Cytoskeletal restraints of band 3 rotational mobility in human erythrocyte membranes

The interaction of band 3 with cytoskeletal proteins was investigated in erythrocyte membranes by measuring the rotational mobility of band 3 using the method of transient dichroism. It was found that selective proteolysis of ankyrin, a protein known to link band 3 to the spectrin-actin network, had no significant effect on band 3 rotation. Incubating ghosts to 70 degrees C, at which temperature ankyrin is expected to be denatured, also had no effect. It thus appears probable that linkage of band 3 to the cytoskeleton via ankyrin does not act as a restraint on band 3 rotational motion. It is suggested that this is a consequence of flexibility in the cytoskeletal structure. In further investigations of the effect of heat treatment, a large enhancement of band 3 rotational mobility was found to result from incubation of intact cells for 1 h at 50 degrees C. This effect was not observed if ghosts were subjected to the same treatment, nor did it occur if the incubation of cells was performed at 47 degrees C. These findings, in combination with previous studies of band 3 rotational mobility, indicate that the interactions which restrain band 3 are likely to be more complex than commonly envisaged.     

Enzymatic methylation of band 3 anion transporter in intact human erythrocytes

Band 3, the anion transport protein of erythrocyte membranes, is a major methyl-accepting substrate of the intracellular erythrocyte protein carboxyl methyltransferase (S-adenosyl-L-methionine: protein-D-aspartate O-methyltransferase; EC 2.1.1.77) [Freitag, C., & Clarke, S. (1981) J. Biol. Chem. 256, 6102-6108]. The localization of methylation sites in intact cells by analysis of proteolytic fragments indicated that sites were present in the cytoplasmic N-terminal domain as well as the membranous C-terminal portion of the polypeptide. The amino acid residues that serve as carboxyl methylation sites of the erythrocyte anion transporter were also investigated. 3H-Methylated band 3 was purified from intact erythrocytes incubated with L-[methyl-3H]methionine and from trypsinized and lysed erythrocytes incubated with S-adenosyl-L-[methyl-3H]methionine. After proteolytic digestion with carboxypeptidase Y, D-aspartic acid beta-[3H]methyl ester was isolated in low yields (9% and 1%, respectively) from each preparation. The bulk of the radioactivity was recovered as [3H]methanol, and the amino acid residue(s) originally associated with these methyl groups could not be determined. No L-aspartic acid beta-[3H]methyl ester or glutamyl gamma-[3H]methyl ester was detected. The formation of D-aspartic acid beta-[3H]methyl esters in this protein in intact cells resulted from protein carboxyl methyltransferase activity since it was inhibited by adenosine and homocysteine thiolactone, which increases the intracellular concentration of the potent product inhibitor S-adenosylhomocysteine, and cycloleucine, which prevents the formation of the substrate S-adenosyl-L-[methyl-3H]methionine.     

Loss of rotational mobility of band 3 proteins in human erythrocyte membranes induced by antibodies to glycophorin A.

The effect of antibodies to glycophorin A on the rotational diffusion of band 3 in human erythrocyte membranes was investigated by transient dichrosim. Three antibodies that recognize different epitopes on the exofacial domain of glycophorin A all strongly reduce the rotational mobility of band 3. The effect is at most only weakly dependent on the distance of the epitope from the membrane surface. The degree of immobilization obtained with two of the antibodies, BRIC14 and R18, is very similar to that produced by antibodies to band 3 itself. Similar results were obtained with membranes stripped of skeletal proteins. Fab fragments and an antibody to glycophorin C had no effect on band 3 rotational mobility. These results rule out a mechanism whereby band 3 rotational immobilization results from enhanced interactions with the membrane skeleton that are mediated by a conformational change in glycophorin A. Rather, they strongly indicate that the antibodies to glycophorin A cross-link existing band 3-glycophorin A complexes that have lifetimes that are long compared with the millisecond time scale of the transient dichroism measurements.     

Both ankyrin and band 4.1 are required to restrict the rotational mobility of band 3 in the human erythrocyte membrane.

