Intracellular mitochondrial membrane potential as an indicator of hepatocyte energy metabolism: Further evidence for thermodynamic control of metabolism

The lipophilic triphenylmethylphosphonium cation (TPMP⁺) has been employed to measure ΔΨ_m, the electrical potential across the inner membrane of the mitochondria of intact hepatocytes. The present studies have examined the validity of this technique in hepatocytes exposed to graded concentrations of inhibitors of mitochondrial energy transduction. Under these conditions, TPMP⁺ uptake allows a reliable measure of ΔΨ_m in intracellular mitochondria, provided that the ratio [TPMP⁺]_i/[TPMP⁺]_e is greater than 50:1 and that at the end of the incubation more than 80% of the hepatocytes exclude Trypan blue. Hepatocytes, staining with Trypan blue, incubated in the presence of Ca²⁺, do not concentrate TPMP⁺. The relationships between ΔΨ_m and two other indicators of cellular energy state, ΔG_Pc and E_h, or between ΔΨ_m and J₀, were examined in hepatocytes from fasted rats by titration with graded concentrations of inhibitors of mitochondrial energy transduction. Linear relationships were generally observed between ΔΨ_m and ΔG_Pc, E_h or J₀ over the ΔΨ_m range of 120−160 mV, except in the presence of carboxyatractyloside or oligomycin, where ΔΨ_m remained constant. Both the magnitude and the direction of the slope of the observed relationships depended upon the nature of the inhibitor. Hepatocytes from fasted rats synthesized glucose from lactate or fructose, and urea from ammonia, at rates which were generally linear functions of the magnitude of ΔΨ_m, except in the presence of oligomycin or carboxyatractyloside. Linear relationships were also observed between ΔΨ_m and the rate of formation of lactate in cells incubated with fructose and in hepatocytes from fed rats. The linear property of these force-flow relationships is taken as evidence for the operation of thermodynamic regulatory mechanisms within hepatocytes.     

Non-ohmic proton conductance of the mitochondrial inner membrane in hepatocytes

The mitochondrial membrane potential in isolated hepatocytes was measured using the distribution of the lipophilic cation triphenylmethylphosphonium (TPMP+) with appropriate corrections for plasma membrane potential, cytoplasmic and mitochondrial binding of TPMP+, and other factors. The relationship between mitochondrial membrane potential and respiration rate in hepatocytes was examined as the respiratory chain was titrated with myxothiazol in the presence of oligomycin. This relationship was nonproportional and similar to results with isolated mitochondria respiring on succinate. This shows that there is an increased proton conductance of the mitochondrial inner membrane in situ at high values of membrane potential. From the respiration rate and mitochondrial membrane potential of hepatocytes in the absence of oligomycin, we estimate that the passive proton permeability of the mitochondrial inner membrane accounts for 20-40% of the basal respiration rate of hepatocytes. The relationship between log[TPMP+]tot/[TPMP+]e and respiration rate in thymocytes was also nonproportional suggesting that the phenomenon is not peculiar to hepatocytes. There is less mitochondrial proton leak in hepatocytes from hypothyroid rats. A large proportion of the difference in basal respiration rate between hepatocytes from normal and hypothyroid rats can be accounted for by differences in the proton permeability characteristics of the mitochondrial inner membrane.     

Unique relationships between the rates of oxidation and phosphorylation and the protonmotive force in rat-liver mitochondria

The rate of ATP synthesis (JP) in isolated rat-liver mitochondria was strongly dependent on the magnitude of the protonmotive force (delta mu H+) across the mitochondrial inner membrane. Addition of different concentrations of various uncouplers or malonate to mitochondrial incubations in State 3 led to a depression of delta mu H+ and a concomitant decrease in JP. A unique relationship between JP and delta mu H+ was obtained, which was independent of the way in which delta mu H+ was varied. This unique relationship was observed when K+ (in the presence of valinomycin) was used as a probe for delta psi. Different relationships between JP and delta mu H+ were observed when K+ was used as a probe for delta psi and when K+ was measured after separation of the mitochondria by centrifugation without silicone oil. This led to a serious underestimation of delta psi, specifically when uncouplers were present, and non-unique flow-force relationships were thus obtained. Anomalous relationships between JP and delta mu H+ were also found when TPMP+ was used as a probe for delta psi. However, in uncoupler incubations the presence of TBP- strongly affected the TPMP+ accumulation ratio without any effect on the K+ accumulation or on JP and in the presence of TBP- unique relationships between JP and delta mu H+ were again obtained. This indicates that the accumulation of TPMP+ inside the mitochondria is not a straightforward function of delta psi but also depends on conditions like the presence of TBP- or uncouplers. We conclude that there is a unique relationship between the rate of phosphorylation and the protonmotive force in mitochondria and that under some conditions the behaviour of TPMP+ is anomalous.     

