Energy Source for Active Transport of α-Aminoisobutyric Acid in KB Cells

Abstract The energy source for concentrative transport of α-amino-isobutyric acid (AIB) in KB cells is ATP generated during either anaerobic glycolysis or oxidative phosphorylation. The dependence of AIB accumulation on the concentration of ATP is described by a rectangular hyperbola from which the ATP concentration supporting half-maximal accumulation of AIB was estimated to be 0.8 mm. With the aid of inhibitors and uncouplers of oxidative phosphorylation it was shown that energization of AIB transport by ATP does not involve the participation of high energy intermediates which may be generated within the mitochondria during oxidative phosphorylation or from ATP. Evidence was obtained against the function of phosphoenolpyruvate as the immediate energy donor to the transport system. A kinetic analysis of AIB influx and efflux revealed that ATP and intracellular K+ act on the step involved in AIB uptake by decreasing the Km for AIB influx, whereas oligomycin increases this Km. A comparison of the effectiveness of oligomycin, peliomycin, and ossamycin in inhibiting three distinct biochemical systems, namely, oxidative phosphorylation, AIB transport, and the (Na+ + K+)-ATPase, showed that all three inhibitors are equally effective in inhibiting oxidative phosphorylation, but peliomycin is the most effective in inhibiting the (Na+ + K+)-ATPase. Ossamycin is the least effective in inhibiting the latter and AIB transport.

From the Department of Biochemistry, School of Medicine, University of Pennsylvania, Philadelphia, Pennsylvania 19174 SUMMARY The energy source for concentrative transport of cu-aminoisobutyric acid (AIB) in KB cells is ATP generated during either anaerobic glycolysis or oxidative phosphorylation. The dependence of AIB accumulation on the concentration of ATP is described by a rectangular hyperbola from which the ATP concentration supporting half-maximal accumulation of AIB was estimated to be 0.8 1~1~.
With the aid of inhibitors and uncouplers of oxidative phosphorylation it was shown that energization of AIB transport by ATP does not involve the participation of high energy intermediates which may be generated within the mitochondria during oxidative phosphorylation or from ATP. Evidence was obtained against the function of phosphoenolpyruvate as the immediate energy donor to the transport system. A kinetic analysis of AIB influx and efflux revealed that ATP and intracellular I(+ act on the step involved in AIB uptake by decreasing the K, for A.IB influx, whereas oligomycin increases this K,. A comparison of the effectiveness of oligomycin, peliomycin, and ossamycin in inhibiting three distinct biochemical systems, namely, oxidative phosphorylation, AIB transport, and the (Naf + I(+)-ATPase, showed that all three inhibitors are equally effective in inhibiting oxidative phosphorylation, but peliomycin is the most effective in inhibiting the (Na+ + I(+)-ATPase.
Ossamycin is the least effective in inhibiting the latter and AIB transport.
During the last decade various proposals have been made concerning the energy source of active transport of nonelectrolytes in mammalian systems. According to one of these proposals the energy available from the Na+ gradient across the plasma membrane maintained by the function of the (Na+ + K+)-ATPase' is sufficient for the active transport of amino acids * This investigation was supported by Public Health Service Research Grant CA-02228.19 from the National Cancer Institute.
$ A portion of this work was taken from a thesis for the degree of Doctor of Philosophy submitted to the Graduate School of Arts and Sciences, University of Pennsylvania.
1 The abbreviations used are: (Na+ + K+)-ATPase, the Na+ + K+-activated ouabain-inhibitable ATPase mediating the trans-and sugars across pigeon erythrocytes and the intestinal epithelium (l-9). However, other investigators working with ascites tumor cells concluded that the energy from the Naf gradient is insufficient and the additional energy could be provided by the K+ gradient across the plasma membrane (10)(11)(12)(13)(14). The validity of this proposal was seriously questioned by subsequent work in which active amino acid transport in various mammalian cells was shown to occur in the absence of Na+ and K+ gradients or when the direction of these gradients was reversed (15)(16)(17)(18)(19)(20)(21)(22).
