Glutamate Transport in Large Muscle Fibres of Balanus nubilus

The uptake of glutamate and other acidic amino acids into barnacle single muscle fibres has been characterized. The uptake of glutamate consists of two components, one Na-independent and one Na-dependent. The Na-dependent uptake is saturable (half-maximal at 250 microM external glutamate) and is inhibited by a variety of analogues of which L-cysteate and D- and L-aspartate are the most potent. These amino acids are also transported into the muscle in a Na-dependent manner. The excitatory agonists kainate, quisqualate, and N-methyl-D-aspartate do not inhibit or affect uptake in any way. Progressive replacement of external Na by choline reduces uptake with very little effect on the apparent affinity for glutamate, suggesting that Na and glutamate bind to the transporter independently. The kinetics of activation are consistent with a requirement for at least two Na ions. Na activation of glutamate uptake can be inhibited by guanidinium with kinetics that are consistent with competitive inhibition at the Na binding site. Studies on the efflux of L-glutamate and other analogues have shown that efflux rates are only slightly increased by the removal of Na and do not seem to be affected in any clear manner by external levels of acidic amino acids.     

Purification and characterization of aspartate racemase from the bivalve mollusk Scapharca broughtonii

High concentrations of D-aspartate occur in blood shell Scapharca broughtonii (Mollusca) tissues. We purified aspartate racemase from the foot muscle of the bivalve to electrophoretic homogeneity. The molecular mass shown by sodium dodecyl sulfate polyacrylamide gel was 39 kDa, while that shown by gel filtration ranged from 51 to 63 kDa. Pyridoxal 5'-phosphate-dependency of the enzyme was demonstrated by its absorption spectrum as well as the effects of amino-oxyacetate and other reagents on the activity and spectrum. The enzyme is highly specific to aspartate and does not racemize L-alanine, L-serine and L-glutamate. It showed the highest activity at pH 8 both in the conversion of L- to D- and D- to L-aspartate, and the optimal temperature was 25 degrees C. V(max) and K(m) values for L-aspartate were 7.39 micromolmin(-1)mg(-1) and 60.4 mM and those for D-aspartate were 22.6 micromolmin(-1)mg(-1) and 159 mM, respectively.     

Heterogeneity of high affinity uptake of L-glutamate and L-aspartate in the mammalian central nervous system.

Characteristics of high affinity uptake of L-glutamate are examined in order to evaluate the possible use of the uptake of [3H]L-glutamate, [3H]L-aspartate or any other suitable [3H]-labelled substrate as a marker for glutamatergic and aspartergic synapses in autoradiographic studies in the mammalian brain. Review of data on substrate specificity indicates the presence of at least two high affinity uptake systems specific for acidic amino acids in the central nervous tissue; one which takes up L-glutamate and L-aspartate and the other which is selective for L-glutamate only. Studies on ionic requirements, too, point to the existence of at least two distinct uptake systems with high affinity for L-glutamate. The Na(+)-dependent uptake system(s) handle(s) both L-glutamate and L-aspartate whereas the Na(+)-independent uptake system(s) show(s) selectivity for L-glutamate only. Available data do not favour the Na(+)-dependent binding of [3H]D-aspartate to thaw-mounted sections of frozen brain tissue as a suitable marker for glutamatergic/aspartergic synaptic nerve endings. However, there are reasons--such as the results of lesion studies and the existence of uptake sites which have a higher affinity for L-aspartate than for D-aspartate--to suggest that Na(+)-dependent binding of [3H]L-aspartate, rather than that of [3H]D-aspartate, should be further investigated as a possible marker for the glutamatergic/aspartergic synapses in the autoradiographic studies using sections of frozen brain.     

Decreased Uptake and Release of D-Aspartate in the Guinea Pig Spinal Cord After Partial Cordotomy