Membrane potential in liposomes measured by the transmembrane distribution of 86Rb+, tetraphenylphosphonium or triphenylmethylphosphonium: effect of cholesterol in the lipid bilayer

Valinomycin-induced potassium diffusion potential (delta psi, inside negative) in the liposomes made of phosphatidylcholine and various amounts of cholesterol was measured by uptake of 86Rb+, tetraphenylphosphonium (TPP+) or triphenylmethylphosphonium (TPMP+). In any liposome, the values of membrane potential obtained by 86Rb+ uptake (delta psi Rb) agreed well with those calculated from the imposed potassium concentration gradient using the Nernst equation, and were not affected by the presence of cholesterol. However, both delta psi TPP and delta psi TPMP showed smaller values than delta psi Rb when the cholesterol content in liposomes increased. delta psi TPMP at a stationary state was much smaller than delta psi TPP. The orientational order parameter of the lipids' bilayer with various cholesterol content was estimated from fluorescence polarization of 1,6-diphenyl-1,3,5-hexatriene. The results indicated that the permeation of TPP+ or TPMP+ into liposomes containing a large amount of cholesterol is strongly restricted by the high ordering of phosphatidylcholine acyl chains.     

Flow-force relationships in mitochondrial oxidative phosphorylation

The rates of oxidation and phosphorylation in isolated rat-liver mitochondria have a steep dependence on the protonmotive force (delta mu H+) across the membrane. These experimentally observed relationships proved to be independent of the way in which delta mu H+ was varied. These results were obtained when the membrane potential (delta psi) was calculated from the distribution of K+ (in the presence of valinomycin). When triphenylmethylphosphonium (TPMP+) was used as a probe for delta psi, slightly different flow-force relationships were obtained. We conclude that unique relationships exist between delta mu H+ and the rates of oxidation and phosphorylation, and that under some conditions the behaviour of the probe TPMP+ is anomalous.     

The mechanism of stimulation of respiration by fatty acids in isolated hepatocytes

Addition of fatty acids to isolated hepatocytes raised respiration rate by 92% and raised mitochondrial membrane potential (delta psi m) in situ from 155 to 162 mV suggesting that the increased fuel supply had a greater effect on respiration rate than any increases in processes that consumed mitochondrial protonmotive force (delta p). The relationship between delta psi m and respiration rate was changed by addition of fatty acids or lactate, showing that there was also stimulation of delta p-consuming reactions. In the presence of oligomycin the relationship between delta psi m and respiration rate was unaffected by substrate addition, showing that the kinetics of delta p consumption by the H+ leak across the mitochondrial inner membrane were unchanged. The stimulation of delta p consumers by fatty acids therefore must be in the pathways of ATP synthesis and turnover. Inhibition of several candidate ATP-consuming reactions had little effect on basal or fatty acid-stimulated respiration, and the nature of the ATP turnover reactions in hepatocytes remains speculative. We conclude that fatty acids (and other substrates) stimulate respiration in hepatocytes in two distinct ways. They provide substrate for the electron transport chain, raising delta p and increasing the non-ohmic proton leak across the mitochondrial inner membrane and the rate of oxygen consumption. They also directly stimulate an unidentified delta p-consuming reaction in the cytoplasm. They do not work by uncoupling or by stimulation of intramitochondrial ATP-turnover reactions.     

Characterization of the plasma and mitochondrial membrane potentials of alveolar type II cells by the use of ionic probes