A population of band 3 proteins in the human erythrocyte membrane is known to have restricted rotational mobility due to interaction with cytoskeletal proteins. We have further investigated the cause of this restriction by measuring the effects on band 3 rotational mobility of rebinding ankyrin and band 4.1 to ghosts stripped of these proteins as well as spectrin and actin. Rebinding either ankyrin or 4.1 alone has no detectable effect on band 3 mobility. Rebinding both these proteins together does, however, reimpose a restriction on band 3 rotation. The effect on band 3 rotational mobility of rebinding ankyrin and 4.1 are similar irrespective of whether or not band 4.2 is removed from the membrane. We suggest that ankyrin and 4.1 together promote the formation of slowly rotating clusters of band 3.     

Amino acid sequences around exofacial proteolytic cleavage sites of band 3 from bovine and porcine erythrocytes

• 1.1. Amino acid sequences of bovine and porcine band 3, an erythrocyte anion transporter, were determined.
• 2.2. The sequence of bovine band 3 was positioned to residues 519–599 (the numbering is based on human band 3), in which probably 6 residues were unidentified.
• 3.3. Binding site of DIDS (4,4'-diisothiocyanostilbene-2,2'-disulfonate), a potent anion transport inhibitor, was identified as Lys-539 in the bovine case.
• 4.4. A loop (residues 551–567), which provides exofacial proteolytic cleavage sites, contains only 53% homology between human and bovine, whereas the residues flanking it on either side are >84% homologous.
• 5.5. Furthermore, the loop of porcine band 3 was indicated to consist of a 6 or 7-residues short peptide as compared with those of other species.

     

The effect of lateral mobility on the binding and reaction rate at membrane sites

The rates of membrane processes like transport, hormone action and enzyme reaction depend on the prevailing temperature. Arrhenius plots of such rates show a break at the phase transition temperature. We have very little insight into the molecular mechanism of the effect of phase transition on the membrane phenomena. In general above this temperature there is an onset of two dimensional mobility of the surface sites. Here, we point out that the binding of ligands to these sites should then be described by an adsorption isotherm appropriate for mobile rather than fixed sites. This introduces an additional factor in the rate equation, which correlates well with the observed changes in the rates at membrane sites on gel to liquid crystalline transition.     

5-Doxylstearate-induced displacement of phencyclidine from its low-affinity binding sites on the nicotinic acetylcholine receptor.

