Evidence that inhibitors of anion exchange induce a transmembrane conformational change in band 3

The transport inhibitor, eosin 5-maleimide, reacts specifically at an external site on the membrane-bound domain of the anion exchange protein, Band 3, in the human erythrocyte membrane. The fluorescence of eosin-labeled resealed ghosts or intact cells was found to be resistant to quenching by CsCl, whereas the fluorescence of labeled inside-out vesicles was quenched by about 27% at saturating CsCl concentrations. Since both Cs+ and eosin maleimide were found to be impermeable to the red cell membrane and the vesicles were sealed, these results indicate that after binding of the eosin maleimide at the external transport site of Band 3, the inhibitor becomes exposed to ions on the cytoplasmic surface. The lifetime of the bound eosin maleimide was determined to be 3 ns both in the absence and presence of CsCl, suggesting that quenching is by a static rather than a dynamic (collisional) mechanism. Intrinsic tryptophan fluorescence of erythrocyte membranes was also investigated using anion transport inhibitors which do not appreciably absorb light at 335 nm. Eosin maleimide caused a 25% quenching and 4,4'-dibenzamidodihydrostilbene-2,2'-disulfonate) caused a 7% quenching of tryptophan fluorescence. Covalent labeling of red cells by either eosin maleimide or BIDS (4-benzamido-4'-isothiocyanostilbene-2,2'-disulfonate) caused an increase in the susceptibility of membrane tryptophan fluorescence to quenching by CsCl. The quenching constant was similar to that for the quenching of eosin fluorescence and was unperturbed by the presence of 0.5 M KCl. Neither NaCl nor Na citrate produced a large change in the relative magnitude of the tryptophan emission. The tryptophan residues that can be quenched by CsCl appear to be different from those quenched by eosin or BIDS and are possibly located on the cytoplasmic domain of Band 3. The results suggest that a conformational change in the Band 3 protein accompanies the binding of certain anion transport inhibitors to the external transport site of Band 3 and that the inhibitors become exposed on the cytoplasmic side of the red cell membrane.     

Further Studies on Zn2+-Mediated Domain–Domain Communication in Human Erythrocyte Band 3

Human erythrocyte band 3 is purified and reconstituted into vesicles, forming right-side-out proteoliposomes. Zn²⁺entrapped inside the proteoliposomes inhibits the anion transport activity of band 3, and removal of the cytoplasmic domain of band 3 is able to diminish Zn²⁺ inhibition. Thus, the inhibition of activity of band 3 results from the Zn²⁺ induced conformational change of the cytoplasmic domain, which in turn is transmitted to the membrane domain. The results of intrinsic fluorescence and its quenching by HB and the ³⁵Cl NMR study indicate that the cytoplasmic domain is essential for the conformational change induced by Zn²⁺.SH-blocking reagents, CH₃I and GSSG, are used to modify the cytoplasmic domain, where they specifically bind to Cys201 and Cys317. It is observed that the Zn²⁺ induced inhibition of anion transport activity is blocked. This demonstrates that Cys201 and Cys317 are required in Zn²⁺-mediated domain–domain communication.     

硒对红细胞膜抗氧化作用的探讨

本文以红细胞膜在体外与超氧阴离子自由基(由邻苯三酚自氧化产生)反应所致氧化损伤作为实验模型,研究了Na₂SeO₃,NaHSeO₃,Na₂SeO₄和SeO₂等硒化合物对红细胞膜的作用。结果表明,Na₂SeO₃有抗氧化作用。表现为膜蛋白交联作用显著减小,脂质过氧化物(膜荧光物质)含量下降。本文还就硒抗氧化作用的机理作了讨论。     

