Role of proton dissociation in the transport of acidic amino acids by the Ehrlich ascites tumor cells

The pH profile for the uptake of l-glutamic acid by the Ehrlich ascites tumor cell arises largely as a sum of the decline with falling pH of a slow, Na⁺-dependent uptake by System A, and an increasing uptake by Na⁺-independent System L. The latter maximizes at about pH 4.5, following approximately the titration curve of the distal carboxyl group. This shift in route of uptake was verified by (a) a declining Na⁺-dependent component. (b) an almost corresponding decline in the 2-(methylamino)-isobutyric acid-inhibitable component, (c) a rising component inhibited by 2-aminonorbornane-2-carboxylic acid. Other amino acids recognized as principally reactive with Systems A or L yielded corresponding inhibitory effects with some conspicuous exceptions: 2-Aminoisobutyric acid and even glycine become better substrates of System L as the pH is lowered; hence their inhibitory action on glutamic acid uptake is not lost. The above results were characterized by generally consistent relations among the half-saturation concentrations of the interacting amino acids with respect to: their own uptake, their inhibition of the uptake, one by another, and their trans stimulation of exodus, one by another.A small Na⁺-dependent component of uptake retained by l-glutamic acid but not by d-glutamic acid at pH 4.5 is inhibitable by methionine but by neither 2-(methylamino)-isobutyric acid nor the norbornane amino acid. We provisionally identified this component with System ASC, which transports l-glutamine throughout the pH range studied. No transport activity specific to the anionic amino acids was detected, and the unequivocally anionic cysteic acid showed neither significant mediated uptake nor inhibition of the uptake of glutamic acid or of the norbornane amino acid.     

Energization of amino acid transport in energy-depleted Ehrlich cells and plasma membrane vesicles

We redirect attention to contributions to the energization of the active transport of amino acids in the Ehrlich cell, beyond the known energization by down-gradient comigration of Na⁺, beyond possible direct energization by coupling to ATP breakdown, and beyond known energization by exchange with prior accumulations of amino acids. We re-emphasize the uphill operation of System L, and by prior depletion of cellular amino acids show that this system must receive energy beyond that made available by their coupled exodus. After this depletion the Na⁺-independent accumulation of the norbornane amino acid, 2-aminobicycloheptane-2-carboxylic acid becomes strongly subject to stimulation by incubation with glucose. Energy transfer between Systems A and L through the mutual substrate action of ordinary amino acids was minimized although not entirely avoided by the use of amino acid analogs specific to each system.When 2,4-dinitrophenol was included in the depleting treatment, and pyruvate, phenazine methosulfate, or glucose used for restoration, recovery of uptake of the norbornane amino acid was independent of external Na⁺ or K⁺ levels. Restoration of the uptake of 2-(methylamino)isobutyric acid was, however, decreased by omission of external K⁺. Contrary to an earlier finding, restoration of uptake of each of these amino acids was associated with distinct and usually correlated rises in cellular ATP levels. ATP addition failed to stimulate exodus of the norbornane amino acid from plasma membrane vesicles, although either NADH or phenazine methosulfate did stimulate exodus. ATP production and use is thus associated with transport energization, although evidence for a direct role failed to appear.     

Cysteine as a system-specific substrate for transport system ASC in rat hepatocytes.

The rapid transport of $\text{L}$-cysteine into isolated rat hepatocytes escapes detectable inhibition by 2-(methylamino)-isobutyric acid at levels up to 50 mM. The system transporting cysteine instead is convincingly similar to the $\text{ASC}$ system described for the Ehrlich cell in structural and steric specificity and in pH sensitivity. The Na⁺-dependent uptake of 2-aminoisobutyric acid is almost evenly divided between Systems $\text{A}$ and $\text{ASC}$, showing better accommodation of its two α-methyl groups by $\text{ASC}$ than in the Ehrlich cell. The hepatocyte $\text{ASC}$ system tolerates Li⁺-for-Na⁺ substitution better than does System $\text{A}$, although the tolerance depends on amino acid structure. Adaptive regulation and insulin and glucagon stimulation were not seen under conditions producing these effects for System $\text{A}$.     

