Sodium-chloride transport in the medullary thick ascending limb of henle's loop: Evidence for a sodium-chloride cotransport system in plasma membrane vesicles

Sodium transport mechanisms were investigated in plasma membrane vesicles prepared from the medullary thick ascending limb of Henle's loop (TALH) of rabbit kidney. The uptake of 22Na into the plasma membrane vesicles was investigated by a rapid filtration technique. Sodium uptake was greatest in the presence of chloride; it was reduced when chloride was replaced by nitrate, gluconate or sulfate. The stimulation of sodium uptake by chloride was seen in the presence of a chloride gradient directed into the vesicle and when the vesicles were equilibrated with NaCl, KCl plus valinomycin so that no chemical or electrical gradients existed across the vesicle (tracer exchange experiments). Furosemide decreased sodium uptake into the vesicles in a dose-dependent manner only in the presence of chloride, with a Ki of around 5 X 10(-6) M. Amiloride, at 2 mM, had no effect on the chloride-dependent sodium uptake. Similarly, potassium removal had no effect on the chloride-dependent sodium uptake and furosemide was an effective inhibitor of sodium uptake in a potassium-free medium. The results show the presence of a furosemide-sensitive sodium-chloride cotransport system in the plasma membranes of the medullary TALH. There is no evidence for a Na+/H+ exchange mechanism or a Na+ -K+ -Cl- cotransport system. The sodium-chloride cotransport system would effect the uphill transport of chloride against its electrochemical potential gradient at the luminal membrane of the cell.     

Sodium-amino acid cotransport by type II alveolar epithelial cells

Type II alveolar epithelial cell monolayers have been shown to actively transport sodium (Na+). Coupling to amino acid uptake could be an important mechanism for Na+ entry into these cells. This study demonstrates the presence of such a coupled cotransport mechanism in the plasma membrane of isolated type II cells by use of the nonmetabolizable amino acid analogue alpha-methylaminoisobutyric acid (MeAIB). Transport of MeAIB in 137 mM Na+ is saturable, with the uptake constant (Vmax) equaling 13.9 pmol X mg prot-1 X s-1 and the Michaelis-Menten constant (Km) equaling 0.13 mM. In the presence of Na+, MeAIB is accumulated against a concentration gradient. MeAIB uptake in the absence of Na+ is linear with MeAIB concentration, as expected for simple diffusion. The Hill coefficient for Na+-MeAIB cotransport is 1.11, suggesting a 1:1 stoichiometry. Proline inhibits Na+-MeAIB cotransport, with Ki equaling 0.5 mM. These findings suggest that Na+-amino acid cotransport may be an important pathway for Na+ (and/or amino acid) uptake into type II alveolar epithelial cells.     

Sodium ion-dependent amino acid transport in membrane vesicles of Bacillus stearothermophilus.

Amino acid transport in membrane vesicles of Bacillus stearothermophilus was studied. A relatively high concentration of sodium ions is needed for uptake of L-alanine (Kt = 1.0 mM) and L-leucine (Kt = 0.4 mM). In contrast, the Na(+)-H(+)-L-glutamate transport system has a high affinity for sodium ions (Kt less than 5.5 microM). Lithium ions, but no other cations tested, can replace sodium ions in neutral amino acid transport. The stimulatory effect of monensin on the steady-state accumulation level of these amino acids and the absence of transport in the presence of nonactin indicate that these amino acids are translocated by a Na+ symport mechanism. This is confirmed by the observation that an artificial delta psi and delta mu Na+/F but not a delta pH can act as a driving force for uptake. The transport system for L-alanine is rather specific. L-Serine, but not L-glycine or other amino acids tested, was found to be a competitive inhibitor of L-alanine uptake. On the other hand, the transport carrier for L-leucine also translocates the amino acids L-isoleucine and L-valine. The initial rates of L-glutamate and L-alanine uptake are strongly dependent on the medium pH. The uptake rates of both amino acids are highest at low external pH (5.5 to 6.0) and decline with increasing pH. The pH allosterically affects the L-glutamate and L-alanine transport systems. The maximal rate of L-glutamate uptake (Vmax) is independent of the external pH between pH 5.5 and 8.5, whereas the affinity constant (Kt) increases with increasing pH. A specific transport system for the basic amino acids L-lysine and L-arginine in the membrane vesicles has also been observed. Transport of these amino acids occurs most likely by a uniport mechanism.     

