induced translocation of potassium with Pi as the anion, and calcium accumulation in presence of Pi. However, NEM was less effective or ineffective in inhibiting some processes that do not require inorganic Pi, namely electron transfer and ATPase activity, ADP binding, energized light scattering changes induced by arsenate and nonenergized light scattering changes induced by acetate. The rate of oxidative phosphorylation and of ATP-³²Pi exchange was normal in ETP_H particles prepared from NEM-treated mitochondria. Also NEM, even et levels 2–3 times greater than those required to inhibit oxidative phosphorylation in intact mitochondria, did not inhibit coupled processes in submitochondrial particles. We are proposing that NEM alkylates sulfhydryl groups in the mitochondrion that modulate Pi translocation, and that the suppression of Pi translocation blocks oxidative phosphorylation, the Pi-dependent energized configurational change in mitochondria and Pi-dependent transport processes.On leave of absence from the Department of Biochemistry, Cancer Institute Okayama University Medical School, Okayama, Japan.On leave of absence from the Department of Pathology, Nagoya University Medical School, Nagoya, Japan.     

Partial puridication of a membrane protein from human erythrocytes involved in glucose transport.

In an attempt to determine which membrane proteins are essential to the stereospecific uptake of D-glucose, isolated human erythrocyte membranes were exposed to a variety of reagents capable of selectively extracting various membrane proteins. These reagents included EDTA, lithium 3,5-diiodosalicylate, sodium iodide, and 2,3-dimethylmaleic anhydride. Selective elution of spectrin and Components 2.1, 2.2, 2.3, 4.1, 4.2, 5, and 6 representing 65% of the ghost protein has no effect on the uptake of D-glucose. All of the sugar transport proteins are associated with a membrane residue consisting of the proteins of Bands 3, 4.5, and 7, the periodic acid-Schiff-sensitive glycoproteins, and ghost phospholipids. Specific cross-linking of the proteins of Band 3 of ghosts by the catalyzed oxidation of intrinsic sulfhydryl groups with the o-phenanthroline-cupric ion complex inhibits D-glucose uptake and alters the relative electrophoretic mobility of Band 3 proteins in sodium dodecyl sulfate-polyacrylamide-agarose gels. This uptake activity and the relative mobility of Band 3 proteins are recovered upon reversal of the cross-linking reaction by reduction with 2-mercaptoethanol. These results and other observations indicate that the D-glucose transport protein is an intrinsic component of the hydrophobic structure of the erythrocyte membrane and may be associated with the proteins of Band 3 which are glycoproteins spanning the membrane bilayer. It is proposed that D-glucose transport occurs through a water-filled channel formed by specific subunit aggregates of the transport proteins in the erythrocyte membrane rather than by rotation of the protein within the plane of the membrane.     

Lateral mobility of a lipid analog in the membrane of irreversible sickle erythrocytes

The major feature of sickle cell anemia is the tendency of erythrocytes to sickle when exposed to decreased oxygen tension and to unsickle when reoxygenated. Irreversible sickle cells (ISCs) are sickle erythrocytes which retain bipolar elongated shapes despite reoxygenation. ISCs are believed to owe their biophysical abnormalities to acquired membrane alterations which decrease membrane deformability. While increased membrane surface viscosity has been measured in ISCs, the lateral dynamics of membrane lipids in these cells have not heretofore been examined. We have measured the lateral diffusion of the lipid analog 3,3'-dioctadecylindocyanine iodide (DiI) in the plasma membrane of intact normal erythrocytes, reversible sickle cells (RSCs), and irreversible sickle cells by fluorescence photobleaching recovery (FPR). The diffusion coefficients +/- standard errors of the mean of DiI in intact normal red blood cells (RBCs), RSCs, and ISCs at 37 degrees C are (8.06 +/- 0.29) X 10(-9) cm2 X s-1, (7.74 +/- 0.22) X 10(-9) cm2 X s-1, and (7.29 +/- 0.24) X 10(-9) cm2 X s-1, respectively. A similar decrease in the diffusion coefficient of DiI in the plasma membranes of the three cell types was observed at 4, 10, 17, 23, and 30 degrees C. ANOVA analysis of the changes in DiI diffusion showed significant differences between the RBC and ISC membranes at all temperatures examined. The characteristic breaks in Arrhenius plots of the diffusion coefficients for the RBCs, RSCs, and ISCs occurred at 20, 19, and 18.6 degrees C, respectively. Photobleaching recovery data were used to estimate (Boullier, J.A., Melnykovich, G. and Barisas, B.G. (1982) Biochim. Biophys. Acta 692, 278-286) the microviscosities of the plasma membranes of the three cell types at 25 degrees C. We find significant differences between our microviscosity values and those obtained in previous fluorescence depolarization studies. However, both methods indicate qualitatively similar differences in membrane microviscosity among the various cell types.     

Volume-dependent regulation of ion transport and membrane phosphorylation in human and rat erythrocytes

Summary Osmotic swelling of human and rat erythrocytes does not induce regulatory volume decrease. Regulatory volume increase was observed in shrunken erythrocytes of rats only. This reaction was blocked by the inhibitors of Na⁺/H⁺ exchange. Cytoplasmic acidification in erythrocytes of both species increases the amiloride-inhibited component of²²Na influx by five- to eight-fold. Both the osmotic and isosmotic shrinkage of rat erythrocytes results in the 10- to 30-fold increase of amiloride-inhibited²²Na influx and a two-fold increase of furosemide-inhibited⁸⁶Rb influx. We failed to indicate any significant changes of these ion transport systems in shrunken human erythrocytes. The shrinking of quin 2-loaded human and rat erythrocytes results in the two- to threefold increase of the rate of⁴⁵Ca influx, which is completely blocked by amiloride. The dependence of volume-induced²²Na influx in rat erythrocytes and⁴⁵Ca influx in human erythrocytes on amiloride concentration does not differ. The rate of⁴⁵Ca influx in resealed ghosts was reduced by one order of magnitude when intravesicular potassium and sodium were replaced by choline. It is assumed that the erythrocyte shrinkage increases the rate of a nonselective Ca _o ²⁺ (Na _i ⁺ , K _i ⁺ ) exchange. Erythrocyte shrinking does not induce significant phosphorylation of membrane protein but increases the³²P incorporation in diphosphoinositides. The effect of shrinkage on the³²P labeling of phosphoinositides is diminished after addition of amiloride. It is assumed that volume-induced phosphoinositide response plays an essential role in the mechanism of the activation of transmembrane ion movements.     

Irreversible inhibition of water transport in erythrocytes by fluoresceinmercuric acetate

Fluoresceinmercuric acetate (FMA) is approximately 5 times more potent than p-chloromercuribenzene sulfonate (PCMBS) in inhibiting water transport across human erythrocyte membranes. Half maximal inhibition occurred at approximately 60 m. While cysteine fully reversed the inhibition induced by p-chloromercuribenzene sulfonate it had no effect on the inhibition induced by fluoresceinmercuric acetate. A comparison of the structures of fluoresceinmercuric acetate and p-chloromercuribenzene sulfonate suggests that either there are two sulfhydryl groups in close proximity or the larger aromatic ring structure of fluoresceinmercuric acetate causes tighter binding to one sulfhydryl group at the active site.     

Urate transport in erythrocytes: possible role of a transport membrane]

Urate transport seems dependant of ATP. So, we studied urate behaviour in relation with the isolated membrane: we observed a linkage between urate and a membrane protein of which molecular weight was estimated to twenty thousand. The exact role of this protein remains to be clarify.