Furthermore, in the absence of metabolic energy the imposed Na+ and K+ gradients could support less than 20% of the amino acid accumulation obtained in the presence of metabolic energy (10,(19)(20)(21).
Schafer and Heinz (19) concluded that the energy available from the electrochemical potential gradients of Na+ and K+, including the transmembrane potential, cannot account for the accumulated amino acid in Ehrlich ascitcs tumor cells. More recently Geck et al. (21) showed that the masimum efficiency of coupling between the influx of Na+ and the transport of cr-aminoisobutyric acid (AIB) in ascites cells is only 7 y0 and therefore too low to allow sufficient channelling of energy from the Na+ and K+ gradients into amino acid transport.
In experiments in which the Na+ and K+ gradients were varied, the concentrations of these cations were also varied from the optimal levels necessary for maximal amino acid accumulation. Therefore, it is not possible to dissociate gradient from concentration effects in those cases in which amino acid transport dcpends on extracellular Na+ (10,15,16,(23)(24)(25)(26)(27)(28) and intracellular K+ (14, 29). From all of the evidence available at prcscnt it can be concluded that aIthough the energy from the electrochemical potential gradients of Na+ and K+ can be used to drive act'ive amino acid transport, a direct coupling between these fiuxes can be excluded as the main mechanism of energization of amino acid transport.
The above considerations stimulated further research directed towards defining the energy source for active amino acid uptake in mammalian cells. Potashner and Johnstonc (27,28) were able to show that amino acid accumulation in Ehrlich ascites cells depended on a normal intracellular [ATP] rather than on the Na+ gradient.
These results gave support to the idea that cellular ATP could serve as energy source for active amino acid transport, but further studies are necessary to establish: (a) the degree of dependence of amino acid accumulation on the concentration of ATP; (b) whether or not the energy of ATP must first be transduced within the mitochondrion to energy-rich intermediates which in turn would drive active amino acid uptake, especially since Van Rossum (30) concluded that the energy which drives the translocation of cations across the plasma membrane of liver cells can be derived directly from high energy intermediates of osidative phosphorylation; (c) the mechanism by which the energy of ATP is coupled to amino acid transport.
In this paper we present the results of our studies bearing on the above aspects of active transport of or-aminoisobutyric acid in KB cells.

EXPERIMESTAL PROCEDURE
Cztllure Co&ilio,ls--The KB cells (certified line No. 17 of the American Type Culture Collection) were grown in suspension cultures in Eagle's minimal essential medium containing 10% horse serum (31). The cell density was maintained between 2 X lo5 and 6 X 105 cells per ml. Im&alion Medium-The medium used in all of these studies was a modified Krebs-Ringer bicarbonate buffer of the following composition, in mM: KCl, 36.0; NaCl, 75.0; NaHtPOr, 10.0; NaHCOa, 25.0; MgSOb, 1.2. The pH was 7.4 by equilibrating with a mixture of 95% 02-570 con. For anaerobic experiments the KRB was equilibrated with a mixture of 95% Nz-5yo CO*. The final osmolarity was 0.3 OSM. Where indicated glucose was added to the medium to a final concentration of 2.0 mM. K+ was raised above the usual level of 5 to 36 rnM in order to maintain its intracellular concentration above 30 mM in those situations in which, by design, the cells are depleted of ATP or their (Na+ + K+)-ATPase is inactivated by various compounds included in the incubation medium.
It was previously shown (29)  were determined in neutralized extracts of the cells by the enzymatic methods indicated. Analytical Methods-The procedures for determining the cell number, the cell water, the cell viability, and [%]AIB were described previously (39). Protein was measured by the method of Lowry et al. (40).
All other materials were of reagent grade. Oligomycin, peoliomycin, and ossamycin were dissolved in absolute ethanol.
The [ethanol] in the incubation mixtures resulting from the addition of these compounds was 0.1%. The same amount of ethanol without these compounds was added to the control incubations.