Partial Purification of Amino Acid Transport Systems in Ehrlich Ascites Tumor Cell Plasma Membranes

Ehrlich ascites tumor cell plasma membranes were subjected to sequential selective protein extraction to identify protein components associated with amino acid transport. These membranes were extracted with Triton X-100 followed by 2,3-dimethylmaleic anhydride. Approximately 80% of the membrane proteins were extracted by these procedures while the original lipids were largely retained (～70%). The quantity of carbohydrate per milligram protein in the residue increased on extraction, consistent with an enrichment of glycoprotein in the residue.

The residual vesicles display the characteristic properties of Na⁺-coupled amino acid transport. These properties include Na⁺-stimulated uptake and Na⁺-gradient-stimulated uptake leading to an accumulation of the solute against its chemical gradient as well as inhibition of uptake by a competitive amino acid, L-methionine. The extracted vesicles exhibit a peak level of α-aminoisobutyrate uptake six times greater than that expected from equilibration of α-aminoisobutyrate. This accumulation is greater than that obtained with native vesicles, albeit slower. The accelerated exchange diffusion of L-leucine is not measurable in the residual vesicles after dimethylmaleic acid anhydride treatment, although it can be measured after Triton extraction. These results are consistent with the conclusion that the amino acid transport systems “A” (Na⁺-coupled) and “L” (Na⁺-independent) in Ehrlich cells, though having overlapping specificities for amino acids, and distinct physical entities.     

Characterization of system L and system y+ amino acid transport activity in cultured vascular smooth muscle cells

The uptake of L-leucine and L-lysine into vascular smooth muscle cells cultured from the aortas of rats has been investigated. Both amino acids are taken up by saturable systems that are independent of the presence of a ^·Na⁺ gradient and can be stimulated in trans by neutral bulky amino acids for leucine and cationic amino acids for lysine. Leucine uptake is inhibited competitively in cis by several neutral amino acids, whereas lysine uptake is inhibited strongly by other cationic amino acids but also significantly by neutral amino acids such as leucine. The leucine inhibition is noncompetitive. Cells preloaded with leucine and lysine could also export these amino acids and the rate of efflux was stimulated by the presence of appropriate amino acids in trans. These data are all consistent with leucine being transported largely if not entirely by System L and lysine by the System y⁺ transporter. © 1993 Wiley-Liss, Inc.     

Workshop 7: 2

Glutamine, the preferred precursor for neurotransmitter glutamate, is likely to be the principal substrate for the neuronal System A transporter SAT1 in vivo. By measuring currents associated with SAT1 expression in Xenopus oocytes, we found that SAT1 mediates transport of small, neutral, aliphatic amino acids including glutamine, alanine and the System A‐specific analogue 2‐(methylamino) isobutyrate, each with K_0.5 of 0.3–0.5 mm . Amino acid transport is driven by the Na⁺ electrochemical gradient. Kinetic data indicates that Na⁺/cotransport comprises the ordered binding first of Na⁺ (a voltage‐dependent step), then alanine, then simultaneous translocation. Li⁺ (but not H⁺) can substitute for Na⁺ but results in reduced V_max. In the absence of amino acid, SAT1 mediates a cation leak with selectivity Na⁺, Li⁺, H⁺, K⁺. The temperature‐dependence of the leak current (E_a = 17 ± 3 kcal/mol) is consistent with carrier‐mediated Na⁺ uniport activity (cf 13 ± 2 kcal/mol for Na⁺/alanine cotransport) but the leak does not saturate at physiological [Na⁺], suggesting channel activity. Despite a Na⁺ Hill coefficient of 1, we obtained Na⁺/amino acid coupling coefficients greater than 1 from simultaneous measurement of charge and [³H]alanine or [³H]glutamine uptake. Interpretation of these data is model‐dependent and consistent with either (1) an all‐carrier model in which Na⁺/amino acid cotransport is thermodynamically coupled 2 : 1, cotransport is preferred over Na⁺ uniport, and in which there is little cooperativity between Na⁺ binding events, or (2) 1 : 1 coupling in parallel with an always‐on Na⁺ channel activity. In either scenario, the presence of SAT1 at the plasma membrane and resultant Na⁺ fluxes will place a significant energy burden on the cell.     