The lipophilic cation triphenylmethylphosphonium (TPMP+) and the potassium analog Rb+, were used to monitor the membrane potential (delta psi) of freshly isolated rabbit type II alveolar epithelial cells. Type II cells were found to accumulate TPMP+ rapidly at 37 degrees C in Hanks' balanced-salt solution with 5 microM tetraphenyl boron, but this accumulation was partially due to non-membrane potential dependent binding of TPMP+ to the cell. Lysophosphatidylcholine (lysoPC) was found to abolish delta psi and permitted correction for bound TPMP+ or Rb+. TPMP+ remaining in the cell following correction for binding represents the sum of mitochondrial and plasma membrane potential dependent accumulation. The accumulation of Rb+ by the type II cell was found to be independent of the mitochondrial membrane potential and indicated a trans-plasma membrane Rb+ distribution potential of -62.9 +/- 4 mV. A similar value was obtained by estimating the plasma membrane potential dependent accumulation of TPMP+ in type II cells whose mitochondria were depolarized with carbonylcyanide m-chlorophenylhydrazone (CCCP). The release of TPMP+ due to CCCP treatment also permitted an estimation for the trans-mitochondrial membrane potential of -141.8 +/- 10 mV. These techniques of membrane potential measurements were found to be sensitive to changes in delta psi induced by a number of inhibitors and ionophores. The ability to measure the membrane potential of the type II pneumocyte, and the changes caused by various agents, should be useful in characterizing the functional responses of this pulmonary surfactant producing cell.     

Operation and energy dependence of the reducing-equivalent shuttles during lactate metabolism by isolated hepatocytes.

The participation and energy dependence of the malate-aspartate shuttle in transporting reducing equivalents generated from cytoplasmic lactate oxidation was studied in isolated hepatocytes of fasted rats. Both lactate removal and glucose synthesis were inhibited by butylmalonate, aminooxyacetate or cycloserine confirming the involvement of malate and aspartate in the transfer of reducing equivalents from the cytoplasm to mitochondria. In the presence of ammonium ions the inhibition of lactate utilization by butylmalonate was considerably reduced, yet the transfer of reducing equivalents into the mitochondria was unaffected, indicating a substantially lesser role for butylmalonate-sensitive malate transport in reducing-equivalent transfer when ammonium ions were present. Ammonium ions had no stimulatory effect on uptake of sorbitol, a substrate whose oxidation principally involves the alpha-glycerophosphate shuttle. The role of cellular energy status (reflected in the mitochondrial membrane electrical potential (delta psi) and redox state), in lactate oxidation and operation of the malate-aspartate shuttle, was studied using a graded concentration range of valinomycin (0-100 nM). Lactate oxidation was strongly inhibited when delta psi fell from 130 to 105 mV whereas O2 consumption and pyruvate removal were only minimally affected over the valinomycin range, suggesting that the oxidation of lactate to pyruvate is an energy-dependent step of lactate metabolism. Our results confirm that the operation of the malate-aspartate shuttle is energy-dependent, driven by delta psi. In the presence of added ammonium ions the removal of lactate was much less impaired by valinomycin, suggesting an energy-independent utilization of lactate under these conditions. The oxidizing effect of ammonium ions on the mitochondrial matrix apparently alleviates the need for energy input for the transfer of reducing equivalents between the cytoplasm and mitochondria. It is concluded that, in the presence of ammonium ions, the transport of lactate hydrogen to the mitochondria is accomplished by malate transfer that is not linked to the electrogenic transport of glutamate across the inner membrane, and, hence, is clearly distinct from the butylmalonate-sensitive, energy-dependent, malate-aspartate shuttle.     

Alterations in energy status by menadione metabolism in hepatocytes isolated from fasted and fed rats

The biochemical mechanism of cytotoxicity, induced by the quinoid compound 2-methyl 1,4-naphthoquinone (menadione), was investigated in hepatocytes freshly isolated from fasted and fed rats. Hepatocytes from fasted rats were significantly more vulnerable to the toxicity of menadione than hepatocytes from fed rats. Menadione (150 microM) induced a 50% loss of viability of cells (LT50) from fasted rats after 55 min of incubation, whereas a LT50 of 80 min was observed after exposure of hepatocytes from fed rats to menadione. Glutathione and NADPH levels were rapidly depleted by menadione metabolism. This depletion was sustained during the incubation period. No significant differences were found in the time course and extent of the menadione-induced glutathione and NADPH depletion in hepatocytes of both nutritional states. Menadione also affected the energy status of the hepatocytes. The ATP content of cells from fasted rats decreased to 50% (AT50) within 18 min of exposure to menadione, whereas a 50% loss of ATP content of hepatocytes from fed rats was reached at 65 min. In contrast to depletion of glutathione and NADPH, the time course and extent of menadione-induced ATP depletion correlated well with the time of onset and rate of cell killing. Our results suggest that menadione metabolism may interfere with both mitochondrial and glycolytic ATP production. Depletion of ATP might be a critical step in menadione-induced cytotoxicity.     