This study attempts to determine if L-glutamate and/or L-aspartate may be transmitters of neural tracts descending from the brain to the spinal cord. The uptake and electrically evoked release of D-[3H]aspartate, a putative marker for L-glutamate and L-aspartate, were measured in the cervical enlargement of the guinea pig spinal cord. These activities were compared using unlesioned animals and others with a lesion on the right side of the spinal cord. Partial cordotomy (segment C5) produced a heavy loss of descending fibers, a small loss of primary sensory fibers, and a depression of the uptake and the Ca2+ -dependent, electrically evoked release of D-aspartate ipsilateral and caudal to the lesion. Contralaterally, there was a moderate loss of corticospinal fibers, some loss of other descending axons, and a depression of D-aspartate release. Dorsal rhizotomy (segments C4-T1) produced a heavy loss of primary sensory fibers ipsilateral to the lesion. Ipsilaterally, but not contralaterally, the uptake and release of D-aspartate were depressed. Degeneration after partial cordotomy in combination with dorsal rhizotomy was assumed to be the sum of that produced by each lesion separately. This combined lesion depressed D-aspartate uptake ipsilaterally and depressed D-aspartate release on both sides of the cervical enlargement. None of the lesions altered the uptake and the evoked release of [3H]GABA. These findings support the hypothesis that the synaptic endings of one or more neural tracts descending from the brain to the spinal cord mediate the uptake and release of D-aspartate and, therefore, may use L-glutamate or L-aspartate as a transmitter.     

Decreased Uptake and Release of D-Aspartate in the Guinea Pig Spinal Cord After Dorsal Root Section

This study attempts to determine if L-glutamate and/or L-aspartate may be transmitters of dorsal sensory neurons. The uptake and the electrically evoked release of D-[3H]aspartate, a putative marker for L-glutamate and L-aspartate, were measured in the cervical enlargement (segments C4-T1) of the guinea pig spinal cord before and after cutting dorsal roots C5-T1 on the right side. The uptake and the release of gamma-aminobutyric acid (GABA) also were measured as indices of the integrity of GABAergic neurons in the spinal cord. The cervical enlargement was excised and divided into left and right halves, then into dorsal and ventral quadrants. Quadrants from unlesioned animals took up D-aspartate and GABA, achieving concentrations in the tissues which were 14-25 times that in the medium. Subsequently, electrical stimulation evoked a Ca2+-dependent release of D-aspartate and of GABA. The uptake and release of D-aspartate and GABA were similar in tissues taken from intact and sham-operated animals. However, dorsal rhizotomy, without damage to dorsal radicular or spinal blood vessels, depressed the uptake (by 22-29%) and the release (by 50%) of D-aspartate only in quadrants ipsilateral to the lesion. The uptake and the release of GABA were unchanged. In transverse sections of the cervical enlargement, stained to reveal degenerating fibers, by far the heaviest loss of axons occurred in the cuneate fasciculus and in the gray matter ipsilateral to the cut dorsal roots. These findings suggest that the synaptic endings of dorsal sensory neurons probably mediate the uptake and the release of D-aspartate and, therefore, may use L-glutamate or L-aspartate as a transmitter. When spinal blood vessels were damaged during dorsal rhizotomy, the deficits in D-aspartate uptake and release were larger than those in the absence of vascular damage and were accompanied by deficits in GABA uptake and release. These findings imply that vascular damage results in the loss of intraspinal neurons, some of which probably mediate the uptake and release of D-aspartate and, therefore, may use L-glutamate and/or L-aspartate as a transmitter.     

Pharmacologically distinct glutamate receptors on cerebellar granule cells

Cultured cerebellar granule cells were found to exhibit calcium-dependent release of 3H-D-aspartate when stimulated with excitatory amino acids. L-glutamate and L-aspartate were found to be potent stimulators of 3H-D-aspartate release, D-aspartate was weaker and only minor effects were seen with D-glutamate, quisqualate, kainate, N-methyl-D-aspartate (NMDA) and L-alpha-aminoadipate (L-alpha AA). It was also found that only L-glutamate and L-aspartate showed high affinity for the 3H-L-glutamate binding sites on granule cell membranes. Stimulation by L-glutamate of 3H-D-aspartate release could be blocked by various excitatory amino acid antagonists. From the relative potencies of agonists and antagonists on D-aspartate release it is suggested that cerebellar granule cells express functionally active glutamate receptors with pharmacological characteristics different from all known excitatory amino acid receptors.     