L-threonine transport in pig jejunal brush border membrane vesicles. Functional characterization of the unique system B in the intestinal epithelium.

Uptake and inhibitory kinetics of [3H]L-threonine were evaluated in preparations of pig jejunal brush border membrane vesicles. Uptake of [3H]L-threonine under O-trans, Na+ gradient, and O-trans, Na(+)-free conditions was best described by high affinity transport (Km < 0.01 mM) plus a nonsaturable component. The maximal velocity of transport was 3-fold greater under Na+ gradient conditions. 100 mM concentrations of all of the dipolar amino acids and 2-aminobicyclo[2.2.1]heptane-2-carboxylic acid caused complete inhibition of [3H]L-threonine transport under Na+ gradient and Na(+)-free conditions. Imino acids, anionic amino acids, cationic amino acids, and methylamino-isobutyric acid caused significant partial inhibition of L-threonine uptake. Inhibitor concentration profiles for proline and lysine were consistent with low affinity competitive inhibition. The Ki values of alanine and phenylalanine approximated 0.2 and 0.5 mM, respectively, under both Na+ gradient and Na(+)-free conditions. These data indicate that the transport system available for L-threonine in the intestinal brush border membrane (system B) is functionally distinct from other amino acid transport systems. Comparison of kinetics parameters in the presence and absence of a Na+ gradient suggests that both partially and fully loaded forms of the carrier can function to translocate substrate and that Na+ serves to accelerate L-threonine transport by a mechanism that does not involve enhanced substrate binding.     

Inhibition of the Na+/I- symporter by harmaline and 3-amino-1-methyl-5H-pyrido(4,3-b)indole acetate in thyroid cells and membrane vesicles

Novel inhibitors of the Na+/I- symporter were identified using rat-thyroid-derived FRTL-5 cells and sealed vesicles from calf thyroid as model systems. Na(+)-dependent 125I- uptake was inhibited by the hallucinogenic drug harmaline and by a chemically related convulsive agent, 3-amino-1-methyl- 5H-pyrido(4,3-b)indole acetate (TRP-P-2). TRP-P-2 (Ki = 0.25 mM) was tenfold more effective as an inhibitor than harmaline (Ki = 4.0 mM). Inhibition by TRP-P-2 was competitive with respect to Na+ and was fully reversible. Although TRP-P-2 is a relatively low-affinity inhibitor, its affinity for the Na+ site of the Na+/I- symporter is over 100 times higher than that of Na+ (Km = 50 mM). 45Ca(2+)-efflux rates in calf thyroid membrane vesicles were not affected by TRP-P-2, indicating that membrane integrity is not disrupted by the drug. These findings show that TRP-P-2 may be a potentially useful tool for the identification and characterization of the Na+/I- symporter.     

Delta endotoxin is a potent inhibitor of the (Na,K)-ATPase

A 68-kDa protein, delta endotoxin, produced by Bacillus thuringiensis ssp. Kurstaki inhibits ion transport, (Na,K)-ATPase, and K+-p-nitrophenylphosphatase activity catalyzed by the Na+ pump. The Ki for inhibition of the K+-p-nitrophenylphosphatase activity of purified dog kidney (Na,K)-ATPase was approximately 0.37 microM. Delta endotoxin had a similar Ki for inhibition of (Na,K)-ATPase activity when assayed at low Na+ concentration (10 mM) but the inhibition was reversed when high concentrations of Na+ (100 mM NaCl) were added to the assay. Phosphorylation of the active site aspartyl residue with 32PO3-4 was also blocked by delta endotoxin. Ouabain-sensitive 86Rb+ uptake into intact human red blood cells was not inhibited by externally added toxin; however, strophanthidin-inhibitable 22Na+ uptake into inside-out vesicles from red blood cells was completely blocked by delta endotoxin (Ki = 0.73 microM). These data suggest that delta endotoxin must enter the cell before it can inhibit the Na+ pump.     