Fatty acids as well as phencyclidine (PCP) inhibit the ion channel activity of the nicotinic acetylcholine receptor (AChR) by a noncompetitive mechanism. However, the exact localization of the fatty acid binding sites is unknown and, thus, the noncompetitive inhibitory mechanism for these endogenous modulators remains to be elucidated. In an attempt to determine the location of the fatty acid binding sites, we study the mutually exclusive action between 5-doxylstearate (5-SASL), a derivative of the endogenous noncompetitive antagonist (NCA) stearic acid, and other exogenous NCAs. For this purpose, both equilibrium and competitive binding assays using fluorescent and radiolabeled ligands were performed on desensitized AChRs. More specifically, we determined: (i) the effect of 5-SASL on the binding of the exogenous NCA [(3)H]PCP; (ii) the effect of 5-SASL on the binding of either quinacrine or ethidium, two fluorescent NCAs from exogenous origin; and (iii) the PCP-induced displacement of quinacrine and ethidium from their respective high-affinity binding sites. Our first target (i) is carried out by measuring the [(3)H]PCP binding in the absence or in the presence of increasing concentrations of 5-SASL. We found that 5-SASL displaces PCP from its low-affinity binding sites. The low-affinity PCP binding sites were pharmacologically characterized by an apparent dissociation constant (K(d)) of 6.1 +/- 5.0 microM and a stoichiometry of 3.7 +/- 1.5 sites per AChR. The fact that 5-SASL increased the apparent K(d) without changing the number of sites per AChR is indicative of a mutually exclusive action. From these results, an apparent inhibition constant (K(i)) of 75 +/- 31 microM for 5-SASL was calculated. In addition, 5-SASL affected neither the apparent K(d) (0.46 +/- 0.37 microM) nor the stoichiometry (1.07 +/- 0.57 sites per AChR) of the high-affinity PCP binding site. The second objective (ii) is achieved by titrating either quinacrine or ethidium into AChR native membranes in the absence or in the presence of increasing concentrations of 5-SASL. These experiments showed that 5-SASL efficiently increased the apparent K(d) of quinacrine without perturbing the interaction of ethidium with its high-affinity locus. Considering that (a) 5-SASL effectively quenched the AChR-bound quinacrine fluorescence (H. R. Arias, Biochim. Biophys. Acta 1347, 9-22, 1997) and (b) fluorescence-quenching is a short-range process, it is possible to suggest that 5-SASL displaces quinacrine from its high-affinity binding site by a steric mechanism. In this regard, a K(i) of 38 +/- 5 microM for 5-SASL was calculated. Concerning the last objective (iii), AChR-bound quinacrine or ethidium was back titrated with PCP. Two PCP K(i) values were obtained by fitting the displacement plots by nonlinear regression with two components. The lowest K(i) values obtained for either quinacrine (0.86 +/- 0.37 microM) or ethidium (0. 29 +/- 0.23 microM) displacement from their respective high-affinity binding sites coincide with the previously determined high-affinity [(3)H]PCP K(d). In addition, the highest K(i) values obtained for either NCA displacement are in the same concentration range as the observed low-affinity [(3)H]PCP K(d). Taking into account all experimental data, we reached the following conclusions: (i) fatty acid molecules, or at least 5-SASL, sterically interact with both the PCP low-affinity and the quinacrine high-affinity binding sites; (ii) the low-affinity PCP binding sites, as well as the high-affinity quinacrine locus, are located at the nonannular lipid domain of the AChR; and, finally, (iii) fatty acid molecules are not accessible to the lumen of the ion channel, indicating an allosteric mode of action for fatty acids to inhibit ion flux. Thus, the 5-SASL, the quinacrine high-affinity, and the PCP low-affinity binding sites are all located at overlapping nonannular loci on the muscle-type AChR.     

Adenosine kinase from human erythrocytes: kinetic studies and characterization of adenosine binding sites

The reaction catalyzed by adenosine kinase purified from human erythrocytes proceeds via a classical ordered sequential mechanism in which adenosine is the first substrate to bind to and AMP is the last product to dissociate from the enzyme. However, the interpretation of the steady-state kinetic data is complicated by the finding that while AMP acts as a classical product inhibitor at concentrations greater than 5 mM, at lower concentrations AMP can act as an apparent activator of the enzyme under certain conditions. This apparent activation by AMP is proposed to be due to AMP allowing the enzyme mechanism to proceed via an alternative reaction pathway that avoids substrate inhibition by adenosine. Quantitative studies of the protection of the enzyme afforded by adenosine against both spontaneous and 5,5'-dithiobis(2-nitrobenzoic acid)-mediated oxidation of thiol groups yielded "protection" constants (equivalent to enzyme-adenosine dissociation constant) of 12.8 microM and 12.6 microM, respectively, values that are more than an order of magnitude greater than the dissociation constant (Kia = 0.53 microM) for the "catalytic" enzyme-adenosine complex. These results suggest that adenosine kinase has at least two adenosine binding sites, one at the catalytic center and another quite distinct site at which binding of adenosine protects the reactive thiol group(s). This "protection" site appears to be separate from the nucleoside triphosphate binding site, and it also appears to be the site that is responsible for the substrate inhibition caused by adenosine.     

