Regulation of Na+-H+ exchange by transmethylation reactions in rat colonic brush-border membranes

Incubation of rat colonic brush-border membrane vesicles with 200 microM S-adenosyl-L-[Me-3H]methionine resulted in the labeling of both membrane phospholipids and proteins. This labeling was decreased approximately 50% by the methylation inhibitor S-adenosyl-L-homocysteine (2 mM). Utilizing the pH-sensitive fluorescent dye, acridine orange, as a means of determining Na+-H+ exchange, S-adenosyl-L-methionine (200 microM) significantly increased sodium-stimulated proton efflux in these vesicles at all concentrations of sodium (2.5-50 mM) tested. Examination of the kinetic parameters for sodium-stimulated proton efflux in the presence and absence of 200 microM S-adenosyl-L-methionine revealed that the methyl donor increased the Vmax for this exchange mechanism (expressed in arbitrary fluorescence units) by approx. 36% but did not influence its Km for sodium. S-Adenosyl-L-homocysteine (2 mM) inhibited S-adenosyl-L-methionine-mediated stimulation of this exchange process. The results demonstrate that methylation of membrane phospholipids and/or proteins can modulate Na+-H+ exchange in rat colonic brush-border membrane vesicles.     

Modulation of Na+-H+ exchange by ethinyl estradiol in rat colonic brush-border membrane vesicles

Prior studies by our laboratory have suggested that a relationship may exist between rat colonic brush-border membrane vesicular fluidity and Na+-H+ exchange. To further explore this possible relationship, in the present studies the effects of ethinyl estradiol (17 alpha-ethinyl-1,3,5-estratriene-3,17-beta-diol) administration subcutaneously (5 mg/kg body wt. per day) for 5 days, on rat colonic brush-border membrane fluidity and Na+-H+ exchange were examined. This treatment regimen has previously been shown to decrease the lipid fluidity of rat hepatic and rabbit small intestinal plasma membranes. In agreement with these prior studies, the present results demonstrate that this agent decreases the lipid fluidity of treated-rat colonic brush-border membranes compared to control membranes, as assessed by steady-state fluorescence polarization techniques using three different fluorophores. An increase in the cholesterol content and cholesterol/phospholipid molar ratio of treated-membranes appear to, at least partially, be responsible for the fluidity differences. Furthermore, examination of the kinetic parameters for amiloride-sensitive sodium-stimulated proton efflux in treated and control membrane vesicles, utilizing the pH-sensitive fluorescent dye, Acridine orange, revealed that ethinyl estradiol administration decreased the Vmax for this exchange mechanism, expressed in arbitrary fluorescence units, by approx. 25% but did not influence its Km for sodium. These data, therefore, lend further support to the contention that alterations in fluidity may modulate Na+-H+ exchange in rat colonic brush-border membrane vesicles.     

Modulation of rat distal colonic brush-border membrane Na+-H+ exchange by dexamethasone: role of lipid fluidity

Earlier studies by our laboratory have suggested a relationship between an amiloride-sensitive Na+-H+ exchange process and the physical state of the lipids of rat colonic brush-border membrane vesicles. To further assess this possible relationship, a series of experiments were performed to examine the effect of dexamethasone administration (100 micrograms/100 g body wt. per day) subcutaneously for 4 days on Na+-H+ exchange, lipid composition and lipid fluidity of rat distal colonic brush-border membrane vesicles. The results of these studies demonstrate that dexamethasone treatment significantly: (1) increased the Vmax of the Na+-H+ exchange without altering the Km for sodium of this exchange process, utilizing the fluorescent pH-sensitive dye, acridine orange. 22Na flux experiments also demonstrated an increase in amiloride-sensitive proton-stimulated sodium influx across dexamethasone-treated brush-border membrane vesicles; (2) increased the lipid fluidity of treated-membrane vesicles compared to their control counterparts, as assessed by steady-state fluorescence polarization techniques using three different lipid-soluble fluorophores; and (3) increased the phospholipid content of treated-membrane vesicles thereby, decreasing the cholesterol/phospholipid molar ratio of treated compared to control preparations. This data, therefore, demonstrates that dexamethasone administration can modulate amiloride-sensitive Na+-H+ exchange in rat colonic distal brush-border membrane vesicles. Moreover, it adds support to the contention that a direct relationship exists between Na+-H+ exchange activity and the physical state of the lipids of rat colonic apical plasma membranes.     