The substrate specificity of a neuronal glutamate transporter is determined by the nature of the coupling ion

Glutamate transporters are essential for terminating synaptic transmission. Glutamate is translocated together with three sodium ions. In the neuronal glutamate transporter EAAC1, lithium can replace sodium. To address the question of whether the coupling ion interacts with the 'driven' substrate during co-transport, the kinetic parameters of transport of the three substrates, L-glutamate and D- and L-aspartate by EAAC-1 in sodium- and lithium-containing media were compared. The major effect of the substitution of sodium by lithium was on Km. In the presence of sodium, the values for Km and Imax of these substrates were similar. In the presence of lithium, the Km for L-aspartate was increased around 13-fold. Remarkably, the corresponding increase for L-glutamate and D-aspartate was much larger, around 130-fold. In marked contrast, the Ki values for a non-transportable substrate analogue were similar in the presence of either sodium or lithium. The preference for L-aspartate in the presence of lithium was also observed when electrogenic transport of radioactive substrates was monitored in EAAC1-containing proteoliposomes. Our results indicate that, subsequent to substrate binding, the co-transported solutes interact functionally in the binding pocket of the transporter.     

Biochemical identification of a putative glutamate receptor in housefly thoracic membranes

Specific stereoselective binding of [3H]L-glutamate was detected to membranes prepared from housefly thorax to which were added several antiproteases. A single high affinity binding site was detected (KD 0.5 +/- 0.04 microM), but total binding varied from preparation to preparation (5-60 pmoles/mg protein). Specific binding was inhibited by preincubation of the membranes with trypsin, chymotrypsin or protease, or by exposure to 70 degrees C for 5 min. It was also inhibited by several compounds, the most potent being L-glutamate and L-aspartate, followed by L-glutamate diethylester, then D-glutamate, N-methyl-D-aspartate and ibotenate. Quisqualate had little effect, while kainate, proctolin and D-aspartate had none. d-Tubocurarine stimulated [3H]L-glutamate binding. The data suggest that [3H]L-glutamate is binding to an L-glutamate receptor in housefly thoracic muscle membranes.     

Glutamine and Aspartate Loading of Synaptosomes: A Reevaluation of Effects on Calcium-Dependent Excitatory Amino Acid Release

Guinea-pig cerebral cortical synaptosomes were preincubated for 60 min with 100 microM D-aspartate, L-aspartate, or L-glutamate. The total D- plus L-aspartate content of the synaptosomal fraction increased to 235%, 195%, or 164%, respectively, of the control. Despite this no increase was seen in the very low KCl evoked, Ca2+-dependent release of aspartate. Preincubation with the three amino acids changed the synaptosomal glutamate content to 78% (D-aspartate), 149% (L-aspartate), or 168% (L-glutamate) of control. However there was no statistically significant effect of these preincubations on the extent of Ca2+-dependent glutamate release. Thus the Ca2+-dependent release of aspartate and glutamate is not determined by the total synaptosomal content of these amino acids. The addition of 0.1-0.5 mM glutamine to the incubation caused a massive appearance of glutamate in the extrasynaptosomal medium. Analysis of specific activities showed that glutamine was hydrolysed directly by an extrasynaptosomal glutaminase, and that intrasynaptosomal glutamate was predominantly labelled by uptake of this glutaminase-derived glutamate. No increase was seen in the extent of Ca2+-dependent release of glutamate (by fluorimetry) either after preincubation with glutamine or in the continued presence of glutamine. Thus we are unable to confirm reports that glutamine expands the transmitter pool of glutamate. The extrasynaptosomal glutaminase activity in the synaptosomal preparation was inhibited by Ca2+ and activated by phosphate. Identical kinetics were obtained with "free" brain mitochondria, confirming the origin of the glutamine-derived glutamate.     

Administration of D-aspartate increases D-aspartate oxidase activity in mouse liver

Oral administration of D-aspartate to mice for 2 weeks by addition of the amino acid to drinking water produced a nearly 4-fold increase in liver D-aspartate oxidase (EC 1.4.3.1) activity, whereas no increase was induced by L-aspartate administered in the same way. Administration of D-aspartate also produced a small significant increase in the kidney enzyme activity, but L-aspartate administration increased the activity as well. The enzyme activity in the brain and muscle was not affected by administration of either D- or L-aspartate. Intraperitoneal administration of D-aspartate increased the enzyme activity only in the liver, and other compounds tested, including D-glutamate and D-alanine, could not replace D-aspartate. The results indicate a specific relationship between D-aspartate and D-aspartate oxidase and suggest that the amino acid is, in fact, a physiological substrate of the enzyme.     

The aspartate aminotransferase-catalysed exchange of the alpha-protons of aspartate and glutamate: the effects of the R386A and R292V mutations on this exchange reaction.

