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.     

Mechanism of proline transport in Escherichia coli K12. II. Effect of alkaline cations on binding of proline to a H+/proline symport carrier in cytoplasmic membrane vesicles

The substrate binding reaction of the proline carrier was investigated in nonenergized conditions using cytoplasmic membrane vesicles prepared from the proline carrier-overproducing strain MinS/ pLC4 -45 of Escherichia coli K12. The binding activity specifically required both alkaline cations (X+), Na+ and Li+, and protons. The Na+-dependent binding activity was dependent on the proline carrier, which is the product of the putP gene, and was not affected by ionophores and energy transduction inhibitors. The parameters of proline binding were determined by double reciprocal plots in reaction media with various combinations of Na+ and H+ concentrations. The apparent dissociation constant was greatly affected by the Na+ and H+ concentrations of the medium and could be expressed as a combination of the reciprocals of the Na+ and H+ concentrations, while the maximum number of binding sites remained constant. The characteristics of proline binding to the carrier can be explained by a mechanism in which the unloaded carrier forms a carrier/H+/X+ (CH+X+) complex by a random equilibrium and only the CH+X+ complex binds substrate in nonenergized conditions, as proposed for the Na+/H+/glutamate symport carrier of E. coli B ( Fujimura , T., Yamato , I., and Anraku , Y. (1983) Biochemistry 22, 1954-1959).     

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.     

Kinetics of the intestinal brush border proline (Imino) carrier

The kinetics of L-proline transport across intestinal brush borders via the Imino carrier were studied using membrane vesicles. The Imino carrier is defined as the agent responsible for L-alanine insensitive. Na+-dependent uptake of L-proline. Initial rate measurements were made under voltage clamped conditions (pD = 0) to investigate L-proline transport as a function of cis and trans Na+ and proline concentrations. Under zero-trans conditions, increasing cis Na+ activated proline uptake with a Hill coefficient of 1.7 and decreased the apparent Kt with no change in Jimax. The Jimax was approximately 60 pmol mg-1 s-1 and the apparent Kt ranged from 0.25 mM at cis Na = 100 to 1.0 mM at cis Na+ = 30 mM. Trans Na inhibited proline uptake via a reduction in Jimax. Trans proline had no significant effect in the absence of trans Na+, but it relieved the trans Na+ inhibition. Under equilibrium exchange conditions, the Jimax was twice that observed under zero-trans conditions. These kinetics of L-proline transport suggest a model in which uptake occurs by a rapid equilibrium iso-ordered ter ter system. Two Na+ ions bind first to the carrier on the cis face of the membrane to increase the affinity of the carrier for proline. The fully loaded complex then isomerizes to release the substrates to the trans side. The partially loaded Na+-only forms are unable to translocate across the membrane. A rate-limiting step appears to be the isomerization of unloaded carrier from the trans to the cis side of the membrane.     

Stimulatory effect of lithium ion on proline transport by whole cells of Escherichia coli.

The effect of monovalent cations on proline transport in whole cells of Escherichia coli K-12 has been examined. Lithium ion added to the uptake medium stimulated proline transport severalfold and K+ and Na+ were slightly effective, whereas Rb+, Cs+, and NH4+ were completely without effect. The stimulatory effect of Li+ on proline transport was not due to an increase in osmolarity of the uptake medium, and d 5 mM p-chloromercuribenzene sulfonic acid completely blocked this effect of Li+ without having any effect on the basal rate of proline transport. The Arrhenius plots for Li+-stimulated transport showed a clear transition point at 35 degrees C in addition to 20 degrees C which was also detectable in the basal transport. Lithium ion stimulated proline transport synergistically in the presence of glucose and succinate as a carbon source. The addition of 2.5 mM KCN or 0.5 mM arsenate did not inhibit this synergistic effect, although the presence of these inhibitors inhibited completely the stimulation of proline transport induced by the addition of carbon source. Carbonylcyanide m-chlorophenylhydrazone and 2,4-dinitrophenol blocked both the basal and Li+-stimulated proline transport. When membrane potential of E. coli cells was measured by the dibenzyldimethylammonium uptake method, the incubation of Li+ with the cells did not affect the preexisting membrane potential. These results suggest that Li+ stimulates proline transport by intact cells of E. coli in a manner somewhat affecting membrane component(s) different from the transport carrier of proline. It is uncertain whether the effect of Li+ is directly involved in the mechanisms of energy coupling of proline transport.     