Amiloride-inhibited Na+ uptake into toad bladder microsomes is Na+-H+ exchange

Amiloride-inhibited Na+ transport into toad urinary bladder microsomes is sensitive to a pH gradient across the vesicular membrane. The magnitude of the gradient was measured directly with acridine orange. Also Na+ could stimulate amiloride-sensitive proton efflux from the microsomes. These results indicated that the transport process was Na+-H+ exchange.     

Proton pathways in rat renal brush-border and basolateral membranes

The quenching of acridine orange fluorescence was used to monitor the formation and dissipation of pH gradients in brush-border and basolateral membrane vesicles isolated from rat kidney cortex. The fluorescence changes of acridine orange were shown to be sensitive exclusively to transmembrane delta pH and not to membrane potential difference. In brush-border membrane vesicles, an Na+ (Li+)-H+ exchange was confirmed. At physiological Na+ concentrations, 40-70% of Na+-H+ exchange was mediated by the electroneutral Na+-H+ antiporter; the remainder consisted of Na+ and H+ movements through parallel conductive pathways. Both modes of Na+-H+ exchange were saturable, with half-maximal rates at about 13 and 24 mM Na+, respectively. Besides a Na+ gradient, a K+ gradient was also able to produce an intravesicular acidification, demonstrating conductance pathways for H+ and K+ in brush-border membranes. Experiments with Cl- or SO2-4 gradients failed to demonstrate measurable Cl--OH- or SO2-4-OH- exchange by an electroneutral antiporter in brush-border membrane vesicles; only Cl- conductance was found. In basolateral membrane vesicles, neither Na+(Li+)-H+ exchange nor Na+ or K+ conductances were found. However, in the presence of valinomycin-induced K+ diffusion potential, H+ conductance of basolateral membranes was demonstrated, which was unaffected by ethoxzolamide and 4,4'-diisothiocyanostilbene-2,2-disulfonic acid. A Cl- conductance of the membranes was also found, but antiporter-mediated electroneutral Cl--OH- or SO2-4-OH- exchange could not be detected by the dye method. The restriction of the electroneutral Na+-H+ exchanger to the luminal membrane can explain net secretion of protons in the mammalian proximal tubule which leads to the reabsorption of bicarbonate.     

Isolation of renal brush-border membrane vesicles by a low-speed centrifugation; effect of sex hormones on Na+-H+ exchange in rat and mouse kidney

Na+-H+ exchange in rat and mouse renal brush-border membrane vesicles was studied by fluorescence quenching of the delta pH indicator, acridine orange. Brush-border membrane vesicles were isolated by a modified Mg/EGTA-precipitation method at low speed centrifugation (8000 X g). The enzymatic characteristics of these membrane vesicles were similar to those obtained by the original high-speed centrifugation method (Biber et al. (1981) Biochim. Biophys. Acta, 647, 169-176). The rates of Na+-H+ exchange in renal brush-border membrane vesicles from male and female rats were similar. Neither ovariectomy nor treatment of ovariectomized rats with estradiol or testosterone changed the activity of Na+-H+ exchanger. The rates of Na+-H+ exchange in the mouse were smaller than in the rat indicating the existence of species differences. Na+-H+ exchange in mouse renal brush-border membranes exhibit strong sex differences, the rates in the male being higher than in the female. Castration of male mice led to a decrease in Na+-H+ exchange to values found in females. Treatment of castrated mice with estradiol had no effect. In contrast, treatment with testosterone increased the rate of the exchanger by more than 100%. The effect of testosterone was restricted to the Vmax of the Na+-H+ exchanger, whereas the apparent Km for Na+ remained unchanged. Na+-dependent D-glucose transport in mouse renal luminal membranes exhibited also sex differences due to the potent stimulatory effect of testosterone. Therefore, Na+-H+ exchange and Na+-dependent D-glucose transport in the mouse kidney are under control of androgen hormones. This effect could be in close connection with the wellknown renotropic action of androgens in the mouse.     