1H-NMR was used to follow the aspartate aminotransferase-catalysed exchange of the alpha-protons of aspartate and glutamate. The effect of the concentrations of both the amino acids and the cognate keto acids on exchange rates was determined for wild-type and the R386A and R292V mutant forms of aspartate aminotransferase. The wild-type enzyme is found to be highly stereospecific for the exchange of the alpha-protons of L-aspartate and L-glutamate. The R386A mutation which removes the interaction of Arg-386 with the alpha-carboxylate group of aspartate causes an approximately 10,000-fold decrease in the first order exchange rate of the alpha-proton of L-aspartate. The R292V mutation which removes the interaction of Arg-292 with the beta-carboxylate group of L-aspartate and the gamma-carboxylate group of L-glutamate causes even larger decreases of 25,000- and 100,000-fold in the first order exchange rate of the alpha-proton of L-aspartate and L-glutamate respectively. Apparently both Arg-386 and Arg-292 must be present for optimal catalysis of the exchange of the alpha-protons of L-aspartate and L-glutamate, perhaps because the interaction of both these residues with the substrate is essential for inducing the closed conformation of the active site.     

Adriamycin-liposome interactions. A magnetic resonance study of the differential effects of cardiolipin on drug-induced fusion and permeability

L-Glutamate and L-aspartate transport into osmotically active intestinal brush border membrane vesicles is specifically increased by Na+ gradient (extravesicular greater than intravesicular) which in addition energizes the transient accumulation (overshoot) of the two amino acids against their concentration gradients. The "overshoot" is observed at minimal external Na+ concentration of 100 mM for L-glutamate and 60 mM for L-aspartate; saturation with respect to [Na+] was observed at a concentration near 100 mM for both amino acids. Increasing amino acid concentration, saturation of the uptake rate was observed for L-glutamate and L-aspartate in the concentration range between 1 and 2 mM. Experiments showing mutual inhibition and transtimulation of the two amino acids indicate that the same Na+ -dependent transport system is shared by the two acidic amino acids. The imposition of diffusion potentials across the membrane vesicles artificially induced by addition of valinomycin in the presence of a K+ gradient supports the conclusion that the cotransport Na+/dicarboxylic amino acid in rat brush border membrane vesicles is electroneutral.     

Increase of Na+ gradient-dependent L-glutamate and L-aspartate transport in high K+ dog erythrocytes associated with high activity of (Na+, K+)-ATPase

As reported previously, some dogs possess red cells characterized by low Na+, high K+ concentrations, and high activity of (Na+, K+)-ATPase, although normal dog red cells contain low K+, high Na+, and lack (Na+, K+)-ATPase. Furthermore, these red cells show increased activities of L-glutamate and L-aspartate transport, resulting in high accumulations of such amino acids in their cells. The present study demonstrated: (i) Na+ gradient-dependent L-glutamate and L-aspartate transport in the high K+ and low K+ red cells were dominated by a saturable component obeying Michaelis-Menten kinetics. Although no difference of the Km values was observed between the high K+ and low K+ cells, the Vmax values for both amino acids' transport in the high K+ cells were about three times those of low ones. (ii) L- and D-aspartate, but not D-glutamate, competitively inhibited L-glutamate transport in both types of the cells. (iii) Ouabain decreased the uptake of the amino acids in the high K+ dog red cells, whereas it was not effective on those in the low K+ cells. (iv) The ATP-treated high K+ cells [(K+]i not equal to [K+]o, [Na+]i greater than [Na+]o) showed a marked decrease of both amino acids' uptake rate, which was almost the same as that of the low K+ cells. (v) Valinomycin stimulated the amino acids' transport in both of the high K+ and the ATP-treated low K+ cells [( K+]i greater than [K+]o, [Na+]o), suggesting that the transport system of L-glutamate and L-aspartate in both types of the cells might be electrogenic. These results indicate that the increased transport activity in the high K+ dog red cells was a secondary consequence of the Na+ concentration gradient created by (Na+, K+)-ATPase.     