Oxidative stress and autologous immunoglobulin G binding to band 3 dimers in newborn erythrocytes

Since birth-induced oxidative stress (OS) results in the removal of erythrocytes from the blood stream, we studied the binding of autologous IgG to erythrocyte band 3 dimers (the 170-kDa band, which marks the erythrocytes for removal) in preterm and term newborns and in adults. The 170-kDa band was present in as much as 74% of preterm, in 21% of term newborns, and in 10% of adults. During erythrocyte ageing "in vitro" (0, 24, and 48 h aerobic incubation), the appearance of the band occurred much faster with erythrocytes from newborns (particularly preterm) than with those from adults. When the blots for the 170-kDa band were quantified by scanning densitometry, it was seen that the 0 time values were significantly higher in preterm compared to term and adult values. After aerobic incubation a progressive increase in the optical density was observed in each group and the densities were higher in preterm than in the other groups. The course of iron release during the various incubations was analogous to that of the 170-kDa band blots, and significant correlations were found at 0 and 48 h. Methemoglobin formation roughly paralleled iron release. Esterified F(2)-isoprostanes (markers of OS) and O(2)(-) production in the nonincubated (0 time) erythrocytes were much higher in newborn (preterm and term) than in adult erythrocytes. Plasma free F(2)-isoprostanes were significantly higher in preterms than in terms and in terms than in adults. Plasma non-protein-bound iron (NPBI) was higher in preterm than in term newborns and not detectable in adults. In conclusion dimers of band 3 with autologous IgG are found under conditions in which OS can be detected in erythrocytes or in plasma: namely in newborns or in aged erythrocytes.     

Cooperative action between band 3 and glycophorin A in human erythrocytes: immobilization of band 3 induced by antibodies to glycophorin A.

The ability of transmembrane receptor proteins to change their association with the cytoskeleton in response to ligand binding seems to be a key mechanism of signal transduction across membranes. To investigate the molecular features of this mechanism we have used the red cell membrane as a model system to study signal transduction through the integral protein, glycophorin A. In these studies the lateral mobility of integral proteins was measured in situ by fluorescence recovery after photobleaching, and membrane rigidity was characterized by micropipette aspiration technique. We found that binding either a monoclonal antibody or its monovalent Fab to the exoplasmic domain of glycophorin A in normal red cells immobilized the receptor and rigidified the membrane. Further, immobilization and rigidification did not occur when antibodies were bound to Miltenberger V cells containing a mutant form of glycophorin A lacking the cytoplasmic domain. These results imply that the site of the immobilization/rigidification lies within the membrane skeletal structure, not in exofacial receptor crosslinking, and requires the extended cytoplasmic domain of normal glycophorin A. In addition, we found that glycophorin A immobilization and membrane skeletal rigidification were accompanied by immobilization of band 3 receptors. This unexpected result indicates a cooperative coupling between liganded glycophorin A, band 3, and the membrane skeleton. We speculate that cooperation of this type may represent a general mechanism for cytoskeletal linkage and transformation initiated by receptors with short cytoplasmic sequences, such as integrins.     

Purification and properties of human erythrocyte band 4.2. Association with the cytoplasmic domain of band 3

We have purified the human erythrocyte membrane protein band 4.2 to greater than 85% homogeneity. The protein was extracted from spectrin-actin-depleted inside-out vesicles in a pH 11 medium and purified by gel filtration in the presence of 1 M KI. The purified protein was heterogeneous and had an average S20,w of 5.5 and an average Stokes radius of 82 A. By electron microscopy, the protein appeared heterogeneous in size and shape, having a diameter ranging from 80 to 150 A. The protein bound saturably to band 4.2-depleted red cell inside-out vesicles, and the binding exhibited a concave Scatchard plot. Binding was reduced greater than 90% by proteolytic digestion of membranes. Digestion studies suggested that there are two classes of binding sites for band 4.2 on the cytoplasmic aspect of red cell membranes, one of which is likely to be band 3. The purified 43-kDa cytoplasmic domain of band 3 competed for band 4.2 binding to red cell membranes and could completely abolish binding when added at a concentration of greater than 200 micrograms/ml. The purification of band 4.2 and the characterization of its association with red cell membranes should facilitate the discovery of the function of this major red cell membrane protein.     