Ganglioside GM3 modulates conformation of reconstituted ca2+-ATPase

Using steady-state fluorescence and nanosecond time-resolved fluorescence techniques, the ca²⁺ ATPase conformational changes induced by ganglioside GM3 were studied with different quenchers. The results showed that GM3 could significantly increase the lifetime of intrinsic fluorescence of Ca²⁺-ATPase reconstituted into proteoliposomes, and could also weaken the intrinsic fluorescence quenching by KI or hypocrellin B, HB. Furthermore, by using quenching kinetic analysis of the time-resolved fluorescence, in the presence of GM3, the quenching constant (K_3V) and quenching efficiency were significantly lowered. The obtained results suggest that the oligosaccharide chain and the ceramide moieties of the GM3 molecule could interact with its counterparts of the ca²⁺-ATPase respectively, thus change the conformation of the hydrophobic domain of the enzyme, making the tryptophan residues in different regions shift towards the hydrophilic-hydrophobic interface, and hence shorten the distance between the hydrophilic and the hydrophobic domains, making the enzyme with a more compact form exhibit higher enzyme activity.     

Study on the interaction of chromate with bovine serum albumin by spectroscopic method

The interaction between two chromates [sodium chromate (Na₂CrO₄) and potassium chromate K₂CrO₄)] and bovine serum albumin (BSA) in physiological buffer (pH 7.4) was investigated by the fluorescence quenching technique. The results of fluorescence titration revealed that two chromates could strongly quench the intrinsic fluorescence of BSA through a static quenching procedure. The apparent binding constants K and number of binding sites n of chromate with BSA were obtained by the fluorescence quenching method. The thermodynamic parameters enthalpy change (ΔH), entropy change (ΔS) were negative, indicating that the interaction of two chromates with BSA was driven mainly by van der Waals forces and hydrogen bonds. The process of binding was a spontaneous process in which Gibbs free energy change was negative. The distance r between donor (BSA) and acceptor (chromate) was calculated based on Forster’s non-radiative energy transfer theory. The results of UV–Vis absorption, synchronous fluorescence, three-dimensional fluorescence and circular dichroism (CD) spectra showed that two chromates induced conformational changes of BSA.     

Ganglioside GM3 modulates conformation of reconstituted ca2+-ATPase

Using steady-state fluorescence and nanosecond time-resolved fluorescence techniques, the ca²⁺ ATPase conformational changes induced by ganglioside GM3 were studied with different quenchers. The results showed that GM3 could significantly increase the lifetime of intrinsic fluorescence of Ca²⁺-ATPase reconstituted into proteoliposomes, and could also weaken the intrinsic fluorescence quenching by KI or hypocrellin B, HB. Furthermore, by using quenching kinetic analysis of the time-resolved fluorescence, in the presence of GM3, the quenching constant (K_3V) and quenching efficiency were significantly lowered. The obtained results suggest that the oligosaccharide chain and the ceramide moieties of the GM3 molecule could interact with its counterparts of the ca²⁺-ATPase respectively, thus change the conformation of the hydrophobic domain of the enzyme, making the tryptophan residues in different regions shift towards the hydrophilic-hydrophobic interface, and hence shorten the distance between the hydrophilic and the hydrophobic domains, making the enzyme with a more compact form exhibit higher enzyme activity. Project supported by the State Key Laboratory of Biomacromolecules.     

Selenium inhibition of avian fatty acid synthetase complex

Injection of 0.48 or 0.72 mg of selenium/100 g body weight (as Na₂SeO₃) into 3-week-old chicks depressed hepatic activity of fatty acid synthetase compared with saline-injected controls. In in vitro experiments with fatty acid synthetase purified to homogeneity, Na₂SeO₃ was a competitive inhibitor (K_i = ca. 70 μM). Dithiothreitol (DTT) at low concentrations increased the inhibition of the enzyme by Na₂SeO₃. At higher DTT concentrations the potentiating effect of DTT on selenium inhibition of the enzyme disappeared. At still higher DTT concentrations, selenium inhibition of fatty acid synthetase was partically relieved. If DTT and Na₂SeO₃ (2 : 1 molar ratio, respectively) in inhibitory concentrations, were reacted together prior to addition to enzyme and substrate, no inhibition was observed. Potentiation of selenium inhibition of fatty acid synthetase was observed with 2-mercaptoethanol but not with ascorbate. Several organic seleno-compounds were not inhibitory. The data suggest that selenium inhibits fatty acid synthetase by reversible bonding to the sulfhydryl (SH) groups (possibly at the active sites for acetyl-CoA and/or malonyl-CoA binding) of the enzyme. Selenotrisulfide formation involving selenium and the SH groups from the enzyme and thiol compounds is advanced as a possible explanation for the interaction among Se, DTT and enzyme observed in these experiments.     