Pharmacology of putative glutamate receptors from insect skeletal muscles, insect central nervous system and rat brain

Binding of [3H]glutamate to housefly brain and honeybee brain and thoracic muscle membranes as well as to the American cockroach nerve cord was measured in Na+-free Tris-citrate buffer, 2.5 mM CaCl2, pH 7.4. The dissociation constants (KDS) ranged from 0.16 to 1.36 microM, and thoracic muscles had 2-4-fold higher density of receptors than brain tissue. The potent inhibitors of housefly brain binding were in decreasing order of effectiveness: L-glutamate greater than L-aspartate = L-cysteate = ibotenate greater than quisqualate greater than L-homocysteate greater than L-APB greater than L-APV greater than NMDA greater than D-APB greater than D-glutamate, with no inhibition by 100 microM of GDEE, dihydrokainate, D-APV, D-homocysteate or D-aspartate. The drug specificity of [3H]glutamate binding sites in housefly brain was generally similar to that of binding sites in housefly muscle, except that the former had a slightly higher affinity for L-APB, L-homocysteate and NMDA. [3H]Glutamate binding to insect tissues differed in its drug sensitivity from binding to rat brain. Binding to insect membranes was much less sensitive to L-APB, D-APB, APV, homocysteate, L-cysteate, quisqualate and ibotenate. However, the insect binding site was much more stereoselective for the L than D isomers of glutamate and aspartate, while the rat brain site was more stereoselective for APB. It is suggested that the observed [3H]glutamate binding to insect tissue is not to NMDA or kainate receptors.(ABSTRACT TRUNCATED AT 250 WORDS)     

Substrate-stereoselectivity of a high-affinity glutamate transporter cloned from the CNS of the cockroach Diploptera punctata

A cDNA encoding a Na(+)-dependent glutamate transporter has been cloned from the brain of the cockroach Diploptera punctata. The cDNA encodes a transporter protein of 481 amino acids, designated DipEAAT1, which when expressed in baculovirus infected insect cells, resulted in a 40-50 fold increase in [(3)H]L-glutamate uptake. DipEAAT1 mRNA is expressed in the brain, as is the RNA encoding TrnEAAT1, a related transporter recently isolated from the caterpillar Trichoplusia ni. The affinity of these transporters for L-glutamate and several structural analogues was compared. Both have a high affinity for L-glutamate, their presumed primary substrate, but quite different affinities for D-aspartate. TrnEAAT1 was found to be similar to other glutamate transporters in that its ability to transport [(3)H]L-glutamate into cells was inhibited strongly by D- and L- isomers of aspartate and its analogues. DipEAAT1, by contrast, was inhibited weakly by all D- isomers tested. The affinity of DipEAAT1 for [(3)H]D-aspartate was found to be an order of magnitude lower than that of TrnEAAT1, revealing an unusual stereoselectivity for aspartate substrates by the cockroach transporter. The activity of DipEAAT1 was also unaffected by the presence of Zn(++) in the bathing solution, despite the presence of a putative Zn(++)-binding motif conferring Zn(++)-sensitivity on some mammalian glutamate transporters.     

Selective potentiation of retinal horizontal cell responses to L-glutamate by D-aspartate

1. L-Glutamate and L-aspartate depolarize type H1 horizontal cells in the isolated retina of goldfish, but only at millimolar concentrations. 2. When applied in the presence of D-aspartate, L-glutamate depolarizes H1 cells at concentrations nearly 15-fold lower than when it is applied alone. The effects of L-aspartate were not potentiated by either D-aspartate or D-glutamate. 3. Since D-aspartate seems also to enhance the effect of the transmitter released by cone photoreceptors, these results are consistent with the possibility that L-glutamate is a neurotransmitter of cones.     

Regional Heterogeneity of L-Glutamate and L-Aspartate High-Affinity Uptake Systems in the Rat CNS

The high-affinity uptake of L-[3H]glutamate and L-[3H]aspartate into synaptosomes prepared from rat cerebral cortical, hippocampal, and cerebellar tissue was reduced by a number of structural analogues of L-glutamate and L-aspartate. threo-3-Hydroxy-L-aspartic acid was a more potent inhibitor of L-glutamate uptake than of L-aspartate uptake in the cerebral cortex, but not in the hippocampus or cerebellum. A similar pattern of selectivity was observed for cis-1-aminocyclobutane-1,3-dicarboxylic acid. Dihydrokainate was also more potent against L-glutamate than against L-aspartate in the cerebral cortex, but in the hippocampus, it was more potent against L-aspartate than against L-glutamate. By contrast, L-alpha-aminoadipate was significantly more potent in the cerebellum than in the cerebral cortex and hippocampus as an antagonist of both L-glutamate and L-aspartate. These results support other evidence that there is regional heterogeneity in acidic amino acid uptake sites and that the amino acids L-glutamate and L-aspartate may be taken up by a number of transport systems with overlapping substrate specificity but different inhibitor profiles.     