Characterization of band 3-ankyrin-Protein 4.2 complex by biochemical and mass spectrometry approaches

The elastic property of red blood cell is supported by interaction between red cell membrane and the intricate cytoskeleton network underlying the membrane bilayer cytoplasmic face. One of the major scaffold protein linkers is band 3-ankyrin complex. Defects occurring in this complex have been found in many inherited diseases, causing red blood cell abnormalities. Here we combined the power of mass spectrometry with conventional biochemical purification methods in order to study the native interactions among band 3, ankyrin and Protein 4.2. This approach provided in vivo evidence for the association between band 3 and N-terminal ankyrin purified directly from the cell membrane. The C-terminal regions of ankyrin were not found to be a stable partner of the band 3 complex. Protein 4.2 was shown here to be an integral part of the complex. Its association to the band 3–ankyrin complex could withstand harsh purification conditions. Our findings lend additional support to the interaction between band 3 and ankyrin N-terminal domain previously shown by in vitro binding assays and provide evidence for a band 3 core complex comprising of band 3, ankyrin and Protein 4.2.     

Iron release, superoxide production and binding of autologous IgG to band 3 dimers in newborn and adult erythrocytes exposed to hypoxia and hypoxia-reoxygenation

Iron is released in a desferrioxamine (DFO)-chelatable form when erythrocytes are challenged by an oxidative stress. The release is increased when an accelerated removal of erythrocytes occurs such as in perinatal period, in which iron release is greater in hypoxic than in non-hypoxic newborns. This suggests that an hypoxic environment at birth promotes iron release. To test this possibility, iron release in a model of hypoxia, hypoxia-reoxygenation and normoxia was studied in newborn and adult erythrocytes. In newborn erythrocytes, hypoxia induced a much greater iron release compared to an equal period of normoxia. In adult erythrocytes, hypoxia also induced a greater iron release as compared to normoxia, but it was much lower than that seen with newborn erythrocytes. Methemoglobin (MetHb) formation roughly paralleled iron release. The phenylhydrazine-promoted superoxide anion (O(2)?(-)) production was greater with normoxic but lower with hypoxic erythrocytes from newborns as compared to that from adults. This discrepancy between iron release and O(2)?(-) production may be explained by the shift towards MetHb in hemoglobin autoxidation. Iron diffusion out of the erythrocytes was much higher with hypoxic erythrocytes from newborns as compared to that from adults. Also the binding of autologous IgG to band 3 dimers (AIgGB) is much greater with hypoxic erythrocytes from newborns as compared to that from adults, suggesting that the level of iron release is related to the extent of band 3 clustering and that hypoxia accelerates removal of erythrocytes from bloodstream in in vivo condition.     

Associations of human erythrocyte band 4.2. Binding to ankyrin and to the cytoplasmic domain of band 3

We have examined the associations of purified red cell band 4.2 with red cell membrane and membrane skeletal proteins using in vitro binding assays. Band 4.2 bound to the purified cytoplasmic domain of band 3 with a Kd between 2 and 8 X 10(-7) M. Binding was saturable and slow, requiring 2-4 h to reach equilibrium. This finding confirms previous work suggesting that the principal membrane-binding site for band 4.2 lies within the 43-kDa cytoplasmic domain of band 3 (Korsgren, C., and Cohen, C. M. (1986) J. Biol. Chem. 261, 5536-5543). Band 4.2 also bound to purified ankyrin in solution with a Kd between 1 and 3.5 X 10(-7) M. As with the cytoplasmic domain of band 3, binding was saturable and required 4-5 h to reach equilibrium. Reconstitution with ankyrin of inside-out vesicles stripped of all peripheral proteins had no effect upon band 4.2 binding to membranes; similarly, reconstitution with band 4.2 had no effect upon ankyrin binding. This shows that ankyrin and band 4.2 bind to distinct loci within the 43-kDa band 3 cytoplasmic domain. Coincubation of ankyrin and band 4.2 in solution partially blocked the binding of both proteins to the membrane. Similarly, coincubation of bands 4.1 and 4.2 in solution partially blocked binding of both to membranes. In all cases, the data suggest the possibility that domains on each of these proteins responsible for low affinity membrane binding are principally affected. The data also provide evidence for an association of band 4.2 with band 4.1. Our results show that band 4.2 can form multiple associations with red cell membrane proteins and may therefore play an as yet unrecognized structural role on the membrane.     