Proton dependence of the partial reactions of the sodium-proton exchanger in renal brush border membranes.

The pre-steady state time dependence of Na+ accumulation by the Na(+)-H+ exchanger in renal brush border membrane vesicles was investigated at 0 degree C by a manual mixing technique using amiloride to quench the reaction. Dilution of acid-loaded (pHi 5.7) vesicles into an alkaline medium (pHo 7.7) containing 1 mM 22Na+ produced a time course of amiloride-sensitive Na+ uptake that consisted of three distinct phases: 1) a lag, 2) a monoexponential "burst," and 3) a linear or steady state phase. Experiments testing for the presence of 22Na+ backflux, residual Na+ binding to the membrane, and hysteresis were negative, lending support to the hypothesis that the burst phase corresponds to Na+ translocation during the initial turnover of Na(+)-H+ exchanger. Lowering the internal pH increased the amount of na+ uptake in each of the phases without affecting the apparent burst rate, whereas lowering the external pH inhibited Na+ uptake while increasing the duration of the lag phase. The pattern of inhibition produced by external H+ was of the simple competitive type, indicating that Na+ and H+ share a common binding site. Steady state Na+ uptake showed a sigmoidal dependence on internal pH (Hill coefficient = 1.67), consistent with the presence of an internal allosteric H+ activation site. Alkaline loading conditions (pHi 7.7), which favor desaturation of the internal H+ binding sites, completely abolished Na+ uptake in the steady state. In contrast, Na+ accumulation during the burst phase was reduced to 25% of an acid-loaded (pHi 5.7) control. The persistence of the burst phase and the disappearance of steady state Na+ uptake under alkaline loading conditions suggest that recycling of the H(+)-loaded exchanger is a late event in the transport cycle that follows Na+ translocation (ping-pong mechanism) and controls the steady state rate of Na+ accumulation. Activation of the recycling step involves sequential binding of H+ to the allosteric and transport sites, thus accounting for the cooperative dependence of steady state Na+ uptake on the internal [H+].     

Cation and harmaline interactions with Na(+)-independent dibasic amino acid transport system y+ in human erythrocytes and in erythrocytes from a primitive vertebrate the pacific hagfish (Eptatretus stouti).

Transport systems y+, asc and ASC exhibit dual interactions with dibasic and neutral amino acids. For conventional Na(+)-dependent neutral amino acid system ASC, side chain amino and guanido groups bind to the Na+ site on the transporter. The topographically equivalent recognition site on related system asc binds harmaline (a Na(+)-site inhibitor) with the same affinity as asc (apparent Ki range 1-4 mM), but exhibits no detectable affinity for Ha. Although also classified as Na(+)-independent, dibasic amino acid transport system y+ accepts neutral amino acids when Na+ or another acceptable cation is also present. This latter observation implies that the y+ translocation site binds Na+ and suggests possible functional and structural similarities with ASC/asc. In the present series of experiments with human erythrocytes, system y(+)-mediated lysine uptake (5 microM, 20 degrees C) was found to be 3-fold higher in isotonic sucrose medium than in normal 150 mM NaCl medium. This difference was not a secondary consequence of changes in membrane potential, but resulted from Na+ functioning as a competitive inhibitor of transport. Apparent Km and Vmax values for lysine transport at 20 degrees C were 15.2 microM and 183 mumol/l cells per h, respectively, in sucrose medium and 59.4 microM and 228 mumol/l cells per h in Na+ medium. Similar results were obtained with y+ in erythrocytes of a primitive vertebrate, the Pacific hagfish (Eptatretus stouti), indicating that Na(+)-inhibition is a general property of this class of amino acid transporter. At a permeant concentration of 5 microM, the IC50 value for Na(+)-inhibition of lysine uptake by human erythrocytes was 27 mM. Other inorganic and organic cations, including K+ and guanidinium+, also inhibited transport. In parallel with its actions on ASC/asc harmaline competitively inhibited lysine uptake by human cells in sucrose medium. As predicted from mutually competitive binding to the y+ translocation site, the presence of 150 mM Na+ increased the harmaline inhibition constant (Ki) from 0.23 mM in sucrose medium to 0.75 mM in NaCl medium. We interpret these observations as further evidence that y+, asc and ASC represent a family of closely related transporters with a common evolutionary origin.     