Na+(Li+)/Branched-chain amino acid cotransport inPseudomonas aeruginosa

Summary A transport system for branched-chain amino acids (designated as LIV-II system) inPseudomonas aeruginosa requires Na⁺ for its operation. Coupling cation for this system was identified by measuring cation movement during substrate entry using cation-selective electrodes. Uptakes of Na⁺ and Li^– were induced by the imposition of an inwardly-directed concentration gradient of leucine, isoleucine, or valine. No uptake of H^– was found, however, under the same conditions. In addition, effects of Na⁺ and Li⁺ on the kinetic property of the system were examined. At chloride salt concentration of 2.5mm, values of apparentK _m andV _max for leucine uptake were larger in the presence of Na⁺ than Li⁺. These results indicate that the LIV-II transport system is a Na⁺(Li⁺)/substrate cotransport system, although effects of Na⁺ and Li⁺ on kinetics of the system are different.     

Mammalian Amino Acid Transport System y+ Revisited: Specificity and Cation Dependence of the Interaction with Neutral Amino Acids

A reevaluation of the specificity of system y⁺, the classical transporter for cationic amino acids is presented. System y⁺ has been defined as a transporter for cationic amino acids that binds neutral amino acids with lower affinity in the presence of Na⁺. The discovery of other transporters for cationic amino has suggested that some properties, originally attributed to system y⁺, may relate to other transport systems. Uncertainty concerns mainly, the affinity for neutral amino acids and the cation dependence of this interaction. Neutral amino acids (13 analogues tested) were found to bind to system y⁺ in human erythrocytes with very low affinity. Inhibition constants (K_iy, mm) ranged between 14.2 mm and >400 mm, and the strength of interaction was similar in the presence of Na⁺, K⁺ or Li⁺ (145 mm). In choline medium, no interaction was detected up to 20 mm of the neutral amino acid. Guanidinium ion (5 mm, osmolarity maintained with choline) potentiated neutral amino acid binding; the effect was most important in the case of l-norvaline which aligned with guanidinium ion is equivalent to arginine. This suggests cooperative interaction at the substrate site. The specificity of system y⁺ was shown to be clearly distinct from that of system y⁺L, a cationic amino acid transporter that accepts neutral amino acids with high affinity in the presence of Na⁺ and which influenced the classical definition of system y⁺. Received: 28 September 1998/Revised: 21 December 1998     

Na+-dependent transport of glycine in renal brush border membrane vesicles: Evidence for a single specific transport system

The uptake of glycine in rabbit renal brush border membrane vesicles was shown to consist of glycine transport into an intravesicular space. An Na⁺ electrochemical gradient (extravesicular>intravesicular) stimulated the initial rate of glycine uptake and effected a transient accumulation of intravesicular glycine above the steady-state value. This stimulation could not be induced by the imposition of a K⁺, Li⁺ or choline⁺ gradient and was enhanced as extravesicular Na⁺ was increased from 10 mM to 100 mM. Dissipation of the Na⁺ gradient by the ionophore gramicidin D resulted in diminished Na⁺-stimulated glycine uptake. Na⁺-stimulated uptake of glycine was electrogenic. Substrate-velocity analysis of Na⁺-dependent glycine uptake over the range of amino acid concentrations from 25 μM to 10 mM demonstrated a single saturable transport system with apparent K_m = 996 μM and V_max = 348 pmol glycine/mg protein per min. Inhibition observed when the Na⁺-dependent uptake of 25 μM glycine was inhibited by 5 mM extravesicular test amino acid segregated dibasic amino acids, which did not inhibit glycine uptake, from all other amino acid groups. The amino acids d-alanine, d-glutamic acid, and d-proline inhibited similarly to their l counterparts. Accelerative exchange of extravesicular [³H]glycine was demonstrated when brush border vesicles were preloaded with glycine, but not when they were preloaded with l-alanine, l-glutamic acid, or with l-proline. It is concluded that a single transport system exists at the level of the rabbit renal brush border membrane that functions to reabsorb glycine independently from other groups of amino acids.     