The effect of selenium on the function of the anion transporter (Band 3) of erythrocyte membranes.

The transport activity of Band 3 of spectrin-stripped inside-out erythrocyte membrane vesicles (IOVs) or resealed ghosts was enhanced in the presence of trace amounts of Na2SeO3 (0.2-0.5 p.p.m.); however, at higher concentrations of Na2SeO3 (> 4.0 p.p.m.), an inverse result was obtained. Reassociation of spectrin with IOVs has no effect either on the transport activity of Band 3 or on the enhancement of its activity by Na2SeO3. Sulfhydryl reagents (p-chloromercuribenzoic acid and N-ethylmaleimide) could also inhibit Band 3 activity and eliminate the selenium effect. It is suggested that SH groups are involved in anion transport of Band 3 and that the selenium effect is based on the interaction of SH groups of Band 3 with Na2SeO3.     

Cytotoxicity of sodium selenite in HaCaT cells induces cell death and alters the mRNA expression of PUMA,ATR, and mTOR genes

BackgroundBy identifying the molecular mechanisms underlying sodium selenite (Na₂SeO₃) cytotoxicity during exposure in non-tumor cells (HaCaT cells), we will improve the current understanding of its antiproliferative effects and modulation of gene expression in the main pathways related to the cell cycle, cell death, oxidative stress, and DNA damage and repair.MethodsNon-tumor HaCaT cells were treated with Na₂SeO₃ to induce cytotoxicity, and the effects were investigated using an MTT assay (cell viability), real-time cell analysis (profiling the cell index), flow cytometry (membrane integrity, cell cycle disruption, and apoptosis), a comet assay (genotoxicity, i.e., DNA damage), and RT-qPCR (mRNA expression of genes).ResultsTreatment with Na₂SeO₃ was cytotoxic at 10 μM, producing morphological changes in cells (cytoplasmic granulations); however, it did not have a genotoxic effect. Na₂SeO₃ induced cell membrane damage, cell death, and cell cycle arrest in HaCaT cells. It also altered the mRNA expression levels of PUMA, ATR, and mTOR genes. However, it had no effect on the mRNA expression of caspases or PARP1, BIRC5, BECN1, and c-MYC genes, suggesting that Na₂SeO₃ causes PUMA-dependent apoptosis in HaCaT cells. The mRNA expression of specific genes related to oxidative stress, DNA damage and repair, and cell cycle control were unchanged by Na₂SeO₃.ConclusionsWe demonstrated the cytotoxic effect of Na₂SeO₃ in HaCaT cells by analyzing mRNA expression patterns, changes in cell morphology, and proliferation kinetics.     

Association of hemoglobin chains with the cell membrane as a cause of red cell distortion in thalassemia

Hemoglobin chains were separated and their interaction with membrane ghosts was studied using their ability to quench the fluorescence intensity of a membrane embedded probe. It was observed that alpha chains bind faster and with higher affinity to the membrane sites than do beta chains. The fast reversible interaction of both chains with the membrane was followed by a time-dependent partial loss of reversibility. Band 3 cytoplasmic fragments (B3F) were isolated and their reaction with separated Hb chains was studied using fluorescence quenching techniques as well. The data demonstrate that the relative affinity of the chains for B3F and loss of reversibility of the reaction followed patterns similar to the corresponding interaction of the chains with whole membranes. Band 3 cytoplasmic poles are therefore suggested as the high-affinity sites on the membrane for hemoglobin chains. When globin was reacted with B3F, it was observed that this protein binds strongly to the same membrane sites, but practically irreversibly. Exchange of the HbA content of normal cells by separated alpha or beta chains resulted in membrane distortions in both cases, but alpha chains caused greater morphological changes than did beta chains. The results of this study may provide one explanation for the differences in the thalassemia syndromes when excess of either alpha or beta chains is involved.     

