Summary
Uptake of α-aminoisobutyric acid (AIB) was examined in Ehrlich ascites tumor cells treated with the cation-exchange ionophore nigericin (20 μg/ml). Membrane voltages were measured using the voltage-sensitive dye diethyloxadicarbocyanine (DOCC). In normal phosphate-buffered media, nigericin changed the distribution ratios of Na+ and K+ (the ratio of intra- to extracellular concentrations) nearly to unity, but AIB was still accumulated to a distribution ratio of ∼9.0. When all but 40mm Na+ in the medium was replaced by choline, nigericin resulted in K+ loss and Na+ gain and both cation distribution ratios approached 2.8–3.4, as would be expected if both ions were distributing near electrochemical equilibrium with a membrane voltage in the range of −28 to −33 mV. This conclusion was supported by the observation that the addition of 5×10−7 m valinomycin to the nigericin-treated cell suspension produced no change in DOCC absorbance. In spite of the apparent zero electrochemical potential gradients for Na+ and K+, AIB was accumulated to a distribution ratio of 5.4 in the low-Na+ medium. Addition of 0.1mm oubain or 50 μm vanadate did not alter the extent of AIB accumulation as would have been expected if a large component of the membrane voltage were due to electrogenic operation of the (Na++K+)-ATPase. Addition of lactate, pyruvate or glucose increased the AIB distribution ratios to 11.9, 9.4 and 15.3, respectively. The effect of glucose could be explained, at least in part, by an enhanced Na+ electrochemical potential gradient. However, neither lactate nor pyruvate produced any change either in membrane voltage or the intracellular Na+ concentration. Therefore, these results confirm the existence of a metabolic energy source which is coupled to AIB accumulation and operates in addition to the Na+ co-transport mechanism, and which is augmented by metabolic substrates such as lactate and pyruvate.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Christensen, H.N., de Cespedes, C., Handlogten, M.E., Ronquist, G. 1973. Energization of amino acid transport, studied for the Ehrlich ascites tumor cell.Biochim. Biophys. Acta 300:487–522
Crane, F.L., Löw, H. 1976. NADH oxidation in liver and fat cell plasma membranes.FEBS Lett. 68:153–156
Garcia-Sancho, J., Sanchez, A., Handlogten, M.E., Christensen, H.N. 1977. Unexpected additional mode of energization of amino-acid transport into Ehrlich cells.Proc. Natl. Acad. Sci. (USA) 74:1488–1491
Geck, P., Heinz, E., Pfeiffer, B. 1974. Evidence against direct coupling between amino acid transport and ATP hydrolysis.Biochim. Biophys. Acta 339:419–425
Harris, E.J., Pressman, B.C. 1967. Obligate cation exchanges in red cells.Nature (London) 216:918–920
Heinz, A., Sachs, G., Schafer, J.A. 1981. Evidence for activation of an active electrogenic proton pump in Ehrlich ascites tumor cells during glycolysis.J. Membrane Biol. 61:143–153
Henderson, P.J.F., McGivan, J.D., Chappell, J.B. 1969. The action of certain antibiotics on mitochondrial, erythrocyte and artificial phospholipid membranes.Biochem. J. 111:521–535
Henius, G.V., Laris, P.C. 1979. The Na+ gradient hypothesis in cytoplasts derived from Ehrlich ascites tumor cells.Biochem. Biophys. Res. Commun. 91:1430–1436
Jackson, J.W., Schafer, J.A. 1977. Amino acid active transport: Further evidence for coupling to a plasma membrane redox system.Physiologist 20:47