Cation transport mechanisms in Mycoplasma mycoides var. Capri cells. Na+-dependent K+ accumulation

We have studied some features of K+ accumulation by glycolysing Mycoplasma mycoides var. Capri cells. We report that when Na+ is absent from the external medium, K+ accumulates up to the level predicted by the amplitude of the transmembrane electrical potential, delta psi m, measured by Rb+ and methyltriphenylphosphonium cation (TPMP+) distribution. Therefore, under these experimental conditions, the coupling mechanism of K+ uptake consists of a delta psi m-driven uniport. More important, when Na+ is present in the external medium, the level of K+ accumulation by glycolysing Mycoplasma cells is far too steep to be equilibrium with delta psi m (-120 mV for delta muK+ compared with -90mV for delta muRb+ or delta muTPMP+). Our results clearly indicate the presence in Mycoplasma of an active K+-transport system specifically stimulated by Na+. Furthermore, by controlling the amplitude of the energy-dependent delta muH+, we obtain strong evidence that this specific Na+-stimulated K+ transport is modulated by the transmembrane electrical potential. Finally, we show that ATP is consumed when such a transport system is in activity.     

Pathway of gluconeogenesis from tagatose in rat hepatocytes

Hepatocytes from fasted rats were incubated with a combination of substrate levels of fructose plus tagatose, and either [3-¹⁴C]fructose or [3-¹⁴C]tagatose. The ¹⁴C distribution in the glucose formed was identical, suggesting that tagatose and fructose are metabolized by identical pathways. When these sugars were incubated separately, the rate of gluconeogenesis from tagatose was about half that from fructose.     

Characterization of a rapid cellular-fractionation technique for hepatocytes. Application in the measurement of mitochondrial membrane potential in situ

A rapid cellular-fractionation technique [ Hoek , Nicholls & Williamson (1980) J. Biol. Chem. 255, 1458-1464] was further characterized by using hepatocytes. Of the mitochondrial marker-enzyme activity, 80% was routinely separated from 71-98% of the total cell activities of marker enzymes for plasma membranes, Golgi-membranes, endoplasmic reticulum, lysosomes and cytosol. The mitochondria were contaminated with 53% of cell nuclei. [3H]Triphenylmethylphosphonium ion (TPMP+) was added to hepatocytes in an attempt to measure cellular transmembrane electrical potentials. After rapid cell fractionation the electrical potential between mitochondria in situ and the incubation medium was found to be 202 mV. This value was slightly increased when hepatocytes were treated with oligomycin, but substantially decreased by oligomycin plus an uncoupler of oxidative phosphorylation. Although estimates of TPMP+ binding were obtained, substantial difficulties prevented the accurate measurement of the electrical potential across the plasma membrane. It is concluded that TPMP+ may be employed to demonstrate the integrity of mitochondria during the fractionation procedures. However, the cation is inadequate for the determination of the separate components of the electrical potential between the mitochondrial matrix and the incubation medium.     

Regulation of hepatic glucose metabolism by translocation of glucokinase between the nucleus and the cytoplasm in hepatocytes.

We studied the role of glucokinase translocation between the nucleus and the cytoplasm in hepatocytes. In cultured hepatocytes, both the translocation of glucokinase from the nucleus to the cytoplasm and the rate of glucose phosphorylation were increased when cells were incubated with high concentrations of glucose. The addition of low concentrations of fructose, which is known to stimulate glucose phosphorylation, stimulated both glucokinase translocation and glucose phosphorylation. There was a good correlation between the increase in cytoplasmic glucokinase induced by fructose and that in the glucose phosphorylation rate induced by fructose. Furthermore, we observed a linear relationship between cytoplasmic glucokinase activity and rate of glucose phosphorylation over various glucose concentrations in the absence or presence of fructose. These results indicate that glucose phosphorylation in hepatocytes depended on glucokinase in the cytoplasmic compartment--that is, the increase in the rate of glucose phosphorylation was due to the increase in translocation of glucokinase out of the nucleus. Also, oral administration of glucose, fructose, or glucose plus fructose to 24-h fasted rats induced translocation of glucokinase in the liver. All of these results indicate that hepatic glucose metabolism is regulated by the translocation of glucokinase.     