Effect of the preparation method on Na+-H+ exchange and ion permeabilities in rat renal brush-border membranes

The delta pH-dependent quenching of Acridine orange was used to characterize Na+-H+ exchange and K+ and H+ conductances in brush-border membrane vesicles isolated by precipitation with either CaCl2 or MgCl2 from rat kidney cortex. A transmembrane pH difference of 2.5 units (inside acidic) was imposed and the initial rate of its dissipation was followed after injecting a puls of tetramethylammonium gluconate (control) or sodium or potassium gluconate. In membranes isolated by CaCl2, the Na+-H+ exchange was partially electroneutral (45% to 77% of the total exchange) and the rest was due to electrically coupled Na+ and H+ movements through conductive pathways in the membranes. In membranes prepared by MgCl2, the rate of total Na+-H+ exchange was about twice as high as that in membranes obtained by CaCl2 precipitation. However, total and electroneutral exchanges were equal indicating negligible electrically coupled Na+ and H+ movements in these membranes. K0.5 for Na+ in all preparations was in the same range, being in average 30 mM. Amiloride was a competitive inhibitor of Na+-H+ exchange in membranes obtained with both preparations; Ki values ranged between 0.1 and 0.58 mM. The rates of delta pH-dissipation with K+ gradients (+/- valinomycin) were by 50% to 150% higher in membranes prepared with CaCl2 than in membranes isolated with MgCl2 indicating much higher H+ and K+ conductances in membranes obtained with CaCl2. Therefore, the rate of Na+-H+ exchange as well as the conductances for various ions in the isolated brush-border membranes depend on membrane preparation.     

Modulation of rat distal colonic brush-border membrane Na−H exchange by dexamethasone: role of lipid fluidity

Earlier studies by our laboratory have suggested a relationship between an amiloride-sensitive Na⁺−H⁺ exchange process and the physical state of the lipids of rat colonic brush-border membrane vesicles. To further assess this possible relationship, a series of experiments were performed to examine the effect of dexamethasone administration (100 μg/100 g body wt. per day) subcutaneously for 4 days on Na⁺−H⁺ exchange, lipid composition and lipid fluidity of rat distal colonic brush-border membrane vesicles. The results of these studies demonstrate that dexamethasone treatment significantly: (1) increased the V_max of the Na⁺−H⁺ exchange without altering the K_m for sodium of this exchange process, utilizing the fluorescent pH-sensitive dye, acridine orange. ²²Na flux experiments also demonstrated an increase in amiloride-sensitive proton-stimulated sodium influx across dexamethasone-treated brush-border membrane vesicles; (2) increased the lipid fluidity of treated-membrane vesicles compared to their control counterparts, as assessed by steady-state fluorescence polarization techniques using three different lipid-soluble fluorophores; and (3) increased the phospholipid content of treated-membrane vesicles thereby, decreasing the cholesterol/phospholipid molar ratio of treated compared to control preparations. This data, therefore, demonstrates that dexamethasone administration can modulate amiloride-sensitive Na⁺−H⁺ exchange in rat colonic distal brush-border membrane vesicles. Moreover, it adds support to the contention that a direct relationship exists between Na⁺−H⁺ exchange activity and the physical state of the lipids of rat colonic apical plasma membranes.     

Presence of a potential-sensitive Na+ transport across renal brush-border membrane vesicles from rats of the Milan hypertensive strain

Sodium transport was measured in brush-border membrane vesicles prepared from kidney cortex of the Milan hypertensive strain (MHS) rats and the corresponding normotensive controls. In the presence of an outwardly directed proton gradient, 22Na was transiently accumulated in the vesicles. When a transmembrane electrical potential was imposed across membrane vesicles, both the accumulation ratio and the initial uptake were increased, indicating the presence of an electrogenic pathway for sodium in these membranes. The potential-dependent sodium uptake was significantly higher in MHS rats. Kinetic analysis give simple Michaelis Menten curves in the presence and in the absence of a membrane potential. In both conditions Jmax was significantly increased in MHS rats, whereas Km was the same for the two rat strains. Sodium uptake was inhibited by amiloride at concentrations that inhibit Na+-H+ exchange. The presence of the higher, potential-sensitive, sodium uptake in MHS is in agreement with studies on renal physiology which support the hypothesis that an increase in tubular sodium reabsorption may be the primary cause for the development of hypertension in this rat strain.     