p-Aminohippurate transport in basal-lateral membrane vesicles from rabbit renal cortex: stimulation by pH and sodium gradients

p-Aminohippuric acid (PAH) uptake was studied in basal-lateral membrane vesicles prepared from rabbit renal cortex. An outwardly directed hydroxyl gradient (pHo = 6.0, pHi = 7.6) stimulated PAH uptake slightly over that when the internal and external pH values were equal at 7.6. A 100 mM sodium gluconate gradient directed into the basal-lateral membrane vesicles increased PAH uptake about 2-fold over that when N-methyl-D-glucamine or potassium gluconate gradients were present. When hydroxyl and sodium gradients were simultaneously imposed (pHo = 6.0, pHi = 7.6 and 100 mM sodium gluconate extravesicularly) PAH uptake was stimulated greater than with the pH or Na+ gradient alone. In fact, an 'overshoot' was observed. Countertransport experiments showed that either intravesicular PAH or intravesicular PAH and Na+ could stimulate 3H-PAH uptake. Probenecid, an inhibitor of organic anion transport, inhibited both the hydroxyl-stimulated and Na+ gradient-stimulated PAH uptake but the greatest inhibition by probenecid was seen when the hydroxyl and sodium gradients were both present. Thus, it is proposed that the driving force for PAH accumulation across the basal-lateral membrane of the proximal tubule is a transport system which moves Na+ and PAH into the cell for an hydroxyl ion leaving the cell, i.e. a sodium-dependent anion-anion exchange system.     

Sensitivity of renal brush-border Na+-cotransport systems to anions

The effect of anions on Na+-cotransport of succinate, lactate, glucose, and phenylalanine was studied under voltage clamped conditions in brush-border membrane vesicles prepared from rabbit renal cortex. The initial rate of succinate uptake varied by an order of magnitude depending on the anion: the highest rates were obtained with fluoride and gluconate, and the lowest with iodide. The anion sequence corresponded with the inverse of the anion hydration energies. The kinetics of succinate uptake were measured in the presence of fluoride and chloride. There was no difference in the maximal rates of uptake, but the Kt in fluoride (0.30 mM) was less than half that in chloride (0.70 mM), i.e. Cl- behaved as a competitive inhibitor of succinate transport with a Ki of 150 mM. The uptake of L-lactate, D-glucose and L-phenylalanine was less sensitive to anions, and there was no correlation with hydration energies. We conclude that the anion effects on sugar and amino acid uptakes measured under open-circuit conditions are largely due to variations in membrane potential, but in the case of the dicarboxylate transporter anions behave as weak competitive inhibitors. The specificity of the anion inhibition suggests that the dicarboxylate binding sites have a weak field strength relative to water.     

Interaction of external H+ with the Na+-H+ exchanger in renal microvillus membrane vesicles

We examined the effects of external H+ on the kinetics of Na+-H+ exchange in microvillus membrane vesicles isolated from the rabbit renal cortex. The initial rate of Na+ influx into vesicles with internal pH 6.0 was optimal at external pH 8.5 and was progressively inhibited as external pH was reduced to 6.0. A plot of 1/V versus [H+]o was linear and yielded apparent KH = 35 nM (apparent pK 7.5). In vesicles with internal pH 6.0 studied at external pH 7.5 or 6.6, apparent KNa was 13 or 54 mM, Ki for inhibition of Na+ influx by external Li+ was 1.2 or 5.2 mM, Ki for inhibition by external NH4+ was 11 or 50 mM, and Ki for inhibition by external amiloride was 7 or 25 microM, respectively. These findings were consistent with competition between each cation and H+ at a site with apparent pK 7.3-7.5. Lastly, stimulation of 22Na efflux by external Na+ (i.e. Na+-Na+ exchange) was inhibited as external pH was reduced from 7.5 to 6.0, also consistent with competition between external H+ and external Na+. Thus, in contrast with internal H+, which interacts at both transport and activator sites, external H+ interacts with the renal microvillus membrane Na+-H+ exchanger at a single site, namely the external transport site, where H+, Na+, Li+, NH4+, and amiloride all compete for binding.     