Reproducibility of Experimental Results-All incubations were performed in duplicate.
The variability of the results among duplicate incubations was less than 5'%, whereas variability among several similar experiments performed with different batches of cells was less than 10%. The values presented in this paper are the averages of two or more experiments.

Accumulation of AIB and Steady State Levels of ATP When
Metabolic Energy Is Derived from Aerobic or Anaerobic Glycolysis- Fig.  1 shows the levels of intracellular ATP when the cells are incubated aerobically or with KCN in the presence of 2 mM glucose. It can be seen that inhibition of respiration causes a 25% decrease of the steady state (ATP].
The ability of the cells to accumulate AIB under these conditions is shown in Table I. Anaerobic conditions cause a small and comparable reduction of AIB accumulation and the steady state [ATP]. Addition of DNP at concentrations which uncouple mitochondrial osidative phosphorylation has no effect on either AIB accumulation or the ATP levels. Thus, in the presence of active glycolysis DNP fails to deplete the ATP.
As will be shown later DNP can deplete the intracellular ATP when the cells are incubated without glucose. AIB Accumulation Driven by Glycolytic ATP When Mitochondrial Respiration and Energy Conservation Are Inhibited-In order to test whether glycolytically derived ATP can support AIB accumulation without the intervention of a mitochondrial energy-transducing event we studied the effects of oligomycin, peliomycin, and ossamycin on AIB accumulation when the Effects of various inhibitors on glycolytically supported AIB accumulation and ATP levels Cells were incubated at 37" for 16 min in KRB containing 2.0 mM glucose with or without NaCN (2.0 mM), and DNP (0.2 mM).
[14C]AIB (0.2 mM) was then added, and the cells were incubated for an additional period of 25 min. Similar incubations with unlabeled AIB were used for ATP analyses. Net AIB accumulation (intracellular minus extracellular concentration) and [ATP] were determined at the end of the incubation period.
In the absence of inhibitors, the cells accumulated 1.52 f 0.08 mM AIB and contained 2.20 f 0.24 mM ATP. The cells were incubated at 37" for 16 min in KRB containing 2.0 mM glucose, 2.0 mM NaCN, and various levels of these inhibitors.
[W]AIB (0.2 mM) was then added and the incubations were continued for an additional 25 min. Similar incubations with unlabeled AIB were used for ATP analyses. Each assay contained 2 X lo6 cells per ml, equivalent to 0.67 mg of protein.
Open symbols represent the [ATP], and solid symbols the net AIB accumulation. cellular ATP is derived from anaerobic glycolysis.
These compounds had been shown to inhibit oxidative phosphorylation and the ATPase reactions induced by various agents (41). A representative experiment showing the time course of inhibition of the initial influx rate of AIB by oligomycin is shown in Fig. 2. It can be seen that about 20 min of exposure to oligomycin produces maximal inhibition of the AIB influx rate. Similar results were obtained with peliomycin and ossamycin.
Therefore, in all subsequent studies with these inhibitors the cells were incubated with the inhibitor for 16 min before AIB accumulation was measured. Fig. 3 presents the effects of oligomycin, peliomycin, and ossamycin on AIB accumulation and the steady state [ATP] maintained by anaerobic glycolysis.
It is clearly shown that oligomycin and peliomycin inhibit AIB ac-cumuIatXon ~CJC without causing any &ecrease in the steady state (ATP].
Both compounds are effective at comparable concentrations.
Fifty per cent inhibition is produced by 5 to 6 I.rg per ml, and maximal inhibition by 8 to 10 pg per ml. The effects of ossamycin are less specific and more complex.
Much higher concentrations are needed to inhibit AIB accumulation, and in addition to its effect on AIB transport, it causes comparable reduction of the steady state [ATP]. Hence, it is not possible to decide whether the inhibition of AIB accumulation by ossamycin is independent of the reduction of the ATP levels.