Zinc inhibition of hepatic fructose metabolism in rats

The ability of Zn to modulate key metabolic processes was investigated in a study of gluconeogenesis in isolated hepatocytes from fasted rats. Zn (100 μM) inhibited glucose production from fructose by 41%, sorbitol by 28%; glycerol by 17%, and glyceraldehyde by 26%. Maximum inhibition of gluconeogenesis from fructose occurred at 25 μM Zn. Zn inhibited the rate of lactate production from fructose by 24% but not from sorbitol, glycerol, or glyceraldehyde. Fructose uptake by hepatocytes was not affected by Zn. A positive linear relationship (r=0.994) was obtained between inhibition by Zn of glucose and lactate production, indicating that a common step in both pathways is inhibited by Zn. The effect of Zn on fructokinase, aldolase-B, and triokinase activities was determined on semipurified rat liver enzyme preparations. Zn had no affect on triokinase activity but inhibited the two other enzymes in a dose-dependent manner, with the inhibition of aldolase-B being much greater than of fructokinase for concentrations of Zn between 2.5 and 20 μM. Zn increased the intracellular concentration of fructose-1-P in hepatocytes incubated with fructose, indicating a more potent Zn inhibition of aldolase-B than fructokinase. In addition, hepatocytes treated with Zn had decreased ATP and ADP concentrations, but had normal energy charge, suggesting an effect of Zn on adenine nucleotide degradation or synthesis. The demonstration that Zn inhibits two enzymes in fructose metabolism adds to the growing list of metabolic pathways that are catalyzed by enzymes that are sensitive to Zn.     

Mitochondrial activation directly triggers the exocytosis of insulin in permeabilized pancreatic beta-cells.

In the pancreatic beta-cell, insulin secretion is stimulated by glucose metabolism resulting in membrane potential-dependent elevation of cytosolic Ca2+ ([Ca2+]c). This cascade involves the mitochondrial membrane potential (delta psi[m]) hyperpolarization and elevation of mitochondrial Ca2+ ([Ca2+]m) which activates the Ca(2+)-sensitive NADH-generating dehydrogenases. Metabolism-secretion coupling requires unidentified signals, other than [Ca2+]c, possibly generated by the mitochondria through the rise in [Ca2+]m. To test this paradigm, we have established an alpha-toxin permeabilized cell preparation permitting the simultaneous monitoring of [Ca2+] with mitochondrially targeted aequorin and insulin secretion under conditions of saturating [ATP] (10 mM) and of clamped [Ca2+]c at substimulatory levels (500 nM). The tricarboxylic acid (TCA) cycle intermediate succinate hyperpolarized delta psi(m), raised [Ca2+]m up to 1.5 microM and stimulated insulin secretion 20-fold, without changing [Ca2+]c. Blockade of the uniporter-mediated Ca2+ influx into the mitochondria abolished the secretory response. Moreover, glycerophosphate, which raises [Ca2+]m by hyperpolarizing delta psi(m) without supplying carbons to the TCA cycle, failed to stimulate exocytosis. Activation of the TCA cycle with citrate evoked secretion only when combined with glycerophosphate. Thus, mitochondrially driven insulin secretion at permissive [Ca2+]c requires both a substrate for the TCA cycle and a rise in [Ca2+]m. Therefore, mitochondrial metabolism generates factors distinct from Ca2+ and ATP capable of inducing insulin exocytosis.     

Depolarization of In Situ Mitochondria Due to Hydrogen Peroxide-Induced Oxidative Stress in Nerve Terminals

Mitochondrial membrane potential (delta psi(m)) was determined in intact isolated nerve terminals using the membrane potential-sensitive probe JC-1. Oxidative stress induced by H2O2 (0.1-1 mM) caused only a minor decrease in delta psi(m). When complex I of the respiratory chain was inhibited by rotenone (2 microM), delta psi(m) was unaltered, but on subsequent addition of H2O2, delta psi(m) started to decrease and collapsed during incubation with 0.5 mM H2O2 for 12 min. The ATP level and [ATP]/[ADP] ratio were greatly reduced in the simultaneous presence of rotenone and H2O2. H2O2 also induced a marked reduction in delta psi(m) when added after oligomycin (10 microM), an inhibitor of F0F1-ATPase. H2O2 (0.1 or 0.5 mM) inhibited alpha-ketoglutarate dehydrogenase and decreased the steady-state NAD(P)H level in nerve terminals. It is concluded that there are at least two factors that determine delta psi(m) in the presence of H2O2: (a) The NADH level reduced owing to inhibition of alpha-ketoglutarate dehydrogenase is insufficient to ensure an optimal rate of respiration, which is reflected in a fall of delta psi(m) when the F0F1-ATPase is not functional. (b) The greatly reduced ATP level in the presence of rotenone and H2O2 prevents maintenance of delta psi(m) by F0F1-ATPase. The results indicate that to maintain delta psi(m) in the nerve terminal during H2O2-induced oxidative stress, both complex I and F0F1-ATPase must be functional. Collapse of delta psi(m) could be a critical event in neuronal injury in ischemia or Parkinson's disease when H2O2 is generated in excess and complex I of the respiratory chain is simultaneously impaired.     