The mechanism of decreased Na+-dependent D-glucose transport in brush-border membrane vesicles from rabbit kidneys with experimental Fanconi syndrome

In our previous paper (Yanase, M. et al. (1983) Biochim. Biophys. Acta 733, 95-101) we reported that the Na+-dependent D-glucose uptake into brush-border membrane vesicles is decreased in rabbits with experimental Fanconi syndrome (induced by anhydro-4-epitetracycline). In the present paper we investigate the mechanism underlying this decrease. D-Glucose is taken up into the osmotically active space in anhydro-4-epitetracycline-treated brush-border membrane vesicles and exhibits the same distribution volume and the same degree of nonspecific binding and trapping as in control brush-border membrane vesicles. The passive permeability properties of control and anhydro-4-epitetracycline-treated brush-border membrane vesicles are shown to be the same as measured by the time-dependence of L-glucose efflux from brush-border membrane vesicles. D-Glucose flux was measured by the equilibrium exchange procedure at constant external and internal Na+ concentrations and zero potential. Kinetic analyses of Na+-dependent D-glucose flux indicate that Vmax in anhydro-4-epitetracycline-treated brush-border membrane vesicles (79.3 +/- 7.6 nmol/min per mg protein) is significantly smaller than in control brush-border membrane vesicles (141.3 +/- 9.9 nmol/min per mg protein), while the Km values in the two cases are not different from each other (22.3 +/- 0.9 and 27.4 +/- 1.8 mM, respectively). These results suggest that Na+-dependent D-glucose carriers per se are affected by anhydro-4-epitetracycline, and that this disorder is an important underlying mechanism in the decreased Na+-dependent D-glucose uptake into anhydro-4-epitetracycline-treated brush-border membrane vesicles.     

Inactivation of the renal microvillus membrane Na+-H+ exchanger by histidine-specific reagents

We examined the effect of histidine-specific reagents on the transport activity of the Na+-H+ exchanger in microvillus (brush-border) membrane vesicles isolated from the rabbit renal cortex. Rose bengal-catalyzed photo-oxidation caused irreversible inhibition of the rate of Na+-H+ exchange but also caused significant loss of vesicle integrity. Treatment of the membrane vesicles with diethylpyrocarbonate caused inactivation of Na+-H+ exchange that could not be attributed to vesicle disruption or collapse of transmembrane H+ gradients. Inactivation of Na+-H+ exchange by diethylpyrocarbonate followed pseudo-first order kinetics to below 10% residual activity, could be reversed by hydroxylamine, was reflected by a decreased Vmax with no change in the Km for Na+, was dependent on external pH but not internal pH, was blocked by amiloride, and was enhanced by Na+. These data are consistent with the hypothesis that a diethylpyrocarbonate-sensitive imidazolium residue is the titratable group found in kinetic studies to bind H+ at the external transport site of the Na+-H+ exchanger.     

Inhibition of Na+-H+ exchange by N,N'-dicyclohexylcarbodiimide in isolated rat renal brush border membrane vesicles

The inactivation of rat renal brush border membrane Na+-H+ exchange by the covalent carboxylate reagent N,N'-dicyclohexylcarbodiimide (DCCD) was studied by measuring 1 mM Na+ influx in the presence of a pH gradient (pHi = 5.5; pHo = 7.5) and H+ influx in the presence of a Na+ or Li+ gradient ([Na+]i = 150 mM; [Na+]o = 1.5 mM). In the presence of DCCD, the rate of Na+ uptake decreased exponentially with time and transport inhibition was irreversible. At all DCCD concentrations the loss of activity was described by a single exponential, consistent with one critical DCCD-reactive residue within the Na+-H+ exchanger. Among several carbodiimides the most hydrophobic carbodiimide, DCCD, was also the most effective inhibitor of Na+-H+ exchange. With 40 nmol of DCCD/mg of protein, at 20 degrees C for 30 min, 75% of the amiloride-sensitive 1 mM Na+ uptake was inhibited. Neither the equilibrium Na+ content nor the amiloride-insensitive Na+ uptake was significantly altered by the treatment. The Na+-dependent H+ flux, measured by the change in acridine orange absorbance, was also decreased 80% by the same DCCD treatment. If 150 mM NaCl, 150 mM LiCl, or 1 mM amiloride was present during incubation of the brush border membranes with 40 nmol of DCCD/mg of protein, then Li+-dependent H+ flux was protected 50, 100, or 100%, respectively, compared to membranes treated with DCCD in the absence of Na+-H+ exchanger substrates. The combination of DCCD and an exogenous nucleophile, e.g. ethylenediamine and glycine methyl ester, increased Na+-dependent H+ flux in the presence of 80 nmol of DCCD/mg of protein, compared to the transport after DCCD treatment alone. These findings suggest that the Na+-H+ exchanger contains a single carboxylate residue in a hydrophobic region of the protein, and the carboxylate and/or a nearby endogenous nucleophilic group is critical for exchange activity.     