The inhibitory action of oligomycin on AIB transport was further studied in terms of its effect on the rate of AIB uptake. The incubation conditions were the same as those described in Fig. 3, except that the incubation time with [W]AIB was 1 min instead of 25 min. FIG. 5 (right). Time course of depletion of glycolytically derived ATP by DNP, and repletion of ATP by oxidative phosphorylation following removal of DNP.
Cells were incubated at 37" in KRB without glucose in the presence or absence of DNP (0.3 mM). Aliquots were removed at the times indicated for determination of intracellular ATP (preincubation). At 35 min the remaining portions of the cells were centrifuged and washed three times with 100 volumes each of ice-cold 0.15 M NaCl in order to remove the intracellular DNP.
The cells were then suspended in fresh KRB without glucose, and were incubated at 37" for various periods as indicated, when the intracellular [ATP] was determined. O---O, cells treated as described above but without exposure to DNP; A--A, cells exposed to DNP.
to the concentration which maximally inhibits AIB accumulation (Fig. 3). Two interpretations can be considered to explain the results obtained with oligomycin and peliomycin.
(a) These compounds could act at the plasma membrane by interacting with the membrane sites involved in AIB transport thereby inhibiting the energieation of the transport system by ATP.
An analogy to this mode of action is the inhibition by oligomycin of the (Na+ + K+)-ATPase of the plasma membrane (42-45 Cells were first incubated in KllB without glucose in the presence of 0.3 mM DNP for 35 min in order to deplet,e the intracellular ATP. At this point the intracellular [ATP] was 0.18 mM. The cells were then cent,rifuged, washed three times with ice-cold 0.15 M NaCl, and were incubated at 37" in fresh KltB medium without glucose for 16 min with or without the additions shown. [%]AIB (0.2 mM) was then added, and the cells were incubated for an additional 25 min in order to determine the extent of AIB accumulation. Similar incubations with unlabeled AIB were used for the determination of intracellular ATP levels. The measurements of ATP and intracellular AIB were performed at the end of the final incubation period. The "control" represents cells which were processed as described above, except that they were never exposed to any of the inhibitors.
In these cells the [ATP] was 1.60 rnh% and the net accumulation of AH3 was 1.30 mM. Since the addition of either cyanide, oligomycin, or DNP at the beginning of the recovery period prevents restoration of normal ATI' levels, the energy used to replenish this ATP is of respiratory origin. These results as well as the estent of AIl3 accumulation after recovery from DNP treatment are shown in Table II. It can be seen that the devised conditions allow AIB accumulation and ATP synthesis to take place entirely from mitochondrial respiratory energy at the expense of endogenous osidizable substrates.
Lactate was examined as a possible endogenous substrate the oxidation of which furnishes the energy for restoration of the [ATP].
In cells treated with DNl' the initial [lactate] following removal of DNP was 1.7 mM, and during the subsequent 20 min of incubation when the cellular ATP is restored to its normal level of 1.2 mM (see Fig. 5 It is also possible that other endogenous substances such as fatty acids and amino acids could serve as oxidizable substrates. In

Respiration-coupled
Oxidative Phosphorylation-Using the conditions described in Table II esperiments were carried out with the following objectives in mind: (a) to compare the concentrations of these inhibitors giving maximal inhibition of osidative phosphorylation with those inhibiting AIB accumulation when the ATP is derived entirely from anaerobic gly- The cells (2 X lo6 cells, equivalent to 0.67 mg of protein) were first depleted of endogenous ATP and glycolytic substrates by incubation with DNP as described in Table II. Following removal of DNP, the cells were exposed to different concentrations of these inhibitors for 16 min at 37". [14C]AIB (0.2 mM) was then added, and the cells were incubated for an additional 25 min in order to allow establishment of steady state accumulation of AIB. At the end of this period, the intracellular [AIB] and [ATP] were determined.
Steady state levels of ATP are established 20 min after the addition of these inhibitors and remain unchanged throughout the remaining incubation period.