L-[3H]Glutamate Binding to Hippocampal Synaptic Membranes: Two Binding Sites Discriminated by Their Differing Affinities for Quisqualate

The excitatory glutamate analogs quisqualate and ibotenate were employed to distinguish multiple binding sites for L-[3H]glutamate on freshly prepared hippocampal synaptic membranes. The fraction of bound radioligand that was displaceable by 5 microM quisqualate was termed GLU A binding. That which persisted in the presence of 5 microM quisqualate, but was displaceable by 100 microM ibotenate, was termed GLU B binding. GLU A binding equilibrated within 5 min and remained unchanged for up to 80 min. GLU B binding appeared to equilibrate at least as rapidly, but incubation with ligand unmasked latent binding sites. Saturation binding curves were best fitted by single exponentials, which yielded KD values of about 200 nM (GLU A) and 1 microM (GLU B). On the average, GLU B binding sites were about twice as abundant in these membranes as were GLU A sites. Rapid freezing of the membranes, followed by storage at -26 degrees C and rapid thawing markedly diminished GLU A binding, but nearly tripled GLU B binding. Both site bound L-glutamate with 10-30 times the affinity of D-glutamate. The GLU A site also bound L-glutamate with about 10 times the affinity of L-aspartate and discriminated poorly between L- and D-aspartate. In contrast, the GLU B site bound L-aspartate with an affinity similar to that for L-glutamate, and with an order-of-magnitude greater affinity than D-aspartate. The structural specificities of the GLU A and GLU B binding sites suggest that these sites may correspond to receptors on hippocampal pyramidal cell dendrites that are activated by iontophoretically applied L-glutamate.     

D-Aspartate Uptake and Release in the Guinea Pig Spinal Cord After Partial Ablation of the Cerebral Cortex

This study attempts to determine if L-glutamate and L-aspartate may be transmitters of the guinea pig corticospinal tract. Unilateral ablations were made of the frontal and parietal neocortex which destroyed most of the motor and somatosensory areas in the right cerebral hemisphere. In lesioned animals, transverse sections of the cervical enlargement of the spinal cord (segments C6--T1) were stained to reveal degenerating fibers. Degeneration of axons first appeared 4 days after surgery, reached a maximum on the seventh day, and began to wane by the ninth day. The most prominent loss of axons appeared deep in the dorsal funiculus and in laminae IV-IX of the gray matter contralateral to the cortical lesion. Ipsilaterally, there was very sparse degeneration of fibers in the dorsal and ventral funiculi and in the spinal gray matter. The uptake and release of D-[3H]aspartate, a putative nonmetabolizable marker for L-glutamate and L-aspartate, were measured in dissected quadrants of the cervical enlargement taken from intact and lesioned animals. The uptake and the electrically evoked, Ca2+-dependent release of D-[3H]aspartate were depressed by 29-35% at 4 and 7 days after surgery, but only in tissue that was contralateral to the cortical ablation. The lesion had no effect on the uptake and release of exogenous gamma-[14C]aminobutyric acid, which were measured as indices of the postlesion integrity of neurons in the spinal gray matter. These findings suggest that the synaptic endings of corticospinal fibers probably mediate the uptake and release of D-[3H]aspartate and, therefore, may use L-glutamate and/or L-aspartate as a transmitter.     

Amino acid transport in the thermophilic anaerobe Clostridium fervidus is driven by an electrochemical sodium gradient.

Amino acid transport was studied in membranes of the peptidolytic, thermophilic, anaerobic bacterium Clostridium fervidus. Uptake of the negatively charged amino acid L-glutamate, the neutral amino acid L-serine, and the positively charged amino acid L-arginine was examined in membrane vesicles fused with cytochrome c-containing liposomes. Artificial ion diffusion gradients were also applied to establish the specific driving forces for the individual amino acid transport systems. Each amino acid was driven by the delta psi and delta mu Na+/F and not by the Z delta pH. The Na+ stoichiometry was estimated from the amino acid-dependent 22Na+ efflux and Na(+)-dependent 3H-amino acid efflux. Serine and arginine were symported with 1 Na+ and glutamate with 2 Na+. C. fervidus membranes contain Na+/Na+ exchange activity, but Na+/H+ exchange activity could not be demonstrated.