Analysis of the oligomeric state of Band 3, the anion transport protein of the human erythrocyte membrane, by size exclusion high performance liquid chromatography. Oligomeric stability and origin of heterogeneity

The oligomeric state of human Band 3 (Mr = 95,000), the erythrocyte membrane anion exchanger, was examined by size exclusion high performance liquid chromatography in solutions containing the nonionic detergent C12E8 (octaethylene glycol n-dodecyl monoether). Band 3 was heterogeneous with respect to oligomeric composition, the predominant (70%) species being a dimer that bound 0.57 mg of C12E8/mg of protein (Stokes radius = 78 A, s20,w = 6.9 S). Variable amounts of larger oligomers were also present; however, no evidence for equilibration between oligomeric species was observed in detergent solution. Analytical and large zone size exclusion chromatography showed that Band 3 could not be dissociated to monomers, other than by protein denaturation. The membrane domain of Band 3 (Mr = 52,000) was also dimeric, but without evidence for higher oligomeric forms, which implies that the interactions responsible for higher associations involve the cytoplasmic domain. Prelabeling of Band 3 with the anion exchange inhibitor 4,4'-diisothiocyanostilbene-2,2'-disulfonate had no effect upon the oligomeric state of either intact Band 3 or its 52-kDa membrane domain. Band 3 oligomeric state could be reversibly changed in the membrane by altering the pH of the solution. The fraction of Band 3 not associated with the cytoskeleton was almost entirely dimeric. Band 3 purified from erythrocytes separated by density gradient centrifugation revealed that older red cells contained a larger proportion of higher oligomers than did younger cells. We conclude that Band 3, in the membrane and in C12E8 solution, exists as a mixture of dimers and larger oligomers. The higher oligomers interact with the cytoskeleton, increase in amount with cell age, and are held together by interactions of the cytoplasmic domain.     

Characterization of the reversible conformational equilibrium of the cytoplasmic domain of erythrocyte membrane band 3

The cytoplasmic domain of the erythrocyte membrane protein, band 3, contains binding sites for hemoglobin, several glycolytic enzymes, and ankyrin, the linkage to the cytoskeleton. In an earlier study, we found evidence which suggested that band 3 might undergo a native conformational change. We demonstrate here that the cytoplasmic domain of band 3 does exist in a reversible, pH-dependent conformational equilibrium among 3 native states. At physiological salt concentrations this equilibrium is characterized by apparent pKa values of 7.2 and 9.2; however, these apparent pKa values change if the domain's sulfhydryl groups are modified. A major component of the structural change appears to involve the pivoting of two subdomains of the cytoplasmic domain at a central hinge, as evidenced by both hydrodynamic and fluorescence energy transfer measurements. The probable site of this hinge is between residues 176 and 191, a region highly accessible to proteases and also rich in proline. These structural rearrangements also apparently extend to the cluster of tryptophan residues near the N terminus, since the domain's intrinsic fluorescence more than doubles between pH 6.5 and 9.5. No measurable change in band 3 secondary or quaternary structure could be detected during the conformational transitions. A structural model of the cytoplasmic domain of band 3 is presented to show the possible spatial relationships between the regions of conformational change and the sites of peripheral protein binding.     