Open synabols represent the [ATP], and solid symbols the net AIB accumulation.
colysis (from such a comparison it would be possible to determine whether or not the energization of AIB transport by glycolytic ATP depends on intramitochondrial energy transduction and generation of energy-rich compounds postulated to be intermediates in the over-all process of oxidative phosphorylation) ; (b) to establish whether or not the mitochondrial energy-conserving process can drive active AIB transport when ATP synthesis during oxidative phosphorylation is inhibited; (c) to determine the quantitative relationship that may exist between the steady state [ATP] and the magnitude of AIB accumulation.
The results of these experiments are presented in Fig. 6. The concentrations of oligomycin, peliomycin, and ossamycin causing 50% decrease of the [ATP] are 0.012,0.008, and 0.012 pg per ml, respectively.
The corresponding concentrations for 50% inhibition of AIB accumulation are 0.016, 0.008, and 0.018 pg per ml, respectively.
Maximal reduction of the [ATP] and inhibition of AIB accumulation are obtained at 0.03 to 0.04 pg per ml with all three inhibitors; addition of as much as 1.0 pg per ml produced no further inhibition.
Therefore, this concentration is effecting maximal inhibition of oxidative phosphorylation. The reason why the steady state [ATP] in the fully inhibited cells is maintained at about 0.15 mM could be that the rates of the reactions which utilize ATP decrease considerably when the [ATP] is severely reduced.
If the inhibited cells are incubated for periods longer than 60 min the [ATP] drops below 0.05 ITIM, and after washing away the inhibitors the cells restore their ATP to normal levels (1.2 MM).
The following conclusions can be drawn from the results presented above.
(a) AIB accumulation depends on the availability of ATP, and inhibition of ATP synthesis by the above In all of these experiments the extracellular [AIB] was inhibitors results in a concomitant inhibition of AIB accumulation of comparable magnitude.
Hence, the energy conserved during electron transport must be converted to ATP before it can energize active AIB transport.
(b) The maximal inhibition of AIB accumulation obtained with 0.04 pg per ml of either one of the above inhibitors is the result of inhibition of ATP synthesis rather than a direct effect of these inhibitors on the AIB transport system since under conditions when the ATP is maintained by anaerobic glycolysis no inhibition of AIB accumulation can be detected until the concentration of oligomycin or peliomycin is increased by more than lo-fold (0.5 fig per ml) and that of ossamycin by more than 500-fold (20 pg per ml), while 50% inhibition of AIB accumulation is obtained with 5 to 6 pg of oligomycin or peliomycin and with 105 pg of ossamycin (see Fig. 3). Thus, concentrations of these inhibitors which inhibit maximally AIB accumulation when synthesis of ATP is of respiratory origin exert no effect on AIB accumulation when ATP is maintained by anaerobic glycolysis, even when DNP (0.2 mM) is simultaneously present (not shown). Hence the energy of ATP can drive active AIB transport without prior transduction within the mitochondrion to high energy intermediates of oxidative phosphorylation.
(c) Th e m 1 1 ran of AIB accumulation ' h'b't' by higher concentrations of these inhibitors when ATP is maintained by glycolysis ought to represent an extramitochondrial effect, probably at the plasma membrane.
Relationship between Steady State Levels of ATP and AIB-From the data presented in Tables I and II, and in Fig. 6, the quantitative relationship between the intracellular levels of ATP and AIB was determined as shown in Fig. 7. The curve describing the points is a rectangular hyperbola, and if the data are plotted according to the method of Lineweaver and Burk a straight line is obtained from which the apparent [ATP] giving half-maximal accumulation of AIB was calculated to be about 0.8 mM.
The actual concentration is probably lower than 0.8 mM since an undetermined fraction of the cellular ATP may be compartmentalized and inaccessible to the AIB transport system.

Effects of Oligomycin,
Peliomycin, and Ossamycin on Rate of Respiration of KB Cells-The inhibition of ATP synthesis by these compounds when the metabolic energy is derived from oxidations via the respiratory chain can be ascribed to the in-hibition of the terminal steps of oxidative phosphorylation leading to the synthesis of ATP (41,(46)(47)(48).