The Binding Specificity of Amino Acid Transport System y+L in Human Erythrocytes is Altered by Monovalent Cations

System y⁺L is a broad-scope amino acid transporter which binds and translocates cationic and neutral amino acids. Na⁺ replacement with K⁺ does not affect lysine transport, but markedly decreases the affinity of the transporter for l-leucine and l-glutamine. This observation suggests that the specificity of system y⁺L varies depending on the ionic composition of the medium. Here we have studied the interaction of the carrier with various amino acids in the presence of Na⁺, K⁺, Li⁺ and guanidinium ion. In agreement with the prediction, the specificity of system y⁺L was altered by the monovalent cations. In the presence of Na⁺, l-leucine was the neutral amino acid that interacted more powerfully. Elongation of the side chain (glycine - l-norleucine) strengthened binding. In contrast, bulkiness at the level of the β carbon was detrimental. In K⁺, the carrier behaved as a cationic amino acid specific carrier, interacting weakly with neutral amino acids. Li⁺ was found to potentiate neutral amino acid binding and in general the apparent affinities were higher than in Na⁺; elongation of the nonpolar side chain made a more important contribution to binding and the carrier was more tolerant towards β carbon substitution. Guanidinium stimulated the interaction of the carrier with neutral amino acids, but the effect was restricted to certain analogues (e.g., l-leucine, l-glutamine, l-methionine). Thus, in the presence of guanidinium, the carrier discriminates sharply among different neutral amino acids. The results suggest that the monovalent cations stabilize different carrier conformations. Received: 22 January 1996/Revised: 26 April 1996     

Lithium ion uptake associated with the stimulation of action potential ionophores of cultured human neuroblastoma cells

Cultured human neuroblastoma cell lines were tested for the action potential sodium ionophore utilizing the Li⁺ ion rather than the ²²Na⁺ ion. The cell lines studied included CHP-134, CHP-100, CHP-126, CHP-212 and LA-N-1. Veratridine-dependent uptake of Li⁺ and ²²Na⁺ and its inhibition by tetrodotoxin implies the presence of the action-potential sodium ionophore. CHP-165, and undifferentiated tumor and RAJI a lymphoblast had no veratridine-dependent Li⁺ uptake. Thus, veratridine-dependent Li⁺ uptake provides a convenient means of assaying human neural cells for the action-potential sodium ionophore without the use of the radioactive Na⁺ ion.     

Regulation of the electrogenic (Na+ + K+)-pump of Ehrlich cells by intracellular cation levels

Ehrlich cells actively accumulate neutral amino acids even if both the Na⁺ and K⁺ gradients are inverted. The seeming contradiction of this observation to the gradient hypothesis is, however, explained by the presence of a powerful electrogenic Na⁺ pump, which stongly raises the electrochemical potential gradient of Na⁺ under these conditions. Since the evidence of this pump has so far been found only during abnormal concentrations of alkali ions (low K⁺, high Na⁺) in these cells, the question arises whether the pump is equally powerful with completely normal cells, when the pump is not ‘needed’ for amino acid transport. Using the initial rate of uptake of the test amino acid (2-aminoisobutyrate) as a sensitive monitor of the electrical potential at constant cation distribution between cell and medium, a procedure has been devised to split the overall electrical potential into the diffusional and the pump component. With this procedure it could be shown that the electrogenic pump per se is most powerful in K⁺-depleted and Na⁺-rich cells but declines to a lower ‘resting’ value according as the electrolyte content of the cell approaches normality. A strong positive correlation between cellular Na⁺ content and the electrogenic pumping activity suggests that the intracellular activity of this ion regulates the rate of the electrogenic pump. The low activity of the pump under normal conditions may explain why the existance of this pump has rarely come to attention previously.     