Quenching of intrinsic tryptophan fluorescence in membranes of rat pituitary cells

The GH₄C₁ strain of hormone-producing rat pituitary cells has specific receptors for the tripeptide thyrotropin-releasing hormone (TRH). Membranes prepared from GH₄C₁ cells show intrinsic tryptophan fluorescence which was quenched by low concentrations (10–100 nM) of TRH and N^τ-methyl TRH but not by biologically inactive analogs of TRH. Membranes from GH₄C₁ cells were subjected to thermal denaturation. A conformational transition was noted above 40°C and an irreversible denaturation was observed at 52°C. TRH-induced quenching of intrinsic fluorescence was lost completely in membranes previously incubated for 10 min at 30°C while loss of [³H]-TRH binding was only about 20% at this temperature. Collisional quenching by iodide revealed that about 38% of the tryptophanyl residues in GH₄C₁ membranes were exposed to solvent. Quenching by TRH occurred with a shift in wavelength maximum from 336 to 342 nm suggesting that few of the tryptophanyl residues quenched by the tripeptide are totally exposed. Membranes prepared from cells preincubated with 20 nM TRH for 48 h, in which TRH receptors were decreased to 30% of control values, showed no quenching of tryptophan fluorescence in response to freshly added TRH. We conclude that the TRH-receptor interaction in GH₄C₁ cells is associated with a change in membrane conformation that can be measured by differential spectrofluorometry of intrinsic tryptophan fluorescence.     

Quenching of the fluorescence of proteins by silver nitrate

The mechanisms by which Ag⁺ may quench protein tryptophanyl fluorescence have been studied. A 1:1 Ag⁺-tryptophan complex was detected spectrophotometrically and shown to have a k_a = 6.5 × 10³ M^?1. The complex was nonfluorescent. Ag⁺ and NO₃^? each caused collisional quenching which proceeded at nearly diffusion-controlled rates in a series of indole-containing compounds. Analysis of the rates by means of Stern-Volmer plots and lifetime measurements showed also that charge and the presence of salt influence the quenching rate constants.The fluorescence of nonsulfhydryl proteins was quenched by AgNO₃ only in concentrations needed for Stern-Volmer quenching of simple indole model compounds. However, the plots for protein quenching were generally nonlinear, a reflection of the heterogeneity of tryptophanyl residues. AgNO₃ quenching increased the polarization of protein fluorescence and decreased the lifetime. Rotational relaxation times were determined from Perrin plots of reciprocal polarization vs fluorescence intensity in the presence of various amounts of AgNO₃.The fluorescence of the sulfhydryl proteins ovalbumin, yeast, and equine liver alcohol dehydrogenases was strongly quenched by AgNO₃ in parallel with the formation of Ag⁺-mercaptide bonds. The quenching of fluorescence of sulfhydryl proteins was exhibited even in 8 m urea, thus ruling out conformational change as a major basis for the quenching. It was found that Ag⁺ mercaptide bond formation was accompanied by development of an ultraviolet absorption band. The reaction of Ag⁺ with cysteine, for example, could be followed spectrophotometrically. The uv absorption of different silver mercaptides varied with the compound and pH.Since the uv absorption of Ag⁺-mercaptides extended up to 340 nm, and was also found in Ag⁺-treated sulfhydryl proteins, energy transfer from excited tryptophans seemed a reasonable basis for the observed fluorescence quenching. This possibility was confirmed by calculation of Förster critical transfer distances for a variety of donor-acceptor (Ag⁺-mercaptide) pairs.The lifetime of sulfhydryl protein fluorescence was decreased by AgNO₃, but the emission spectrum was relatively little affected, in contrast to previously reported quenching by Hg²⁺. Additional mechanisms of fluorescence alteration by Ag⁺ in proteins (e.g., “heavy atom” effect, conformational changes, enhancement of sulfhydryl quenching) are also considered.The spectral effects of Ag⁺ interaction with proteins have the following practical applications:determination of —SH groups; probe of accessibility of binding sites and tryptophan-sulfhydryl distances; determination of rotational relaxation times by Perrin plots of reciprocal polarization vs lifetime; kinetic studies of Ag⁺ interaction with proteins.     