Analysis of the mobilities of band 3 populations associated with ankyrin protein and junctional complexes in intact murine erythrocytes

Current models of the erythrocyte membrane depict three populations of band 3: (i) a population tethered to spectrin via ankyrin, (ii) a fraction attached to the spectrin-actin junctional complex via adducin, and (iii) a freely diffusing population. Because many studies of band 3 diffusion also distinguish three populations of the polypeptide, it has been speculated that the three populations envisioned in membrane models correspond to the three fractions observed in diffusion analyses. To test this hypothesis, we characterized band 3 diffusion by single-particle tracking in wild-type and ankyrin- and adducin-deficient erythrocytes. We report that ～40% of total band 3 in wild-type murine erythrocytes is attached to ankyrin, whereas ～33% is immobilized by adducin, and ～27% is not attached to any cytoskeletal anchor. More detailed analyses reveal that mobilities of individual ankyrin- and adducin-tethered band 3 molecules are heterogeneous, varying by nearly 2 orders of magnitude and that there is considerable overlap in diffusion coefficients for adducin and ankyrin-tethered populations. Taken together, the data suggest that although the ankyrin- and adducin-immobilized band 3 can be monitored separately, significant heterogeneity still exists within each population, suggesting that structural and compositional properties likely vary considerably within each band 3 complex.     

Solubilization and characterization of the beta-adrenergic receptor binding sites of frog erythrocytes.

Specific beta-adrenergic receptors present in membrane preparations of frog erythrocytes were identified by binding of (-)-[3H]dihydroalprenolol, a potent competitive beta-adrenergic antagonist. The (-)-[3H]dihydroalprenolol binding sites could be solubilized by treatment of a purified erythrocyte membrane fraction with the plant glycoside digitonin but not by treatment with a wide variety of other detergents. The binding sites appeared to be soluble by several independent experimental criteria including (a) failure to sediment of 105,000 X g for 2 hours; (b) passage through 0.22-mu Millipore filters; (c) chromatography on Sepharose 6B gels; and (d) electron microscopy. The soluble receptor sites retained all of the essential characteristics of the membrane-bound sites, namely rapid and reversible binding of beta-adrenergic agonists and antagonists; strict stereospecificity toward both beta-adrenergic agonists and antagonists; appropriate structure-activity relationships; saturability of the sites at low concentrations of ligand; no affinity for alpha-adrenergic drugs, nonphysiologically active catechol compounds, and catecholamine metabolites. Based on gel chromatography in the presence of detergent, the molecular weight of the soluble receptor is estimated to be no greater than 130,000 to 150,000. Equilibrium binding studies indicated a KD for the soluble receptor of 2 nM. Hill coefficients (nH) of 0.77 and curved Scatchard plots suggested the presence of negatively cooperative interactions among the solubilized receptors in agreement with previous findings with the membrane-bound sites. Kinetic studies indicated an association rate constant K1 = 3.8 X 10(6) M-1 min-1 and a reverse rate constant k2 = 2.3 X 10(-3) min-1 at 4 degrees. The kinetically derived KD (k2/k1) of 0.6 nM is in reasonable agreement with that determined by equilibrium studies. The soluble receptors were labile at temperature greater than 4 degrees but could be stabilized with high concentrations of EDTA. Guanidine hydrochloride and urea produced concentration-dependent losses of binding activity which were partially reversible upon dialysis. Trypsin and phospholipase A both degraded the soluble receptors but a variety of other proteases and phospholipases as well as DNase and RNase were without effect. Experiments with group-specific reagents indicated that free lysine, tryptophan, serine, and sulfhydryl groups may be important for receptor binding. These studies suggest that the receptor is probably a protein which requires lipids for functional integrity. Data obtained with the solubilized binding sites are consistent with the contention that these sites represent the physiologically relevant beta-adrenergic receptors which have been extracted from the membranes with full retention of their properties.     