Amino acid transport systems in animal cells: Interrelations and energization

After summarizing the discrimination of the several transport systems of neutral amino acids in the cell of the higher animal, I discuss here the ways in which 2 dissimilar transport systems interact, so that one tends to run forward for net entry and the other backwards for net exodus. An evaluation of the proposals for energization shows that uphill transport continues when neither alkali-ion gradients nor ATP levels are favorable. Evidence is presented that under these conditions a major contribution is made by another mode of energization, which may depend on the fueling of an oxidoreductase in the plasma membrane. This fueling may involve the export by the mitochondrion of the reducing equivalents of NADH by one of the known shuttles, e.g., the malate-aspartate shuttle. After depletion of the energy reseves in the Ehrilich cell by treating it with dinitrophenol plus iodoacetate concentrative uptake of test amino acids is restoration by pyruvate but in poor correlation with the restoration of alkali-ion gradients and ATP levels. This restoration by pyruvate but not by glucose is highly senstitive to rotenone. A combination of phenazine methosulfate and ascorbate will also produce transport restoration, before either the alkali-ion gradients or ATP levels have begun to rise. The restoration of transport applies to a model amino acid entering by the Na⁺-independent system, as well as to one entering by the principal Na⁺-dependent system, restoration being blocked by ouabain, despite the weak effect of ouabain on the alkali-ion gradients in the Ehrlich cell. Quinacrine terminates very quickly the uptake of model amino acids, before the alkali-ion gradients have begun to fall and before the ATP level has been halved. Quinacrine is also effective in blocking restoration of uphill transport by either pyruvate or the phenazine reagent. Preliminary results show that vesicles prepared from the plasma membrane of the Ehrlich cell quickly reduce cytochrome c or ferricyanide in the presence of NADH, and that the distribution of a test amino acid between the vesicle and its environment is influenced by NADH, quinacrine, and an uncoupling agent in ways consistent with the above proposal, assuming that a majority of the vesicles are everted.     

K+- and Na+-gradient-dependent transport of l-phenylalanine by mouse intestinal brush border membrane vesicles

In the presence of an Na⁺- or a K⁺-gradient ($\text{outside > inside}$), l-phenylalanine uptake exhibited an overshoot phenomenon indicating active transport. The amplitudes of the overshoots were increased by increasing either Na⁺ or K⁺ concentrations in the incubation media, indicating that binding alone cannot account for the K⁺ effect. The K⁺-induced overshoot is not due to the presence of a membrane potential alone, as a gradient of choline chloride failed to produce it. Li⁺ could also substitute for Na⁺ though less potent than Na⁺ in inducing an overshoot. Uptake of l-leucine also showed Na⁺- and K⁺-effects and l-leucine and l-alanine could inhibit the Na⁺- and K⁺-overshoots obtained with phenylalanine. These results lead us to postulate the presence of a carrier for neutral amino acids dependent on monovalent cation with higher affinity for Na⁺ in mouse intestine. The Na⁺- and K⁺-driven active transport of l-phenylalanine were shown to be dependent on the presence of a membrane potential, as short-circuiting the membrane with FCCP reduced the amplitude of the overshoots seen with both ions. However, substitution of Cl^? by more lipophilic anions (NO₃^?, SCN^?) produced an inhibition of uptake. A preliminary analysis of the interrelations between Na⁺ and K⁺ for l-phenylalanine uptake showed complex interactions which can be best explained by mutual competition for a common carrier at both sides of the membrane. These results suggest the presence of a new transport system or a variant of an ASC-type system for l-phenylalanine (and neutral amino acids) in the mouse intestine. However, our studies do not rule out the possible involvement of more than one system for neutral amino acid uptake.     