Mg2+ efflux is accomplished by an amiloride-sensitive Na+/Mg2+ antiport

Mg2+ efflux from Mg2+-preloaded chicken erythrocytes is caused by an electroneutral Na+/Mg2+ antiport. It depends specifically on extracellular Na+, according to Michaelis-Menten kinetics (Km = 25 mM), and is reversibly noncompetitively inhibited by amiloride (Ki = 0.59 mM). In contrast to Na+/H+ antiport, Li+, Ca2+ and N-ethylmaleimide do not interfere with Na+/Mg2+ antiport. The Na+/Mg2+ antiport is driven by the intracellular/extracellular Mg2+ gradient.     

Mechanism of proline transport in Escherichia coli K12. I. Effect of a membrane potential on the kinetics of 2H+/proline symport in cytoplasmic membrane vesicles

The stoichiometric coupling mechanism of the membrane potential (delta psi) in the reaction of H+/proline symport was investigated kinetically, using cytoplasmic membrane vesicles of the proline carrier-overproducing strain of Escherichia coli MinS/ pLC4 -45. When a delta psi was imposed across the cytoplasmic membrane by respiration, the Michaelis constant of transport (Kt) was lowered to about 1 microM, which was 2 orders of magnitude smaller than that of passive influx and efflux, and the maximum velocity (Vmax) was concomitantly enhanced as an exponential function of delta psi. Thermodynamically, the carrier translocated proline with a stoichiometry of 2 mol of protons versus 1 mol of substrate when driven by a delta psi at pH 8.0. Data on the delta psi dependence of Vmax of proline transport could be explained quantitatively by the Geck-Heinz hypothesis (Geck, P., and Heinz, E. (1976) Biochim, Biophys. Acta 443, 49-63). A symmetrical model of the 2H+/proline symport via formation of a carrier/H+/substrate (CH+H+S) intermediate is proposed. In this model, the effect of delta psi on the Kt was resolved as stimulation of formation of a transport intermediate, whereas the effect of delta psi on the Vmax was explained by enhancement of translocation of loaded carriers between the two sides of the membrane.     

Biochemical characterization of the amiloride-sensitive Na+/H+ antiport in Chinese hamster lung fibroblasts

Net H+ fluxes across the plasma membrane of Chinese hamster lung fibroblasts (CC139) were monitored by pH-stat titration. Na+-depleted cells release H+ upon addition of Na+. Conversely Na+- or Li+-loaded cells take up H+ from the medium when shifted to a Na+,Li+-free medium. This reversible Na+ (or Li+)-dependent H+ flux is inhibited by amiloride and does not occur in digitonin-permeabilized cells. A similar Na+/H+ exchanger was identified in vascular smooth muscle cells, corneal and aortic endothelial cells, lens epithelial cells of bovine origin, and human platelets. Kinetic studies carried out with CC139 cells indicate the following properties: 1) half-saturation of the system is observed at pH = 7.8, in the absence of Na+; 2) external Na+ stimulates H+ release and inhibits H+ uptake in a competitive manner (Ki = 2-3 mM); 3) amiloride is a competitive inhibitor for Na+ (Ki congruent to 1 microM) and a noncompetitive inhibitor for H+; 4) a coupling ratio of 1.3 +/- 0.3 for the H+/Li+ exchange suggests a stoichiometry of 1:1. We conclude that CC139 cells possess in their plasma membrane a reversible, electroneutral, and amiloride-sensitive Na+/H+ antiporter, with two distinct and mutually exclusive binding sites for Na+ and H+. The rapid stimulation of the Na+/H+ antiporter in G0/G1-arrested CC139 cells upon addition of growth factors, together with the fact that intracellular H+ concentration is, under physiological conditions, around the apparent K0.5 of the system, strongly suggests a key role of this antiport in pHi regulation and mitogen action.     