Jacquez, J.A., Schafer, J.A. 1969. Na+ and K+ electrochemical potential gradients and the transport of α-aminoisobutyric acid in Ehrlich ascites tumor cells.Biochim. Biophys. Acta 193:368–383
Johnstone, R.M. 1974. Role of ATP in the initial rate of amino acid uptake in Ehrlich ascites cells.Biochim. Biophys. Acta 356:319–330
Johnstone, R.M. 1978. The basic asymmetry of Na+-dependent glycine transport in Ehrlich cells.Biochim. Biophys. Acta 512:199–213
Laris, P.C., Pershadsingh, H.A., Johnstone, R.M. 1976. Monitoring membrane potentials in Ehrlich ascites tumor cells by means of a fluorescent dye.Biochim. Biophys. Acta 436:475–488
Nechay, B.R., Saunders, J.P. 1978. Inhibition by vanadium of sodium and potassium dependent adenosine triphosphatase derived from animals and human tissues.J. Environ. Pathol. Toxicol. 2:247–262
Ohsawa, M., Kilberg, M.S., Kimmel, G., Christensen, H.N. 1980. Energization of amino acid transport in energy-depleted Ehrlich cells and plasma membrane vesicles.Biochim. Biophys. Acta 599:175–190
Philo, R.D., Eddy, A.A. 1978a. The membrane potential of mouse ascites-tumor cells studied with the fluorescent probe 3,3′-dipropyloxadicarbocyanine. Amplitude of the depolarization caused by amino acids.Biochem. J. 174:801–810
Philo, R.D., Eddy, A.A. 1978b. Equilibrium and steady-state models of the coupling between the amino acid gradient and the sodium electrochemical gradient in mouse ascites-tumour cells.Biochem. J. 174:811–817
Pietrzyk, C., Geck, P., Heinz, E. 1978. Regulation of the electrogenic (Na++K+)-pump of Ehrlich cells by intracellular cation levels.Biochim. Biophys. Acta 513:89–98
Pietrzyk, C., Heinz, E. 1974. The sequestration of Na+, K+ and Cl− in the cellular nucleus and its energetic consequences for the gradient hypothesis of amino acid transport in Ehrlich cells.Biochim. Biophys. Acta 352:397–411
Pressman, B.C. 1968. Ionophorous antibiotics as models for biological transport.Fed. Proc. 27:1283–1288
Rabon, E., Chang, H., Sachs, G. 1978. Quantitation of hydrogen ion and potential gradients in gastric plasma membrane vesicles.Biochemistry 17:3345–3353
Schafer, J.A. 1977. A reassessment of decreased amino acid accumulation by Ehrlich ascites tumor cells in the presence of metabolic inhibitors.J. Gen. Physiol. 69:681–704
Schafer, J.A., Heinz, E. 1971. The effect of reversal of Na+ and K+ electrochemical potential gradients on the active transport of amino acids in Ehrlich ascites tumor cells.Biochim. Biophys. Acta 249:15–33
Schafer, J.A., Jacquez, J.A. 1967. Change in Na+ uptake during amino acid transport.Biochim. Biophys. Acta 135:1081–1083
Smith, T.C., Herlihy, J.T., Robinson, S.C. 1981. The effect of the fluorescent probe, 3,3′-dipropylthiadicarbocyanine iodide, on the energy metabolism of Ehrlich ascites tumor cells.J. Biol. Chem. 256:1108–1110
Stanley, P.E., Williams, S.G. 1969. Use of the scintillation spectrometer for determining adenosine triphosphate by the luciferase enzyme.Anal. Biochem. 29:381–392
Waggoner, A.S., Wang, C.H., Tolles, R.L. 1977. Mechanism of potential-dependent light absorption changes of lipid bilayer membranes in the presence of cyanine and oxonol dyes.J. Membrane Biol. 33:109–140
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Heinz, A., Jackson, J.W., Richey, B.E. et al. Amino acid active transport and stimulation by substrates in the absence of a Na+ electrochemical potential gradient. J. Membrain Biol. 62, 149–160 (1981). https://doi.org/10.1007/BF01870207
Received:
Revised:
Issue Date:
DOI: https://doi.org/10.1007/BF01870207