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 $\text{K}{}_{\mathrm{<mtext>i</mtext>}}$ 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 $\text{Li}{}^{\mathrm{+}}\text{> Na}{}^{\mathrm{+}}\text{> K}{}^{\mathrm{+}}\text{> Rb}{}^{\mathrm{+}}\text{> Cs}{}^{\mathrm{+}}$. 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.     

Isolation of plasma membranes from Ehrlich ascites tumor cells Influence of amino acids on (Na + K)-ATPase and K-stimulated phosphatase

A method was developed for isolating plasma membranes from Ehrlich ascites tumor cells. The plasma membranes appeared as highly irregular shrunken sacs or ghosts. Enzymatic characterization of the plasma membranes showed them to be high in (Na⁺ + K⁺-ATPase activity and K⁺-stimulated phosphatase activity. A detailed study showed that both of these latter enzymic functions were stimulated by various amino acids. Such stimulation occurred in the 1–15 mM range of amino acids and was most effective for aromatic species, e.g. phenylalanine and histidine. The amino acid stimulation, which appeared to show little or no stereospecificity, was eliminated by a one carbon separation of NH₂ and COOH groups. Since the metal chelating agent EDTA was also effective in mimicking the stimulation by amino acids, and since a mild washing procedure did not render membranes insensitive to subsequent amino acid or EDTA stimulation, it is proposed that the operation of the (Na⁺ + K⁺)-ATPase (and K⁺-stimulated phosphatase) is to some extent controlled by a tightly bound metal. The possible physiological function of an amino acid-regulated transport ATPase is discussed.     

The Na+ gradient hypothesis in cytoplasts derived from Ehrlich ascites tumor cells

The concentration gradients of Na⁺ and the non-metabolizable amino acid, α-aminoisobutyric acid, and the membrane potential were measured in cytoplasts derived from Ehrlich ascites tumor cells in order to test the Na⁺ gradient hypothesis for the active transport of neutral amino acids in animal cells. According to this hypothesis, the Na⁺ electrochemical gradient and the amino acid activity gradient should be equal at the steady state. It has been difficult to measure the Na⁺ electrochemical gradient in intact Ehrlich cells because Na⁺ may be sequestered in the nuclei of these cells. This problem is avoided with cytoplasts derived from Ehrlich cells because they do not contain internal compartments where Na⁺ could be sequestered. Since these cytoplasts also maintain steady state concentrations of Na⁺, K⁺, and α-aminoisobutyric acid similar to those found in whole Ehrlich cells, they are uniquely suited for testing the Na⁺ gradient hypothesis. Assuming the activity coefficients of external and cytoplasmic Na⁺ are equal, the energy in the Na⁺ electrochemical gradient of cytoplasts was 90% of that in the α-aminoisobutyric acid concentration gradient at the steady state. If the Na⁺ gradient hypothesis is correct, the 10% difference between these two gradients cannot be explained in terms of the sequestration of Na⁺ in the nucleus because cytoplasts do not contain internal compartments.     

Amino acid stimulation of ATP cleavage by two Ehrlich cell membrane preparations in the presence of ouabain