Specificity of intestinal brush-border proline transport: cyanine dye studies

The ability of rabbit jejunal brush borders to transport inhibitors of the imino carrier was investigated in membrane vesicles by measuring their ability to depolarize the membrane potential. Membrane potentials were monitored using a voltage-sensitive cyanine dye. Piperidine and pyrrolidine carboxylic acids, which are potent inhibitors of Na+-dependent proline transport (Ki less than 0.5 mM) depolarize the potential in a Na+-dependent, saturable manner indicating transport. On the other hand, N-methylated amino acids, which are fair inhibitors (Ki 2-10 mM), do not depolarize the membrane to any significant extent, but they competitively inhibit the L-proline transport signal. This indicates that these analogs are nontransported inhibitors of the imino carrier. The poor inhibitors niacin and pipolinic acid (Ki greater than 60 mM) depolarize the membrane about twice as much as proline and with low Kf values. This suggests separate carriers for these substrates.     

Kinetic properties of the Na+/H+ antiport of heart mitochondria

The fluorescence of 2',7'-bis(carboxyethyl)-5(6)-carboxyfluorescein (BCECF) has been used to follow the Na+/H+ antiport activity of isolated heart mitochondria as a Na+-dependent extrusion of matrix H+. The antiport activity measured in this way shows a hyperbolic dependence on external Na+ or Li+ concentration when the external pH (pHo) is 7.2 or higher. The apparent Km for Na+ decreases with increasing pHo to a limit of 4.6 mM. The Ki for external H+ as a competitive inhibitor of Na+/H+ antiport averages 3.0 nM (pHo 8.6). The Vmax at 24 degrees C is 160 ng ion of H+ min-1 (mg of protein)-1 and does not vary with pHo. Li+ reacts with the antiporter with higher affinity, but much lower Vmax, and is a competitive inhibitor of Na+/H+ antiport. The rate of Na+/H+ antiport is optimal when the pHi is near 7.2. When pHo is maintained constant, Na+-dependent extrusion of matrix H+ shows a hyperbolic dependence on [H+]i with an apparent Km corresponding to a pHi of 6.8. The Na+/H+ antiport is inhibited by benzamil and by 5-N-substituted amiloride analogues with I50 values in the range from 50 to 100 microM. The pH profile for this inhibition seems consistent with the availability of a matrix binding site for the amiloride analogues. The mitochondrial Na+/H+ antiport resembles the antiport found in the plasma membrane of mammalian cells in that Na+, Li+, and external H+ appear to compete for a common external binding site and both exchanges are inhibited by amiloride analogues.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effect of alkali ions on the active transport of neutral amino acids into Streptomyces hydrogenans.

The active transport of neutral amino acids into Streptomyces hydrogenans is inhibited by external Na+. There is no indication that in these cells amino acid accumulation is driven by an inward gradient of Na+. The extent of transport inhibition by Na+ depends on the nature of the amino acid. It decreases with increasing chain length of the amino acid molecules i.e. with increasing non-polar properties of the side chain. Kinetic studies show that Na+ competes with the amino acid for a binding site at the amino acid carrier. There is a close relation between the Ki values for Na+ and the number of C atoms of the amino acids. Other cations also inhibit neutral amino acid uptake competitively; the effectiveness decreases in the order Li+ greater than Na+ greater than K+ greater than Rb+ greater than Cs+. Anions do not have a significant effect on the uptake of neutral amino acids. After prolonged incubation of the cells with 150 mM Na+, in addition to the competitive inhibition of transport Na+ induces an increase in membrane permeability for amino acids.     