Demonstration of a Na+/H+ exchange activity in purified canine cardiac sarcolemmal vesicles

Purified canine cardiac sarcolemmal membrane vesicles exhibit a sodium ion for proton exchange activity (Na+/H+ exchange). Na+/H+ exchange was demonstrated both by measuring rapid 22Na uptake into sarcolemmal vesicles in response to a transmembrane H+ gradient and by following H+ transport in response to a transmembrane Na+ gradient with use of the probe acridine orange. Maximal 22Na uptake into the sarcolemmal vesicles (with starting intravesicular pH = 6 and extravesicular pH = 8) was approximately 20 nmol/mg protein. The extravesicular Km of the Na+/H+ exchange activity for Na+ was determined to be between 2 and 4 mM (intravesicular pH = 5.9, extravesicular pH = 7.9), as assessed by measuring the concentration dependence of the 22Na uptake rate and the ability of extravesicular Na+ to collapse an imposed H+ gradient. All results suggested that Na+/H+ exchange was reversible and tightly coupled. The Na+/H+ exchange activity was assayed in membrane subfractions and found most concentrated in highly purified cardiac sarcolemmal vesicles and was absent from free and junctional sarcoplasmic reticulum vesicles. 22Na uptake into sarcolemmal vesicles mediated by Na+/H+ exchange was dependent on extravesicular pH, having an optimum around pH 9 (initial internal pH = 6). Although the Na+/H+ exchange activity was not inhibited by tetrodotoxin or digitoxin, it was inhibited by quinidine, quinacrine, amiloride, and several amiloride derivatives. The relative potencies of the various inhibitors tested were found to be: quinacrine greater than quinidine = ethylisopropylamiloride greater than methylisopropylamiloride greater than dimethylamiloride greater than amiloride. The Na+/H+ exchange activity identified in purified cardiac sarcolemmal vesicles appears to be qualitatively similar to Na+/H+ exchange activities recently described in intact cell systems. Isolated cardiac sarcolemmal vesicles should prove a useful model system for the study of Na+/H+ exchange regulation in myocardial tissue.     

Mixed type inhibition of the renal Na+/H+ antiporter by Li+ and amiloride. Evidence for a modifier site

We studied the interactions of Na+, Li+, and amiloride on the Na+/H+ antiporter in brush-border membrane vesicles from rabbit renal cortex. Cation-mediated collapse of an outwardly directed proton gradient (pHin = 6.0; pHout = 7.5) was monitored with the fluorescent amine, acridine orange. Proton efflux resulting from external addition of Na+ or Li+ exhibited simple saturation kinetics with Hill coefficients of 1.0. However, kinetic parameters for Na+ and Li+ differed (Km for Li+ = 1.2 +/- 0.1 mM; Km for Na+ = 14.3 +/- 0.8 mM; Vmax for Li+ = 2.40 +/- 0.07 fluorescence units/s/mg of protein; Vmax for Na+ = 7.10 +/- 0.24 fluorescence units/s/mg of protein). Inhibition of Na+/H+ exchange by Li+ and amiloride was also studied. Li+ inhibited the Na+/H+ antiporter by two mechanisms. Na+ and Li+ competed with each other at the cation transport site. However, when [Na+] was markedly higher than [Li+], [( Na+] = 90 mM; [Li+] less than 1 mM), we observed noncompetitive inhibition (Vmax for Na+/H+ exchange reduced by 25%). The apparent Ki for this noncompetitive inhibition was congruent to 50 microM. In addition, 2-30 mM intravesicular Li+, but not Na+, resulted in trans inhibition of Na+/H+ exchange. Amiloride was a mixed inhibitor of Na+/H+ exchange (Ki = 30 microM, Ki' = 90 microM) but was only a simple competitive inhibitor of Li+/H+ exchange (Ki = 10 microM). At [Li] = 1 mM and [amiloride] less than 100 microM, inhibition of Na+/H+ exchange by a combination of the two inhibitors was always less than additive. These results suggest the presence of a cation-binding site (separate from the cation-transport site) which could be a modifier site of the Na+/H+ antiporter.     

