Light-induced glutamate transport in Halobacterium halobium envelope vesicles. I. Kinetics of the light-dependent and the sodium-gradient-dependent uptake.

During illumination Halobacterium halobium cell envelope vesicles accumulate [3H]glutamate by an apparently unidirectional transport system. The driving force for the active transport originates from the light-dependent translocation of protons by bacteriorhodopsin and is due to a transmembrane electrical potential rather than a pH difference. Transport of glutamate against high concentration gradients is also achieved in the dark, with high outside/inside Na+ gradients. Transport in both cases proceeds with similar kinetics and shows a requirement for Na+ on the outside and for K+ on the inside of the vesicles. The unidirectional nature of glutamate transport seems to be due to the low permeability of the membranes to the anionic glutamate, and to the differential cation requirement of the carrier on the two sides of the membrane for substrate translocation. Thus, glutamate gradients can be collapsed in the dark either by lowering the intravesicle pH (with nigericin, or carbonyl cyanide p-trifluoromethoxyphenylhydrazone plus valinomycin), or by reversing the cation balance across the membranes, i.e., providing NaCl on the inside and KCl on the outside of the vesicles. In contrast to the case of light-dependent glutamate transport, the initial rates of Na+-gradient-dependent transport are not depressed when an opposing diffusion potential is introduced by adding the membrane-permeant cation, triphenylmethylphosphonium bromide. Therefore, it appears that, although the electrical potential must be the primary source of energy for the light-dependent transport, the translocation step itself is electrically neutral.

[1]  R. Baker,et al.  Energy coupling in the active transport of amino acids by bacteriohodopsin-containing cells of Halobacterium holobium , 1976, Journal of bacteriology.

[2]  W. Konings,et al.  Transport of amino acids in membrane vesicles of Rhodopseudomonas spheroides energized by respiratory and cyclic electron flow. , 1975, European journal of biochemistry.

[3]  E. Racker,et al.  Light-dependent proton and rubidium translocation in membrane vesicles from Halobacterium halobium. , 1975, Biochemical and biophysical research communications.

[4]  A. Blaurock Bacteriorhodopsin: A trans-membrane pump containing α-helix , 1975 .

[5]  R. Henderson The structure of the purple membrane from Halobacterium hallobium: analysis of the X-ray diffraction pattern. , 1975, Journal of molecular biology.

[6]  F. Harold,et al.  Accumulation of arsenate, phosphate, and aspartate by Sreptococcus faecalis , 1975, Journal of bacteriology.

[7]  R. Prasad,et al.  Active transport of glutamine and glutamic acid in membrane vesicles from Mycobacterium phlei. , 1975, Biochemical and biophysical research communications.

[8]  L. Heppel,et al.  Different mechanisms of energy coupling for the shock-sensitive and shock-resistant amino acid permeases of Escherichia coli. , 1974, The Journal of biological chemistry.

[9]  A. F. Brodie,et al.  Active transport of proline in membrane preparations from Mycobacterium phlei. , 1974, The Journal of biological chemistry.

[10]  J. Thompson,et al.  Potassium Transport and the Relationship Between Intracellular Potassium Concentration and Amino Acid Uptake by Cells of a Marine Pseudomonad , 1974, Journal of bacteriology.

[11]  I. West,et al.  Proton/sodium ion antiport in Escherichia coli. , 1974, The Biochemical journal.

[12]  W. Hamilton,et al.  Mechanisms of energy coupling to the transport of amino acids by Staphylococcus aureus. , 1974, European journal of biochemistry.

[13]  W. Stoeckenius,et al.  Photophosphorylation in Halobacterium halobium. , 1974, Proceedings of the National Academy of Sciences of the United States of America.

[14]  K. M. Miner,et al.  Sodium-Stimulated Glutamate Transport in Osmotically Shocked Cells and Membrane Vesicles of Escherichia coli , 1974, Journal of bacteriology.

[15]  F. Harold,et al.  Lactic Acid Translocation: Terminal Step in Glycolysis by Streptococcus faecalis , 1974, Journal of bacteriology.

[16]  U. Hopfer,et al.  Demonstration of electrogenic Na+-dependent D-glucose transport in intestinal brush border membranes. , 1974, Proceedings of the National Academy of Sciences of the United States of America.

[17]  D. Oesterhelt,et al.  Functions of a new photoreceptor membrane. , 1973, Proceedings of the National Academy of Sciences of the United States of America.

[18]  Y. S. Halpern,et al.  Sodium and Potassium Requirements for Active Transport of Glutamate by Escherichia coli K-12 , 1973, Journal of bacteriology.