Temperature sensitivity and substrate specificity of two distinct Na+-activated D-glucose transport systems in guinea pig jejunal brush border membrane vesicles

D-Glucose transport was studied with isolated brush border membrane vesicles from guinea pig jejunum. Saturation curves were carried out at either 25 or 35 degrees C in buffers containing Na+, Li+, K+ (100 mM chloride salt), or sorbitol (200 mM). Uncorrected uptake rates were fitted by nonlinear regression analysis to an equation involving one diffusional and two saturable terms. In the presence of Na+ at 35 degrees C, two saturable systems (Km = 0.4 and 24 mM, respectively) were evident, as well as a diffusion component quantitatively identical with that measured with L-glucose in separate experiments. In contrast, at 25 degrees C only one saturable system was apparent (Km = 1.2 mM): the second exhibited diffusion-like kinetics. In the presence of Na+ at 35 degrees C, D-glucose uptake was fully inhibited by both D-glucose and D-galactose, whereas alpha-methylglucoside gave kinetics of partial inhibition. We conclude that in the presence of Na+ there are at least two distinct D-glucose transport systems: 1) System I, a low temperature-sensitive system, fully inhibited by D-glucose, D-galactose, and alpha-methylglucoside; we identify it as the "classical" D-glucose/Na+ cotransport system, insensitive to inhibition by cytochalasin B and obligatorily dependent on Na+; and 2) System II, a high temperature-sensitive system where D-glucose and D-galactose inhibit but alpha-methylglucoside is inert. Its cation specificity is unclear but it appears to be sensitive to cytochalasin B inhibition. When Li+ or K+ substituted for Na+, only one transport system was apparent. The Li+-activated transport was: independent of the incubation temperature; inhibited by D-glucose and D-galactose but not by alpha-methylglucoside, 2-deoxy-D-glucose, D-mannose, and D-xylose; and sensitive to cytochalasin B inhibition. The exact nature of the system (or systems) involved in D-glucose transport in the absence of sodium remains to be established.     

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.     

Energetics of alanine, lysine, and proline transport in cytoplasmic membranes of the polyphosphate-accumulating Acinetobacter johnsonii strain 210A.

Amino acid transport in right-side-out membrane vesicles of Acinetobacter johnsonii 210A was studied. L-Alanine, L-lysine, and L-proline were actively transported when a proton motive force of -76 mV was generated by the oxidation of glucose via the membrane-bound glucose dehydrogenase. Kinetic analysis of amino acid uptake at concentrations of up to 80 microM revealed the presence of a single transport system for each of these amino acids with a Kt of less than 4 microM. The mode of energy coupling to solute uptake was analyzed by imposition of artificial ion diffusion gradients. The uptake of alanine and lysine was driven by a membrane potential and a transmembrane pH gradient. In contrast, the uptake of proline was driven by a membrane potential and a transmembrane chemical gradient of sodium ions. The mechanistic stoichiometry for the solute and the coupling ion was close to unity for all three amino acids. The Na+ dependence of the proline carrier was studied in greater detail. Membrane potential-driven uptake of proline was stimulated by Na+, with a half-maximal Na+ concentration of 26 microM. At Na+ concentrations above 250 microM, proline uptake was strongly inhibited. Generation of a sodium motive force and maintenance of a low internal Na+ concentration are most likely mediated by a sodium/proton antiporter, the presence of which was suggested by the Na(+)-dependent alkalinization of the intravesicular pH in inside-out membrane vesicles. The results show that both H+ and Na+ can function as coupling ions in amino acid transport in Acinetobacter spp.     

Intracellular acidification-induced alkali metal cation/H+ exchange in human neutrophils