The involvement of microfilaments and microtubules in the lateral mobility of lectin binding sites of normal and brachypod mouse limb mesenchyme

It has been demonstrated that differences exist in the lateral mobility of Con A- and WGA-binding sites in the membranes of normal and brachypod mouse limb mesenchymal cells (Hewitt et al., 1978). The work presented here investigates the involvement of microtubules and microfilaments as mediators of binding site mobility in this system. Treatment of cells with colchicine suggests that microtubules are not involved in the mobility of either type of lectin-binding site. Disruption of microfilaments with cytochalasin B prevents the redistribution of Con A-binding sites but not those of WGA. the results were found to be the same for both genotypes. This suggests that the differences which have been found between genotypes are related to some mechanism of restraining the lateral mobility of lectin binding sites other than by attachment to microtubules and microfilaments.     

Organic phosphate binding to hemoglobin in intact human erythrocytes determined by 31P nuclear magnetic resonance spectroscopy.

Phosphorus nuclear magnetic resonance (31P NMR) spectroscopy was used to estimate the percent of 2,3-diphosphoglycerate and ATP bound to hemoglobin in intact human erythrocytes at 37 degrees C. Binding was assessed by comparing the chemical shifts (delta) of 2,3-diphosphoglycerate and of ATP observed in intact cells with the delta values of these organic phosphates determined in model solutions closely simulating intracellular conditions, in which percent binding was directly evaluated by membrane ultrafiltration. The results showed that the percent of bound 2,3-diphosphoglycerate in intact cells varied with pH, the state of oxygenation, and 2,3-diphosphoglycerate concentration. The values ranged from 33% in cells incubated with glucose in air at an intracellular pH of 7.2 to 100% in cells incubated with inosine in N2 at a pH of 6.75. At the same 2,3-diphosphoglycerate concentration, a greater percentage of the compound appeared to be bound in erythrocytes than in the closely simulated model system. ATP was not significantly bound to hemoglobin under any condition examined, but appeared to be strongly complexed to Mg2+ inside the erythrocyte. The binding percentages for both 2,3-diphosphoglycerate and ATP in intact cells estimated by 31P NMR spectroscopy were lower than those calculated by others from individual association constants determined for the binding of different ligands to hemoglobin.     

Involvement of carboxyl groups in chloride transport and reversible DIDS binding to band 3 protein in human erythrocytes

Noncovalent DIDS binding to Band 3 (AE1) protein in human erythrocyte membranes, modified by non-penetrating, water soluble 1-ethyl-3-(4-azonia-4,4-dimethylpentyl)-carbodiimide iodide (EAC), was studied at 0°C in the presence of 165 mM KCl. Under experimental conditions applied up to (48 ± 5) % of irreversible chloride self-exchange inhibition was observed. The apparent dissociation constant, KD, for “DIDS-Band 3” complex, determined from the chloride transport experiments, was (34 ± 3) nM and (80 ± 12) nM for control and EAC-treated resealed ghosts, respectively. The inhibition constant, Ki, for DIDS was (35 ± 6) nM and (60 ± 8) nM in control and EAC-treated ghosts, respectively. The reduced affinity for DIDS reversible binding was not a result of negative cooperativity of DIDS binding sites of Band 3 oligomer since Hill’s coefficients were indistinguishable from 1 (within the limit error) both for control and EAC-treated ghosts. By using tritium-labeled DIDS, 4,4’-diisothiocyanato-2,2’-stilbenedisulfonate ([³H]DIDS), the association rate constant, k₊₁ (M⁻¹s⁻¹), was measured. The mean values of (4.3 ± 0.7) × 10⁵ M⁻¹s⁻¹ for control and (2.7 ± 0.7) × 10⁵ M⁻¹s⁻¹ for EAC-treated ghosts were obtained. The mean values for K_D, evaluated from [³H]DIDS binding measurements, were (37 ± 9) nM and (90 ± 21) nM for control and EAC-modified ghosts, respectively. The results demonstrate that EAC modification of AE1 reduces about 2-fold the affinity of AE1 for DIDS. It is suggested that half of the subunits are modified near the transport site by EAC.