Kidney epithelial cells of monkey origin (BSC-1) express a sodium bicarbonate cotransport. Characterization by 22Na+ flux measurements

Na movement across the plasma membranes of confluent monolayers of monkey kidney epithelial cells (BSC-1) was studied using 22Na+ uptake and efflux techniques in the presence of 10(-4) M ouabain. In the presence of 28 mM bicarbonate, uptake was inhibited by both 10(-3) M amiloride and 10(-3) M 4,4'diisothiocyanostilbene-2,2'-disulfonic acid (DIDS). In DIDS-pretreated cells, 10(-3) M amiloride led to a further reduction of 22Na+ uptake, while 10(-5) furosemide was ineffective. DIDS also inhibited sodium efflux, indicating that the DIDS-sensitive pathway mediates both influx and efflux of 22Na+. DIDS-sensitive 22Na+ uptake, as studied in the presence of both 10(-4) M ouabain and 10(-3) M amiloride, was abolished by the absence of bicarbonate, which could not be substituted by other plasma membrane-permeable buffers. In 28 mM HCO3-, DIDS-sensitive uptake of 28 mM Na+ was cis-inhibited by 124 mM Na+, but no significant inhibition by K+ or Li+ was found. DIDS-sensitive 22Na+ uptake was a saturable function of both Na+ concentration (apparent Km between 20 and 40 mM at 28 mM HCO3-) and HCO3- concentration (apparent Km between 7 and 14 mM at 151 mM Na+). Intracellular microelectrode measurements showed that net Na+ transport in the presence of HCO3- is electrogenic, i.e. that there is anion cotransport with Na+. This effect is abolished by 1 mM DIDS. It is concluded that monkey kidney epithelial cells possess a stilbene-sensitive, electrogenic sodium bicarbonate symport, which may play an important role in bicarbonate reabsorption in the mammalian kidney.     

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.     

Gentamicin inhibits Na+-dependent D-glucose transport in rabbit kidney brush-border membrane vesicles

We studied the effect of gentamicin on Na+-dependent D-glucose transport into brush-border membrane vesicles isolated from rabbit kidney outer cortex (early proximal tubule) and outer medulla (late proximal tubule) in vitro. We found the same osmotically active space and nonspecific binding between control and gentamicin-treated brush-border membrane vesicles. There was no difference in the passive permeability properties between control and gentamicin-treated brush-border membrane vesicles. Kinetic analyses of D-glucose transport into 1 mM gentamicin-treated brush-border membrane vesicles demonstrated that gentamicin decreased Vmax in the outer cortical preparation, while it did not affect Vmax in the outer medullary preparation. With regard to Km, there was no effect of gentamicin in any vesicle preparation. When brush-border membrane vesicles were incubated with higher concentrations of gentamicin, Na+-dependent D-glucose transport was inhibited dose-dependently in both outer cortical and outer medullary preparations. Dixon plots yield inhibition constant Ki = 4 mM in the outer cortical preparation and Ki = 7 mM in the outer medullary preparation. These results indicate that the Na+-dependent D-glucose transport system in early proximal tubule is more vulnerable to gentamicin toxicity than that in late proximal tubule.     