Pretreatment of isolated human neutrophils (resting pHi congruent to 7.25 at pHo 7.40) with 30 mM NH4Cl for 30 min leads to an intracellular acidification (pHi congruen to 6.60) when the NH4Cl prepulse is removed. Thereafter, in 140 mM Na+ medium, pHi recovers exponentially with time (initial rate, approximately 0.12 pH/min) to reach the normal resting pHi by approximately 20 min, a process that is accomplished mainly, if not exclusively, though an exchange of internal H+ for external Na+. This Na+/H+ countertransport is stimulated by external Na+ (Km congruent to 21 mM) and by external Li+ (Km congruent to 14 mM), though the maximal transport rate for Na+ is about twice that for Li+. Both Na+ and Li+ compete as substrates for the same translocation sites on the exchange carrier. Other alkali metal cations, such as K+, Rb+, or Cs+, do not promote pHi recovery, owing to an apparent lack of affinity for the carrier. The exchange system is unaffected by ouabain or furosemide, but can be competitively inhibited by the diuretic amiloride (Ki congruent to 8 microM). The influx of Na+ or Li+ is accompanied by an equivalent counter-reflux of H+, indicating a 1:1 stoichiometry for the exchange reaction, a finding consistent with the lack of voltage sensitivity (i.e., electroneutrality) of pHi recovery. These studies indicate that the predominant mechanism in human neutrophils for pHi regulation after intracellular acidification is an amiloride-sensitive alkali metal cation/H+ exchange that shares a number of important features with similar recovery processes in a variety of other mammalian cell types.     

Defective cation-coupling mutants of Escherichia coli Na+/proline symport carrier. Characterization and localization of mutations

A major proline carrier in Escherichia coli encoded by the putP gene mediates proline/Na+ or Li+ symport. Proline carrier mutants with altered cation specificity were obtained by mutagenesis with nitrous acid in vitro of a plasmid carrying the wild-type putP gene. Two mutant strains harboring plasmid pMOP4135 and pMOP4141 could transport proline efficiently only in the presence of an increased concentration of sodium ion. Mutations of these plasmids, putP4135 and putP4141, caused reduction of affinity for Na+ of proline transport and binding, without remarkable change in the affinity for proline or in production of the carriers. Consistent with the lower affinity of the putP4141 carrier for Na+, the mutant carrier was supersensitive to N-ethylmaleimide inhibition. The pH dependence of proline binding was also changed in these mutant carriers. The lesions of putP4135 and putP4141 were located in the N-terminal part of the putP gene (ClaI-PvuII fragment) by in vitro recombination and subsequent examination of the phenotype of the transformants. DNA sequencing of these fragments revealed one base alteration of G to A at nucleotides 299 and 656 in pMOP4141 and pMOP4135, respectively, which corresponded to amino acid changes from Gly22 to glutamic acid and Cys141 to tyrosine, respectively.     

Identification of histidyl and thiol groups at the active site of rabbit renal dipeptide transporter

Active transport of dipeptides in rabbit renal brush-border membrane vesicles is energized by an inward-directed H+ gradient rather than a Na+ gradient. We examined the effects of treatment of membrane vesicles with diethylpyrocarbonate (DEP), a reagent specific for histidyl groups, on this H+ gradient-dependent dipeptide uptake. DEP inhibited the uptake of all three dipeptides studied, Gly-sarcosine, Gly-Gly, and Gly-Pro (Ki = 0.6-0.9 mM), and the inhibition was noncompetitive. The dipeptide transporter could be protected from DEP inhibition by the presence of dipeptide substrates during the treatment of the vesicles with the inhibitor, whereas leucine plus Na+ failed to offer the protection. Na+-dependent leucine uptake was also inhibited by DEP (Ki = 2.5 mM) and the amino acid transporter could be protected from the inhibition by leucine plus Na+, but not by dipeptides. Treatment of membrane vesicles with the thiol group-specific reagents, 7-chloro-4-nitrobenz-2-oxa-1,3-diazole,3-bromopyruvate, p-chloromercuribenzenesulfonic acid, and N-ethylmaleimide, also inhibited the H+ gradient-dependent dipeptide uptake. The potency of their inhibition was in the order: 7-chloro-4-nitrobenz-2-oxa-1,3-diazol greater than p-chloromercuribenzenesulfonic acid greater than 3-bromopyruvate greater than N-ethylmaleimide. The inhibition could be reversed in some cases by treatment of the membrane vesicles with reducing agents such as 2,3-dimercaptopropanol following incubation with the inhibitors. Dipeptide substrates could protect the dipeptide transporter from the inhibition. We conclude that histidyl and thiol groups are present at or near the substrate-binding site of the rabbit renal dipeptide transporter.     