[19]  I. West,et al.  Stoicheiometry of lactose–proton symport across the plasma membrane of Escherichia coli , 1973 .

[20]  J. Lanyi Studies of the electron transport chain of extremely halophilic bacteria. 8. Respiration-dependent detergent dissolution of cell envelopes. , 1972, Biochimica et biophysica acta.

[21]  A. Bisschop,et al.  Transport of L‐glutamate and L‐aspartate by membrane vesicles of Bacillus subtilis W 23 , 1972, FEBS letters.

[22]  Kaback Hr Transport across isolated bacterial cytoplasmic membranes. , 1972 .

[23]  J. Lanyi Studies of the electron transport chain of extremely halophilic bacteria. VII. Solubilization properties of menadione reductase. , 1972, The Journal of biological chemistry.

[24]  D. Oesterhelt,et al.  Rhodopsin-like protein from the purple membrane of Halobacterium halobium. , 1971, Nature: New biology.

[25]  W. Stoeckenius,et al.  Structure of the purple membrane. , 1971, Nature: New biology.

[26]  J. Lanyi Studies of the Electron Transport Chain of Extremely Halophilic Bacteria VI. SALT-DEPENDENT DISSOLUTION OF THE CELL ENVELOPE , 1971 .

[27]  S. Roseman,et al.  A sodium-dependent sugar co-transport system in bacteria. , 1971, Biochemical and biophysical research communications.

[28]  J. Thompson,et al.  Functions of Na+ and K+ in the active transport of -aminoisobutyric acid in a marine pseudomonad. , 1971, The Journal of biological chemistry.

[29]  I. West Lactose transport coupled to proton movements in Escherichia coli. , 1970, Biochemical and biophysical research communications.

[30]  S. Schultz,et al.  Coupled transport of sodium and organic solutes. , 1970, Physiological reviews.

[31]  K. S. Cheah The membrane-bound ascorbate oxidase system of Halobacterium halobium. , 1970, Biochimica et biophysica acta.

[32]  L. Frank,et al.  Sodium-Stimulated Transport of Glutamate in Escherichia coli , 1969, Journal of bacteriology.

[33]  A. Eddy,et al.  Further observations on the inhibitory effect of extracellular potassium ions on glycine uptake by mouse ascites-tumour cells. , 1969, The Biochemical journal.

[34]  K. S. Cheah Properties of electron transport particles from Halobacterium cutirubrum. The respiratory chain system. , 1969, Biochimica et biophysica acta.

[35]  J. Lanyi,et al.  Studies of the electron transport chain of extremely halophilic bacteria. II. Salt dependence of reduced diphosphopyridine nucleotide oxidase. , 1969, The Journal of biological chemistry.

[36]  J. Thompson,et al.  Nutrition and metabolism of marine bacteria. XVII. Ion-dependent retention of alpha-aminoisobutyric acid and its relation to Na+ dependent transport in a marine pseudomonad. , 1969, The Journal of biological chemistry.

[37]  J. Lanyi Studies of the electron transport chain of extremely halophilic bacteria. I. Spectrophotometric identification of the cytochromes of Halobacterium cutirubrum. , 1968, Archives of biochemistry and biophysics.

[38]  A. Eddy A net gain of sodium ions and a net loss of potassium ions accompanying the uptake of glycine by mouse ascites-tumour cells in the presence of sodium cyanide. , 1968, The Biochemical journal.

[39]  H. Christensen,et al.  Interdependent fluxes of amino acids and sodium ion in the pigeon red blood cell. , 1967, The Journal of biological chemistry.

[40]  W. Stoeckenius,et al.  A MORPHOLOGICAL STUDY OF HALOBACTERIUM HALOBIUM AND ITS LYSIS IN MEDIA OF LOW SALT CONCENTRATION , 1967, The Journal of cell biology.

[41]  M. Mulcahy,et al.  The effects of sodium ions and potassium ions on glycine uptake by mouse ascites-tumour cells in the presence and absence of selected metabolic inhibitors. , 1967, The Biochemical journal.

[42]  J. Stevenson The specific requirement for sodium chloride for the active uptake of L-glutamate by Halobacterium salinarium. , 1966, The Biochemical journal.

[43]  R. E. MacDonald,et al.  Light-induced leucine transport in Halobacterium halobium envelope vesicles: a chemiosmotic system. , 1975, Biochemistry.

[44]  P. Postma,et al.  The energetics of bacterial active transport. , 1975, Annual review of biochemistry.

[45]  W. Stoeckenius,et al.  Light energy conversion in Halobacterium halobium. , 1974, Journal of supramolecular structure.

[46]  F. Harold Antimicrobial Agents and Membrane Function , 1969 .