Since similar detailed studies are not available for KB cells it was of interest to study the effect of these inhibitors on the rate of respiration of these cells. If these compounds inhibit mitochondrial ATP synthesis, they should cause an inhibition of respiration which would be relieved by the addition of DNP.
These studies showed that when KB cells are incubated in KRB containing 2.0 mM glucose separate addition of oligomycin, peliomycin, and ossamycin (0.04 or 10 pg per ml) causes severe inhibition of respiration.
Subsequent addition of DNP not only relieves this inhibition but stimulates the rate of respiration above that obtained by the uninhibited cells. DNP also relieves the inhibition of respiration caused by high concentrations (10 mM) of glucose (49). These results are in agreement with the proposed mode of action of these compounds as inhibitors of ATP synthesis during oxidative phosphorylation, while DNP acts typically as an uncoupler of this process.

Kinetic Parameters of AIB Transport in KB Cells under Various Experimental
Conditions-It was shown above that depletion of cellular ATP or inhibition of the cells by oligomycin and peliomycin leads to a loss of active AIB transport.
It was earlier shown that depletion of cellular K+ also results in the inability of the cells to concentrate AIB, and the transport system reverts from an active to one of facilitated diffusion (29). Since the loss of active transport can result from either inhibition of the entry or acceleration of the exit of the transported compound, experiments were carried out to determine which kinetic parameter of the AIB transport is affected by the above conditions.
Three types of cell preparations were used in these studies: (a) cells depleted of cellular K+ but containing normal ATP levels. The preparation of these cells by a preliminary incubation at 5" for 90 min in KRB containing glucose (2.0 mM) but lacking K+ was described earlier (29). Such cells contain 4 to 8 mM K+ and maintain normal levels (2.2 to 2.4 mM) of ATP throughout the subsequent period of the kinetic measurements of AIB transport.
The kinetics of AIB transport were studied in the above medium.
It was previously shown that AIB transport in KB cells is not affected by omission of extracellular K+ if the cellular K+ is maintained above 30 mM (29). Another portion of the cells was treated as described above, but during the kinetic measurements the incubation medium contained 10 mM Kf.
These cells served as the "Control"; (b) cells depleted of ATP (the cellular ATP was 0.07 to 0.09 mM) but containing optimal levels (45 to 50 mM) of K+. The conditions for preparing these cells by a preliminary incubation with DNP were described in Table Il. The kinetic measurements were carried out in KRB lacking glucose and containing 0.2 mM DNP in order to prevent restoration of cellular ATP.
Another portion of the cells treated as described above but allowed to restore normal ATP levels by omitting the DNP during the kinetic measurements served as "Control"; (c) cells containing normal levels of ATP (1.8 to 1.9 mM) and K+ (65 to 75 MM), but incapable of concentrative AIB transport due to inhibition by oligomycin. The preparation of these cells by a preliminary incubation in KRB containing glucose (2.0 mM), cyanide (2.0 mM), and oligomycin (10 pg per ml) was described in Fig. 3. The kinetic measurements were carried out in the same medium.
Another portion of the cells treated as above but which was not exposed to oligomycin served as "Control." The conditions for measuring initial rates of AIB influx and efflux were described in a previous publication (32). For influx Three types of cell preparations were used in these studies: 1. cells depleted of cellular ATP and containing optimal levels of K+; 2. cells depleted of K+ and containing normal levels of ATP; 3. cells containing normal levels of ATP and K+ but which lost active AIB transport as a result of inhibition by oligomycin. The preparation of these cells and the conditions used in the kinetic measurements were described in the text. The K, (millimolar) and V,., (nanomoles of AIB per lo6 cells per min) values were derived from Lineweaver-Burk plots of initial flux rates versus AIB concentrations from which the fluxes emanate.  In System 1 the cells were incubated in KRB containing glucose (2.0 mM) and KCN (2.0 mM) for 16 min at 37". [l*C]AIB (0.2 mM) was then added and the incubations were continued for 25 min for establishing steady state AIB accumulation.