Influence of gemfibrozil on sulfate transport in human erythrocytes during the oxygenation-deoxygenation cycle

The effects of gemfibrozil (GFZ), an antihyperlipidemic agent, on the anionic transport of the human red blood cells (RBC) during the oxygenation-deoxygenation cycle were examined. Gemfibrozil clearly plays a role in the modulation of the anionic flux in erythrocytes; in fact it causes a strong increment of anions transport when the RBCs are in the high-oxygenation state (HOS). Such an effect is remarkably reduced in the low-oxygenation state (LOS). With the aim of identifying the dynamics of fibrate action, this effect has been investigated also in human ghost and chicken erythrocytes. These latter, in fact, are known to possess a B3 (anion transporter or Band 3) modified at the cytoplasmic domain (cdb3) which plays a significant role in the metabolic modulation of red blood cells. The results were analyzed taking into account the well-known interactions between fibrates and both conformational states of hemoglobin i.e. the T state (deoxy-conformation) and the R state (oxy-conformation). The effect of gemfibrozil on anionic influx appears to be due to a wide interaction involving a "multimeric" Hb-GFZ-cdb3 macromolecular complex.     

H2O2-Induced Oxidative Stress Affects SO4= Transport in Human Erythrocytes

The aim of the present investigation was to verify the effect of H₂O₂-induced oxidative stress on SO₄⁼ uptake through Band 3 protein, responsible for Cl^-/HCO₃^- as well as for cell membrane deformability, due to its cross link with cytoskeletal proteins. The role of cytoplasmic proteins binding to Band 3 protein has been also considered by assaying H₂O₂ effects on hemoglobin-free resealed ghosts of erythrocytes. Oxidative conditions were induced by 30 min exposure of human erythrocytes to different H₂O₂ concentrations (10 to 300 μM), with or without GSH (glutathione, 2 mM) or curcumin (10 μM), compounds with proved antioxidant properties. Since SO₄⁼ influx through Band 3 protein is slower and better controllable than Cl^- or HCO₃^- exchange, the rate constant for SO₄⁼ uptake was measured to prove anion transport efficiency, while MDA (malondialdehyde) levels and –SH groups were estimated to quantify the effect of oxidative stress. H₂O₂ induced a significant decrease in rate constant for SO₄⁼ uptake at both 100 and 300 μM H₂O₂. This reduction, observed in erythrocytes but not in resealed ghosts and associated to increase in neither MDA levels nor in –SH groups, was impaired by both curcumin and GSH, whereas only curcumin effectively restored H₂O₂-induced changes in erythrocytes shape. Our results show that: i) 30 min exposure to 300 μM H₂O₂ reduced SO₄⁼ uptake in human erythrocytes; ii) oxidative damage was revealed by the reduction in rate constant for SO₄⁼ uptake, but not by MDA or –SH groups levels; iii) the damage was produced via cytoplasmic components which cross link with Band 3 protein; iv) the natural antioxidant curcumin may be useful in protecting erythrocytes from oxidative injury; v) SO₄⁼ uptake through Band 3 protein may be reasonably suggested as a tool to monitor erythrocytes function under oxidative conditions possibly deriving from alcohol consumption, use of drugs, radiographic contrast media administration, hyperglicemia or neurodegenerative diseases.     