Passive transport of Rb+ by hog gastric (H+,K+)-ATPase

Gastric vesicles enriched in (H+,K+)-ATPase were prepared from hog fundic mucosa and studied for their ability to transport K+ using 86Rb+ as tracer. In the absence of ATP, the vesicles elicited a rapid uptake of 86Rb+ (t 1/2 = 45 +/- 9 s at 30 degrees C) which accounted for both transport and binding. Transport was osmotically sensitive and was the fastest phase. It was not limited by anion permeability (C1- was equivalent to SO2-4) but rather by availability of either H+ or K+ as intravesicular countercation suggesting a Rb+-K+ or a Rb+-H+ exchange. Selectivity was K+ greater than Rb+ greater than Cs+ much greater than Na+,Li+. The capacity of vesicles which catalyzed the fast transport of K+ was 83 +/- 4% of maximal vesicular capacity of the fraction. Addition of ATP decreased both rate and extent of 86Rb+ uptake (by 62 and 43%, respectively with 1 mM ATP) with an apparent Ki of 30 microM. Such an effect was not seen on 22Na+ transport. ATP inhibition of transport did not require the presence of Mg2+, and inhibition was also produced by ADP even in the presence of myokinase inhibitor. On the other hand, 86Rb+ uptake was as strongly inhibited by 200 microM vanadate in the presence of Mg2+. Efflux studies suggested that ATP inhibition was originally due to a decrease of vesicular influx with little or no modification of efflux. Since ATP, ADP, and vanadate are known modulators of the (H+,K+)-ATPase, we propose that, in the absence of ATP, (H+,K+)-ATPase passively exchanges K+ for K+ or H+ and that ATP, ADP, and vanadate regulate this exchange.     

Characteristics of proline transport into R3230AC mammary tumor cells

Cells separated by enzyme treatment of the R3230AC mammary carcinoma were used to characterize the entry of proline. These cells showed minimal changes in cell viability and intracellular volume and were found to be suitable for transport studies, since the vi of proline was maintained for at least 4 h when cells were stored at 37 or 4 degrees C, or when transport was measured in the presence or absence of Na+. Proline was acitvely transported by these tumor cells, reaching a distribution ratio ([proline] intracellular/[proline] extracellular) of 20 after 2 h. Proline entry consisted of two processes, one saturable (carrier mediated) and the other, non-saturable. The carrier-mediated entry, Km - 0.83 mM and V = 151.10(-5) mumol/min per 5.10(6) cells, was Na+-dependent, sensitive to pH and metabolic inhibitors, and completely inhibited by alpha-(methylamino)-isobutyric acid (Ki = 0.34 mM). Proline entry in the absence of Na+ was 20% that in the presence of Na+ and was found to be due to a non-saturable process, since (a) vi of proline uptake in the absence of Na+ increases linearly with increasing proline concentration and (b) was not suppressed by either 20 mM alpha-(methyl-amino)-isobutyric acid, 50 mM glycine +20 mM phenylalanine, or 50 mM serine +20 mM phenylalanine when proline uptake was measured in the presence or absence of Na+. Therefore, under the conditions studied, we conclude that proline transport appears to be restricted to the A (alanine-preferring) system. Furthermore, these cells should provide a suitable model to study the effect of hormonal manipulations on the amino acid transport process.     

Role of lithium ions in proline transport in Escherichia coli.

Mechanisms of Li+ stimulation of proline transport were studied in cells of Escherichia coli 7 and NR70, a mutant of strain 7 lacking adenosine triphosphatase (EC 3.6.1.3). An electrochemical potential difference of Li+ induced in an inward direction of energy-depleted cells caused a transient uptake of proline depending on the driving force provided. When proline was added to unbuffered cell suspensions under anaerobic conditions, the medium was found to be acidified only in the presence of Li+ but not in the presence of Na+ or K+. This acidification was abolished by the addition of a permeant anion, SCN-, to the medium containing Li+, but this was not demonstrated with cells of a mutant strain deficient in a carrier protein specific for proline. These results support the assumption that proline is taken up by a mechanism of Li+-proline cotransport in E. coli.