Transport characteristics of L-glutamate in human jejunal brush-border membrane vesicles

Previous work using human jejunal brush-border membrane vesicles has demonstrated the existence of a distinct transport system in man for acidic amino acids. This system is energized by an inwardly directed Na+ gradient and an outwardly directed K+ gradient. These studies further characterize the transport of L-glutamate in the human jejunal brush-border membrane vesicles. Efflux studies were performed by loading the brush-border membrane vesicles with radiolabeled L-glutamate and sodium chloride. Extravesicular K+ accelerated the efflux of L-glutamate when compared to extravesicular Na+ or choline, indicating that potassium serves to recycle the carrier. Unlabeled extravesicular L-glutamate (but not D-glutamate) also enhanced the efflux of radiolabeled L-glutamate demonstrating that there is a bidirectional similarity to the transport system. The effect of pH on the transport system was also investigated by varying the intravesicular and extravesicular pH from 5.5 to 9. A pH environment of 6.5 produced the highest initial uptake rates as well as the greatest overshoots for transport of L-glutamate into brush-border membrane vesicles. The imposition of an inwardly directed pH gradient (5.5 outside, 7.5 inside) accelerated both the influx and efflux of L-glutamate. These results demonstrate that the L-glutamate carrier system in human jejunum appears to have similar energizing characteristics in either direction across the brush-border membrane. In addition, the system operates at an optimal pH of 6.5 and protonation of the system may enhance its mobility.     

Molecular size of the Na+-H+ antiport in renal brush border membranes, as estimated by radiation inactivation

The radiation inactivation method was applied to brush border membrane vesicles from rat kidney, in order to estimate the molecular size of the Na+-H+ antiporter. Sodium influx (1mM) driven by an acid intravesicular pH was unaffected by the high osmolarity of the cryoprotective solution. Initial rate of influx was estimated by linear regression performed on the first 10 seconds of transport: 0.512 pmol/micrograms protein/s. There was no binding component involved. Incubation performed in the presence of 1 mM amiloride, an inhibitor of the Na+-H+ antiport gave an initial rate of only 0.071 pmol/microgram/s, an 82% inhibition. Membrane vesicles were irradiated at -78 degrees C in a Gammacel Model 220. Sodium influx was reduced, as the dose of radiation increased, but the influx remained linear for the period of time (10s) during which the initial rate was estimated, indicating no alteration of the proton driving force during this time period. Amiloride-insensitive flux remained totally unaffected by the radiation dose, indicating that the passive permeability of the membrane towards sodium was unaffected. The amiloride-sensitive pathway presented a monoexponential profile of inactivation, allowing the molecular size to be estimated at 321 kDa. Based on DCCD-binding studies suggesting the molecular size of the monomer to be around 65 kDa for rat kidney, our results suggest that the functional transporter in the membrane to be a multimer.     

Na+/H+ exchange mechanism in the basolateral membrane of the rat enterocyte

Basolateral membrane vesicles from rat jejunal enterocytes, especially purified of brush-border contamination, were used for Na+ uptake. The basolateral membrane vesicles are osmotically active and under our experimental conditions Na+ binding is much lower than transport. An outwardly directed proton gradient stimulates Na+ uptake at both 5 microM and 5 mM concentrations. The proton gradient effect can be inhibited completely by 2 mM amiloride and partially by either FCCP or NH4Cl (NH3 diffusion). Membrane potential effects can be excluded by having valinomycin plus K+ on both sides of the vesicles. These results suggest that there is an Na+/H+ exchanger in the basolateral membrane of rat enterocytes.     