At the end of this period the concentrations of ATP, PEP, and AIB were determined. In System 2 the cells were first depleted of ATP and glycolytic intermediates as described in Fig. 5. After washing away the DNP the cells were incubated in KRB without glucose in the presence or absence of oligomycin (0.04 rg per ml) for 16 min at 37". ["C]AIB was then added and the samples were incubated and processed as in System 1. The results of these studies are summarized in Table III (circles), peliomycin (triangles), and ossamycin (squares) on the activities of the ouabain-inhibitable (Na+ + K+)-ATPase and the ouabain-insensitive ATPase. The activities were assayed using a cell-free particulate fraction (0.3 mg of protein) as described previously (33). The complete assay mixture minus ATP was incubated with or without various levels of these inhibitors in the presence or absence of ouabain (0.13 mM) at 37" for 16 min, and the reaction was then initiated by the addition of ATP. The amount of P, released after 15 min was measured calorimetrically.
Under these conditions the reaction velocities were linear for 30 min and proportional to the amount of enzyme extract added (0.1 to 0.5 mg of protein per ml). Activities are expressed in micromoles of Pi released per mg of protein per 15 min. Solid symbols represent the activity of the ouabain-inhibitable (Na+ + K+)-ATPase, and ope?L symbols the activity of the ouabain-insensitive ATPase.
The concentrations of oligomycin and peliomycin are indicated on the upper scale, while those of ossamycin on the lower scale.
for efflux. None of the other kinetic parameters of AIB transport are changed by t'he above conditions. Thus, ATP and intracellular K+ function by decreasing the apparent K, for AIB influx.
Potashner and Johnstone (28) also reported an increase of the K, for amino acid influx in Ehrlich ascites cells depleted of ATP.
However, no data were given concerning the kinetics of amino. acid efflux. Our results offer an explanation for the observation of Heinz (50) that in Ehrlich ascites cells DNP and iodoacetate cause a significant decrease of the influx coefficient of glycine without affecting the efflux coefficient. Relationship between Steady State Levels of ATP, P-enolpyruvate, and Accumulated AIB-These studies were carried out in an attempt to determine whether or not PEP which is in eyuilibrium with ATP may be a more immediate energy donor than ATP for active AIB uptake.
The approach used was to examine whether the extent of AIB accumulation depends on the steady st.ate level of PEP. The experiments were carried out with KB cells in two different metabolic conditions: (a) cells in which the metabolic energy is derived from anaerobic glycolysis; and (b) cells in which the energy is derived from oxidations via the mit.ochondrial electron transport system. The results of these experiments are shown in Table IV These results strongly suggest that PEP is not the immediate energy donor in active AI13 transport.
Inhibition of (Naf + K+)-ATPase by Oligomycin, Peliomgcin, and Ossamycin-The inhibition by these compounds of active AIB transport by a mechanism not involving mitochondrial oxidative phosphorylation suggests that they may interact with other membrane systems, such as the plasma membrane, causing severe impairment of amino acid transport. Another important transport system of the plasma membrane, the activity of which is essential for t.he functional integrity of the AIB transport system, is the ouabain-inhibitable (Na+ + K+)-ATPase (29) which was shown to be inhibitable by oligomycin (42-45).
Thus, oligomycin inhibits three distinct cellular processes, namely oxidative phosphorylation, active amino acid transport, and active translocation of Na+ and K+ across the plasma membrane.
It was important therefore to determine whether or not peliomycin and ossamycin which inhibit the first two processes also inhibit this ATPase.
The results of these experiments are presented in Fig. 8 which also shows the effect of these inhibitors on the ouabain-insensitive ATPase activity.
The latter very likely represents the composite action of more than one enzyme. It can be seen that peliomycin is the most effective in inhibiting the (Na+ + K+)-ATPase, followed by oligomycin and lastly by ossamycin.