Reversible depolarization of in situ mitochondria by oxidative stress parallels a decrease in NAD(P)H level in nerve terminals

We have reported recently (Chinopoulos et al., 1999 J. Neurochem. 73, 220 228) that mitochondrial membrane potential (delta(psi)m) in isolated nerve terminals is markedly reduced by H2O2 in the absence of F0F1-ATPase working as a proton pump. Here we demonstrate that delta(psi)m reduced by H2O2 (0.5 mM) in the presence of oligomycin (10 mM), an inhibitor of the F0F1-ATPase, was able to recover by the addition of catalase (2000 U). Similarly, a decrease in the NAD(P)H level due to H2O2 can be reversed by catalase. In addition, H2O2 decreased the ATP level and the [ATP]:[ADP] ratio measured in the presence of oligomycin reflecting an inhibition of glycolysis by H2O2, but this effect was not reversible. The effect of H2O2 on delta(psi)m in the presence of the complex I inhibitor, rotenone, was also unaltered by addition of catalase. These results provide circumstantial evidence for a relationship between the decreased NAD(P)H level and the inability of mitochondria to maintain delta(psi)m during oxidative stress.     

The control of electron flux through cytochrome oxidase.

1. The electron flux through cytochrome oxidase is a linear function of the net thermodynamic force across the complex over a limited range of conditions. 2. Over a wide range of conditions the electron flux is a complicated function of the percentage reduction of the cytochrome c pool and of delta psi (at low values of delta pH). 3. We have estimated the elasticities of electron flux through cytochrome oxidase to delta Eh of the redox reaction catalysed by cytochrome oxidase (or to cyt c2+/cyt c3+) and to delta psi. The elasticities varied depending on the values of delta psi and of the percentage reduction of the cytochrome c pool. 4. At intermediate rates (which may correspond to those in vivo) the electron flux through cytochrome oxidase is controlled to about the same extent by delta psi and by delta Eh.     

Coupling of Li+ distribution to the plasma membrane potential of rat cortical synaptosomes

The effect of the plasma membrane potential delta psi p on the transport rate and steady state distribution of Li+ was assessed in rat cortical synaptosomes. Up to 15 mM Li+ failed to saturate Li+ influx into polarized synaptosomes in a Na+-based medium with 3 mM external K+. Veratridine increased and tetrodotoxin, ouabain, or high external K+ decreased the rate of Li+ influx. At steady state, Li+ was concentrated about 3-fold in resting synaptosomes at 0.3 to 1 mM Li+ externally. Subsequent depolarization of the plasma membrane by veratridine or high external K+ induced an immediate release of Li+. When graded depolarizations were imposed onto the plasma membrane by varying concentrations of ouabain, veratridine, or external K+, steady state distribution of Li+ was linearly related with K+ distribution or electrochemical activity coefficients. It was concluded that uptake rate and steady state distribution of Li+ depend significantly on delta psi p. However, Li+ gradients were lower than predicted from delta psi p, suggesting that (secondary) active transport systems counteracted passive equilibration by uphill extrusion of Li+. The electrochemical potential difference delta mu Li+ maintained at a delta psi p of -72 mV was calculated to 4.2 kJ/mol of Li+. At physiological external K+, Li+ was not actively transported by the sodium pump. The ouabain sensitivity resulted from the coupling of Li+ uptake to the pump-dependent K+ diffusion potential. In low K+ and K+-free media, however, active transport of Li+ by the sodium pump contributed to total uptake. In the absence of K+, Li+ substituted for K+ in generating a delta psi p of -64 mV maximally, as calculated from TPMP+ distribution at 40 mM external Li+. Since Li+ gradients were far too low to account for a diffusion potential, it was assumed that Li+ gave rise to an electrogenic pump potential.