Two membrane fractions prepared from the Ehrlich ascites-tumor cell show non-identical stimulatory responses to certain amino acids in their Mg²⁺-dependent activity to cleave ATP, despite the presence of ouabain and the absence of Na⁺ or K⁺. The first of these, previously described, shows little ($\text{Na}{}^{\mathrm{+}}\text{+ K}{}^{\mathrm{+}}$)-ATPase activity, and is characteristically stimulated by the presence of certain diamino acids with low $\text{pK}{}_2$, and at pH values suggesting that the cationic forms of these amino acids are effective. The evidence indicates that these effects are not obtained through occupation of the kinetically discernible receptor site serving characteristically for the uphill transport of these amino acids into the Ehrlich cell. The second membrane preparation was purified with the goal of concentrating the ($\text{Na}{}^{\mathrm{+}}\text{+ K}{}^{\mathrm{+}}$)-ATPase activity. It also is stimulated by the model diamino acid, 4-amino-1-methylpiperidine-4-carboxylic acid, and several ordinary amino acids. The diamino acids were most effective at pH values where the neutral zwitterionic forms might be responsible. Among the optically active amino acids tested, the effects of ornithine and leucine were substantially stronger for the l than for d isomers. The list of stimulatory amino acids again corresponds poorly to any single transport system, although the possibility was not excluded that stimulation might occur for both preparations by occupation of a membrane site which ordinarily is kinetically silent in the transport sequence. The high sensitivity to deoxycholate and to dicyclohexylcarbodiimide of the hydrolytic activity produced by the presence of l-ornithine and 4-amino-1-methyl-piperidine-4-carboxylic acid suggests that the stimulatory effect is not merely a general intensification of the background Mg⁺-dependent hydrolytic activity.     

The Relation between Membrane Potential and the Transport Activity of Systems a and L in Plasma Membrane Vesicles of the Ehrlich Cell

Plasma membrane vesicles isolated from Ehrlich ascites tumor cells have been used to investigate the role of the transmembrane potential in the energetics of Systems A and L. As expected, Na⁺-dependent System A was responsive to changes in membrane potential. System L activity, as measured by transport of 2-aminonorbornane-2-carboxylic acid (BCH), was shown to be Na⁺-independent and was not altered by changes in the membrane potential. The combination of valinomycin and nigericin decreased accumulation of MeAIB but not that of BCH. The presence of nigericin alone caused a significant decrease in uptake by System A and a decrease in uptake by System L to a lesser degree. The inhibitory action of nigericin might reflect its ability to dissipate the Na⁺ gradient rather than an effect on K⁺ or H⁺ flows. The results indicate that modes of energization not produced through the transmembrane potential must account for any uphill operation of System L.     

Li/Na exchange and Li active transport in human lymphoid cells U937 cultured in lithium media

Lithium transport across the cell membrane is interesting in the light of general cell physiology and because of its alteration during numerous human diseases. The mechanism of Li⁺ transfer has been studied mainly in erythrocytes with a slow kinetics of ion exchange and therefore under the unbalanced ion distribution. Proliferating cultured cells with a rapid ion exchange have not been used practically in study of Li⁺ transport. In the present paper, the kinetics of Li⁺ uptake and exit, as well as its balanced distribution across the plasma membrane of U937 cells, were studied at minimal external Li⁺ concentrations and after the whole replacement of external Na⁺ for Li⁺. It is found that a balanced Li⁺ distribution attained at a high rate similar to that for Na⁺ and Cl^? and that Li⁺/Na⁺ discrimination under balanced ion distribution at 1–10 mM external Li⁺ stays on 3 and drops to 1 following Na, K-ATPase pump blocking by ouabain. About 80% of the total Li⁺ flux across the plasma membrane under the balanced Li⁺ distribution at 5 mM external Li⁺ accounts for the equivalent Li⁺/Li⁺ exchange. The majority of the Li⁺ flux into the cell down the electrochemical gradient is a flux through channels and its small part may account for the NC and NKCC cotransport influxes. The downhill Li⁺ influxes are balanced by the uphill Li⁺ efflux involved in Li⁺/Na⁺ exchange. The Na⁺ flux involved in the countertransport with the Li⁺ accounts for about 0.5% of the total Na⁺ flux across the plasma membrane. The study of Li⁺ transport is an important approach to understanding the mechanism of the equivalent Li⁺/Li⁺/Na⁺/Na⁺ exchange, because no blockers of this mode of ion transfer are known and it cannot be revealed by electrophysiological methods. Cells cultured in the medium where Na⁺ is replaced for Li⁺ are recommended as an object for studying cells without the Na,K-ATPase pump and with very low intracellular Na⁺ and K⁺ concentration.