Na+-Independent Transporters, LAT-2 and b0,+, Exchange L-DOPA with Neutral and Basic Amino Acids in Two Clonal Renal Cell Lines

The present study examined the functional characteristics of L-DOPA transporters in two functionally different clonal subpopulations of opossum kidney (OKLC and OKHC) cells. The uptake of L-DOPA was largely Na+-independent, though in OKHC cells a minor component (approximately 15%) required extracellular Na+. At least two Na+-independent transporters appear to be involved in L-DOPA uptake. One of these transporters has a broad specificity for small and large neutral amino acids, is stimulated by acid pH and inhibited by 2-aminobicyclo(2,2,l)-heptane-2-carboxylic acid (BCH; OKLC, Ki = 291 mM; OKHC, Ki = 380 mM). The other Na+-independent transporter binds neutral and basic amino acids and also recognizes the di-amino acid cystine. [14C]-L-DOPA efflux from OKLC and OKHC cells over 12 min corresponded to a small amount of intracellular [14C]-L-DOPA. L-Leucine, nonlabelled L-DOPA, BCH and L-arginine, stimulated the efflux of [14C]-L-DOPA in a Na+-independent manner. It is suggested that L-DOPA uses at least two major transporters, systems LAT-2 and b0,+. The transport of L-DOPA by LAT-2 corresponds to a Na+-independent transporter with a broad specificity for small and large neutral amino acids, stimulated by acid pH and inhibited by BCH. The transport of L-DOPA by system b0,+ is a Na+-independent transporter for neutral and basic amino acids that also recognizes cystine. LAT-2 was found equally important at the apical and basolateral membranes, whereas system b0,+ had a predominant distribution in apical membranes.     

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.     

Chemotactic factor-induced activation of Na+/H+ exchange in human neutrophils. I. Sodium fluxes

The nature of Na+ fluxes in resting and in chemotactic factor-activated human neutrophils was investigated. In resting cells, ouabain-insensitive unidirectional 22Na+ in- and effluxes represented passive electrodiffusional fluxes through ion channels: they were nonsaturable and voltage-dependent (PNa = 4.3 X 10(-9) cm/s). Amiloride (1 mM) had little effect on resting 22Na+ influx (approximately 0.8 meq/liter X min), thereby suggesting a minor contribution of Na+/H+ exchange and a lack of amiloride-sensitive Na+ channels. When neutrophils were exposed to the chemotactic tripeptide N-formyl-methionyl-leucyl-phenylalanine (FMLP, 0.1 microM), 22Na+ influx was stimulated approximately 30-fold (initial rate approximately 22 meq/liter X min). The FMLP-induced 22Na+ influx was saturable with respect to external Na+ (Km 26-35 mM, Vmax approximately 28 meq/liter X min), was electroneutral, and could be competitively inhibited by amiloride (Ki 10.6 microM). From a resting value of approximately 30 meq/liter of cell water, internal Na+ in FMLP-stimulated cells rose exponentially to reach a concentration of approximately 60 meq/liter by 10-15 min. This uptake was blocked by amiloride. FMLP also stimulated the efflux of 22Na+ which followed a single exponential time course (rate coefficient approximately 0.16 min-1). The FMLP-induced 22Na+ fluxes were similar to those observed with 10 microM monensin, a known Na+/H+ exchanging ionophore. The data indicate that FMLP activates an otherwise quiescent, amiloride-sensitive Na+/H+ exchange. Furthermore, all of the FMLP-induced 22Na+ fluxes can be satisfactorily accounted for by transport through the exchanger, leaving little room for an appreciable increase in Na+ conductance.     

The mechanism of insulin stimulation of (Na+,K+)-ATPase transport activity in muscle