Unique gating properties of C. elegans ClC anion channel splice variants are determined by altered CBS domain conformation and the R-helix linker

All eukaryotic and some prokaryotic ClC anion transport proteins have extensive cytoplasmic C-termini containing two cystathionine-β-synthase (CBS) domains. CBS domain secondary structure is highly conserved and consists of two a-helices and three b-strands arranged as b1-a1-b2-b3-a2. ClC CBS domain mutations cause muscle and bone disease and alter ClC gating. However, the precise functional roles of CBS domains and the structural bases by which they regulate ClC function are poorly understood. CLH-3a and CLH-3b are C. elegans ClC anion channel splice variants with strikingly different biophysical properties. Splice variation occurs at cytoplasmic N- and C-termini and includes several amino acids that form a2 of the second CBS domain (CBS2). We demonstrate that interchanging a2 between CLH-3a and CLH-3b interchanges their gating properties. The "R-helix" of ClC proteins forms part of the ion conducting pore and selectivity filter and is connected to the cytoplasmic C-terminus via a short stretch of cytoplasmic amino acids termed the "R-helix linker". C-terminus conformation changes could cause R-helix structural rearrangements via this linker. X-ray structures of three ClC protein cytoplasmic C-termini suggest that a2 of CBS2 and the R-helix linker could be closely apposed and may therefore interact. We found that mutating apposing amino acids in a2 and the R-helix linker of CLH-3b was sufficient to give rise to CLH-3a-like gating. We postulate that the R-helix linker interacts with CBS2 a2, and that this putative interaction provides a pathway by which cytoplasmic C-terminus conformational changes induce conformational changes in membrane domains that in turn modulate ClC function.     

Binding of vanadate to human erythrocyte ghosts and subsequent events

Spectroscopic techniques were used to investigate the interaction between vanadate and human erythrocyte ghosts. Direct evidence from ⁵¹V nuclear magnetic resonance (NMR) studies suggested that the monomeric and polymeric vanadate species may bind to the anion binding sites of band 3 protein of the erythrocyte membrane. The results of ⁵¹V NMR studies and the quenching effect of vanadate on the intrinsic fluorescence of the membrane proteins indicated that in the low concentration range of vanadate (<0.6 mm), monomeric vanadate binds mostly to the anion sites of band 3 protein with the dissociation constant close to 0.23 mm. The experiments of sulfhydryl content titration by the method of Ellman and residue sulfhydryl-labeled fluorescence spectroscopies clearly displayed that vanadate reacts directly with sulfhydryl groups. The appearance of the anisotropic election spin resonance (ESR) signal of vanadyl suggests that a small (c. 3%) amount of vanadate was reduced by sulfhydryl groups of membrane proteins. The fluidity and order of intact ghost membrane were reduced by the reaction with vanadate, as shown by the ESR studies employing the protein- and lipid-specific spin labels. It was concluded that although vanadates mainly bind to band 3 protein, a minor part of vanadate may oxidize the residue sulfhydryl groups of membrane proteins, and thus decrease the fluidity of erythrocyte membrane.     

Na/H Antiport in Isolated Tonoplast Vesicles from Storage Tissue of Beta vulgaris

The pH-dependent fluorescence quenching of acridine orange was used to study the Na⁺- and K⁺-dependent H⁺ fluxes in tonoplast vesicles isolated from storage tissue of red beet and sugar beet (Beta vulgaris L.). The Na⁺-dependent H⁺ flux across the tonoplast membrane could be resolved into two components: (a) a membrane potential-mediated flux through conductive pathways; and (b) an electroneutral flux which showed Michaelis-Menten kinetics relationship to Na⁺ concentration and was competitively inhibited by amiloride (K_i = 0.1 millimolar). The potential-dependent component of H⁺ flux showed an approximately linear dependence on Na⁺ concentration. In contrast, the K⁺-dependent H⁺ flux apparently consisted of a single component which showed an approximately linear dependence on K⁺ concentration, and was insensitive to amiloride. Based on the Na⁺- and K⁺-dependent H⁺ fluxes, the passive permeability of the vesicle preparation to Na⁺ was about half of that to K⁺.

The apparent K_m for Na⁺ of the electroneutral Na⁺/H⁺ exchange varied by more than 3-fold (7.5-26.5 millimolar) when the internal and external pH values were changed in parallel. The results suggest a simple kinetic model for the operation of the Na⁺/H⁺ antiport which can account for the estimated in vivo accumulation ratio for Na⁺ into the vacuole.