Cl(-)-HCO3- exchange in rat renal basolateral membrane vesicles

Pathways for HCO3- transport across the basolateral membrane were investigated using membrane vesicles isolated from rat renal cortex. The presence of Cl(-)-HCO3- exchange was assessed directly by 36Cl- tracer flux measurements and indirectly by determinations of acridine orange absorbance changes. Under 10% CO2/90% N2 the imposition of an outwardly directed HCO3- concentration gradient (pHo 6/pHi 7.5) stimulated Cl- uptake compared to Cl- uptake under 100% N2 in the presence of a pH gradient alone. Mediated exchange of Cl- for HCO3- was suggested by the HCO3- gradient-induced concentrative accumulation of intravesicular Cl-. Maneuvers designed to offset the development of ion-gradient-induced diffusion potentials had no significant effect on the magnitude of HCO3- gradient-driven Cl- uptake further suggesting chemical as opposed to electrical Cl(-)-HCO3- exchange coupling. Although basolateral membrane vesicle Cl- uptake was observed to be voltage sensitive, the DIDS insensitivity of the Cl- conductive pathway served to distinguish this mode of Cl- translocation from HCO3- gradient-driven Cl- uptake. No evidence for K+/Cl- cotransport was obtained. As determined by acridine orange absorbance measurements in the presence of an imposed pH gradient (pHo 7.5/pHi 6), a HCO3- dependent increase in the rate of intravesicular alkalinization was observed in response to an outwardly directed Cl- concentration gradient. The basolateral membrane vesicle origin of the observed Cl(-)-HCO3- exchange activity was verified by experiments performed with purified brush-border membrane vesicles. In contrast to our previous observations of the effect of Cl- on HCO3- gradient-driven Na+ uptake suggesting a basolateral membrane Na+-HCO3- for Cl- exchange mechanism, no effect of Na+ on Cl-HCO3- exchange was observed in the present study.     

Chemical modifications of the Na+-H+ antiport in Escherichia coli membrane vesicles

The effects of chemical modifications of the Na+-H+ antiport in Escherichia coli have been analyzed by studying the resulting variations of the energy-dependent, downhill Na+ efflux from membrane vesicles. The histidyl reagent diethylpyrocarbonate (EtO)2C2O3 prevents the activation of the Na+ efflux mechanism by delta microH+ or its components. Inactivation of the antiporter by (EtO)2C2O3 is completely reversed by hydroxylamine. The data suggest that histidine residues are involved in the molecular mechanism of the Na+-H+ antiport. In contrast, no conclusive evidence suggesting participation of carboxylic, tyrosine or sulfhydryl residues in the Na+-H+ exchange reaction has been obtained.     

Uptake of aminoglycoside antibiotics into brush-border membrane vesicles and inhibition of (Na+ + K+)-ATPase activity of basolateral membrane

The effects of aminoglycoside antibiotics on plasma membranes were studied using rat renal basolateral and brush-border membrane vesicles. 3',4'-Dideoxykanamycin was bound to the basolateral membrane and brush-border membrane vesicles. They had a single class of binding sites with nearly the same constant, and the basolateral membrane vesicles had more binding sites than those of the brush-border membrane. Dideoxykanamycin B was transported into the intravesicular space of brush-border membrane vesicles, but not into that of basolateral membrane vesicles. The (Na+ + K+)-ATPase activity of the plasma membrane fraction prepared from the kidney of rat administered with dideoxykanamycin B intravenously decreased significantly. Aminoglycoside antibiotics entrapped in the basolateral membrane vesicles inhibited (Na+ + K+)-ATPase activity, but those added to the basolateral membrane vesicles externally failed to do so. The activity of (Na+ + K+)-ATPase was non-competitively inhibited by gentamicin. It is thus concluded that aminoglycoside antibiotics are taken up into the renal proximal tubular cells across the brush-border membrane and inhibit the (Na+ + K+)-ATPase activity of basolateral membrane. This inhibition may possibly disrupt the balance of cellular electrolytes, leading to a cellular dysfunction, and consequently to the development of aminoglycoside antibiotics' nephrotoxicity.