Since the mechanism underlying the insulin stimulation of (Na+,K+)-ATPase transport activity observed in multiple tissues has remained undetermined, we have examined (Na+,K+)-ATPase transport activity (ouabain-sensitive 86Rb+ uptake) and Na+/H+ exchange transport (amiloride-sensitive 22Na+ influx) in differentiated BC3H-1 cultured myocytes as a model of insulin action in muscle. The active uptake of 86Rb+ was sensitive to physiological insulin concentrations (1 nM), yielding a maximum increase of 60% without any change in 86Rb+ permeability. In order to determine the mechanism of insulin stimulation of (Na+,K+)-ATPase activity, we demonstrated that insulin also stimulates passive 22Na+ influx by Na+/H+ exchange transport (maximal 200% increase) and an 80% increase in intracellular Na+ concentration with an identical time course and dose-response curve as insulin-stimulated (Na+,K+)-ATPase transport activity. Incubation of the cells with high [Na+] (195 mM) significantly potentiated insulin stimulation of ouabain-inhibitable 86Rb+ uptake. The ionophore monensin, which also promotes passive Na+ entry into BC3H-1 cells, mimics the insulin stimulation of ouabain-inhibitable 86Rb+ uptake. In contrast, incubation with amiloride or low [Na+] (10 mM), both of which inhibit Na+/H+ exchange transport, abolished the insulin stimulation of (Na+,K+)-ATPase transport activity. Furthermore, each of these insulin-stimulated transport activities displayed a similar sensitivity to amiloride. These results indicate that insulin stimulates a large increase in Na+/H+ exchange transport and that the resulting Na+ influx increases the intracellular Na+ concentration, thus activating the internal Na+ transport sites of the (Na+,K+)-ATPase. This Na+ influx is, therefore, the mediator of the insulin-induced stimulation of membrane (Na+,K+)-ATPase transport activity classically observed in muscle.     

Topographical similarities between harmaline inhibition sites on Na+-dependent amino acid transport system ASC in human erythrocytes and Na+-independent system asc in horse erythrocytes

Na+-dependent system ASC and Na+-independent system asc are characterized by a common selectivity for neutral amino acids of intermediate size such as L-alanine and by their interactions with dibasic amino acids. For system ASC, the positive charge on the dibasic amino acid side chain is considered to occupy the Na+-binding site on the transporter. We report here the use of harmaline (a Na+-site inhibitor in some systems) as a probe of possible structural homology between these two classes of amino acid transporter. Harmaline was found to inhibit human erythrocyte system ASC noncompetitively with respect to L-alanine concentration, but approximated competitive inhibition with respect to Na+ concentration (apparent Ki = 2.0 and 0.9 mM, respectively). Similarly, harmaline noncompetitively inhibited L-alanine uptake by horse erythrocyte systems asc1 and asc2 (apparent Ki = 2.0 and 1.9 mM, respectively). In contrast, harmaline functioned as a competitive inhibitor of L-lysine uptake by system asc1 (apparent Ki = 2.6 mM). It is concluded that harmaline competes with Na+ for binding to system ASC and that a topographically similar harmaline inhibition site is present on system asc. This site does not however bind Na+, the asc1 transporter exhibiting normal L-alanine and L-lysine influx kinetics in the total absence of extracellular cations.     

Evidence for a lactate transport system in the sarcolemmal membrane of the perfused rabbit heart: kinetics of unidirectional influx, carrier specificity and effects of glucagon

The kinetics and specificity of L-lactate transport into cardiac muscle were studied during a single transit through the isolated perfused rabbit heart using a rapid (15 s) paired-tracer dilution technique. Kinetic experiments revealed that lactate influx was highly stereospecific and saturable with an apparent Kt = 19 +/- 6 mM and a Vmax = 8.4 +/- 1.5 mumol/min per g (mean +/- S.E., n = 14 hearts). At high perfusate concentrations (10 mM), the inhibitors alpha-cyano-4-hydroxycinnamate (Ki = 7.3 mM), pyruvate (Ki = 6.5 mM), acetate (Ki = 19.4 mM) and chloroacetate (Ki = 28 mM) reduced L-lactate influx, and Ki values were estimated assuming a purely competitive interaction of the inhibitors with the monocarboxylate carrier. The monocarboxylic acids [14C]pyruvate and [3H]acetate were themselves transported, and sarcolemmal uptakes of respectively 38 +/- 1% and 70 +/- 8% were measured relative to D-mannitol. Perfusion of hearts for 10-30 min with 0.15 or 1.5 microM glucagon increased myocardial lactate production and simultaneously inhibited tracer uptake of lactate, pyruvate and acetate. It is concluded that a stereospecific lactate transporter exhibiting an affinity for other substituted monocarboxylic acids is operative in the sarcolemmal plasma membrane of the rabbit myocardium.