With regard to their action on the ouabain-insensitive ATPase peliomycin and ossamycin cause some inhibition, while oligomycin produces slight stimulation. Table V summarizes the concentrations of these compounds which produce 50% reduction of AIB accumulation, the steady state levels of ATP, and the activity of the (Na+ + K+)-ATPase. The concentrations producing 50% reduction of AIB accumulation and ATP levels when oxidative phosphorylation is the energy source are 6 to 10 times lower than those reported for a comparable inhibition of the rate of oxidative phosphorylation in rat liver mitochondria (51). However, in our studies the actual intracellular concentration of these inhibitors is not known.
Our results show that the energy for active AIB transport in KB cells is derived from ATP generated during either anaerobic glycolysis or respiration-coupled oxidative phosphorylation. Through the judicious use of three inhibitors of oxidative phos-phorylation, namely, oligomycin, peliomycin, and ossamycin, it was possible to systematically vary the steady state [ATP] and to show that the extent of AIB accumulation is dependent on the [ATP] in a manner described by a rectangular hyperbola from which the apparent [ATP], which supports half-maximal AIB accumulation, was estimated to be 0.8 mM. All three inhibitors are equally effective in inhibiting ATP synthesis and AIB accumulation when the metabolic energy is of respiratory origin.
In these experiments the steady state [ATP] was used as a measure of the relative effectiveness of these agents in inhibiting oxidative phosphorylation and hence ATP synthesis. The possibility that they may affect various cell reactions which utilize ATP in a manner such that the [ATP] may not reflect the rate of its synthesis appears rather unlikely since under conditions of anaerobic glycolysis the [ATP] is not affected by the presence of these compounds at concentrations 1000 times higher than those which abolish oxidative phosphorylation.
Furthermore, the inhibitor concentrations causing 50y0 reduction of the [ATP] are in good agreement with those producing 50% inhibition of ATP synthesis in respiring liver mitochondria (51). The experiments designed to determine the route by which the energy of ATP is channelled to the AIB transport system have clearly shown that ATP generated during glycolysis drives active AIB transport without prior energy transduction within the mitochondria to energy-rich intermediates of oxidative phosphorylation.
Conversely, respiratory energy must be converted to ATP before it can be used in concentrative AIB uptake.
The possibility that PEP may be the immediate energy donor to the transport system can be excluded since it was shown that AIB accumulation is abolished when the ATP is depleted even though the steady state [PEP] remains unchanged (Table IV).
Similarly, on the basis of evidence presented earlier in the introduction, indirect channelling of the AT1 energy to the transport system through establishment of cation gradients by the (Na+ + K+)-ATPase can also be excluded.
The reverse situation is more likely since it was shown that this ATPase can catalyze the synthesis of ATP utilizing the energy released from dissipation of the cation gradients (52, 53).
A kinetic analysis of AIB influx and efflux under presteady state conditions revealed that ATP, intracellular Kf, and oligomycin act on the entry process of the transport system. The same action was earlier shown for extracellular Na+ (26). Thus, depletion of cellular ATP or K+, elimination of extracellular Na+, and inhibition by oligomycin abolish active AIB transport by increasing the K, for AIB entry to the same value as the K, for exit. Many attempts to induce significant changes of the value of the latter parameter were unsuccessful.
These findings indicate that in KB cells the regulation of active AIB transport is accomplished by modulation of the K, for AIB entry through changes in the concentration of ATP, intracellular K+, and extracellular Na+. It is not known whether KB cells possess other means of regulating the activity of this transport system.
The abolition of AIB accumulation by higher concentrations of oligomycin and peliomycin when ATP is of glycolytic origin indicates that these agents inhibit AIB transport either by interacting with the carrier sites of the plasma membrane or by inhibiting the energy transfer from ATP to the transport system. It is of interest that another plasma membrane system, the (Na+ + Kf)-ATPase, is inhibited by oligomycin (42-45). Our studies confirm this observation and show that peliomycin also inhibits this carrier system. Compared to oligomycin peliomycin is 5 to 6 times more effective in inhibiting this ATPase,