Na+-dependent high-affinity glutamate transport in macrophages

Excessive accumulation of glutamate in the CNS leads to excitotoxic neuronal damage. However, glutamate clearance is essentially mediated by astrocytes through Na+-dependent high-affinity glutamate transporters (excitatory amino acid transporters (EAATs)). Nevertheless, EAAT function was recently shown to be developmentally restricted in astrocytes and undetectable in mature astrocytes. This suggests a need for other cell types for clearing glutamate in the brain. As blood monocytes infiltrate the CNS in traumatic or inflammatory conditions, we addressed the question of whether macrophages expressed EAATs and were involved in glutamate clearance. We found that macrophages derived from human blood monocytes express both the cystine/glutamate antiporter and EAATs. Kinetic parameters were similar to those determined for neonatal astrocytes and embryonic neurons. Freshly sorted tissue macrophages did not possess EAATs, whereas cultured human spleen macrophages and cultured neonatal murine microglia did. Moreover, blood monocytes did not transport glutamate, but their stimulation with TNF-alpha led to functional transport. This suggests that the acquisition of these transporters by macrophages could be under the control of inflammatory molecules. Also, monocyte-derived macrophages overcame glutamate toxicity in neuron cultures by clearing this molecule. This suggests that brain-infiltrated macrophages and resident microglia may acquire EAATs and, along with astrocytes, regulate extracellular glutamate concentration. Moreover, we showed that EAATs are involved in the regulation of glutathione synthesis by providing intracellular glutamate. These observations thus offer new insight into the role of macrophages in excitotoxicity and in their response to oxidative stress.     

Na(+)-dependent AIB transport by neuroblastoma cells.

Na(+)-dependent amino isobutyric acid transport by two neuroblastoma cell lines with and without amplification of the oncogene N-myc is studied. Surprisingly, the contribution of system A is greater in the cell line showing no N-myc amplification. Preliminary data support a role for essential tyrosine and cysteine residues in the active center of the carriers, mainly in system A.     

Characteristics of Na(+)-dependent intestinal nucleoside transport in the pig

Since the capacity of nucleic acid digestion and absorption appears to be comparatively high in the pig, we investigated the properties of transport of (3)H-labelled nucleosides across the porcine intestinal brush border membrane (BBM) using BBM vesicles isolated from the small intestine of slaughter pigs. In the presence of a transmembrane Na(+) gradient, uridine, thymidine and guanosine transiently accumulated in the vesicular lumen beyond the equilibrium (60 min) value suggesting the presence of Na(+)/nucleoside cotransporters in the BBM. The findings of inhibitory studies are consistent with the presence of two Na(+)-dependent nucleoside transporters with overlapping substrate specificity, one for pyrimidine nucleosides (N2) and one for purine nucleosides (N1). Guanosine appeared to be a specific substrate for N1, while this applies to thymidine for N2. Transport of thymidine and guanosine were also inhibited by 2 mmol/l D-glucose and alpha-methyl-D-glucoside. The maximal transport capacity (V(max)) for Na(+)-dependent thymidine and guanosine transport were much higher than reported for other monogastric species. Unlike in other species tested, there was no proximal-to-distal gradient, neither in nucleoside transport activity nor in the inhibition of nucleoside transport by monosaccharides in the porcine small intestine. The high intestinal nucleoside transport activity may contribute to the high digestive capacity for nucleic acids in the pig.     

Mechanism of Na(+)-dependent citrate transport in Klebsiella pneumoniae.

Citrate transport via CitS of Klebsiella pneumoniae has been shown to depend on the presence of Na+. This transport system has been expressed in Escherichia coli, and uptake of citrate in E. coli membrane vesicles via this uptake system was found to be an electrogenic process, although the pH gradient is the main driving force for citrate uptake (M. E. van der Rest, R. M. Siewe, T. Abee, E. Schwartz, D. Oesterhelt, and W. N. Konings, J. Biol. Chem. 267:8971-8976, 1992). Analysis of the affinity constants for the different citrate species at different pH values of the medium indicates that H-citrate2- is the transported species. Since the electrical potential across the membrane is a driving force for citrate transport, this indicates that transport occurs in symport with at least three monovalent cations. Citrate efflux is stimulated by Na+ concentrations of up to 5 mM but inhibited by higher Na+ concentrations. Citrate exchange, however, is stimulated by all Na+ concentrations, indicating sequential events in which Na+ binds before citrate for translocation followed by a release of Na+ after release of citrate. CitS has, at pH 6.0 and in the presence of 5 mM citrate on both sides of the membrane, an apparent affinity (K(app)) for Na+ of 200 microM. The Na+/citrate stoichiometry was found to be 1. It is postulated that H-citrate2- is transported via CitS in symport with one Na+ and at least two H+ ions.     

Pyroglutamate stimulates Na+ -dependent glutamate transport across the blood-brain barrier

Regulation of Na(+)-dependent glutamate transport was studied in isolated luminal and abluminal plasma membranes derived from the bovine blood-brain barrier. Abluminal membranes have Na(+)-dependent glutamate transporters while luminal membranes have facilitative transporters. This organization allows glutamate to be actively removed from brain. gamma-Glutamyl transpeptidase, the first enzyme of the gamma-glutamyl cycle (GGC), is on the luminal membrane. Pyroglutamate (oxoproline), an intracellular product of GGC, stimulated Na(+)-dependent transport of glutamate by 46%, whereas facilitative glutamate uptake in luminal membranes was inhibited. This relationship between GGC and glutamate transporters may be part of a regulatory mechanism that accelerates glutamate removal from brain.     

Na(+)-dependent fructose transport via rNaGLT1 in rat kidney

We found a system of Na(+)-dependent uptake of fructose by rat renal brush-border membrane vesicles. It consisted of two saturable components, and was thought to involve at least two transporters. rNaGLT1, a novel glucose transporter in rat kidney, showed fructose uptake as well as alpha-methyl-D-glucopyranoside uptake by transfected HEK293 cells. The features of the lower affinity type of fructose transporter in the brush-border membranes, such as affinity and substrate recognition, were very comparable with those of rNaGLT1-transfected HEK293 cells. These results indicated that rNaGLT1 is a primary fructose transporter in rat renal brush-border membranes.     

Na(+)-dependent, active and Na(+)-independent, facilitated transport of formycin B in mouse spleen lymphocytes

Na(+)-dependent, active and Na(+)-independent facilitated nucleoside transport were characterized in mouse spleen cells using rapid kinetic techniques and formycin B, a metabolically inert analog of inosine, as substrate. The Michaelis-Menten constants for formycin B transport by the two transporters were about 30 and 400 microM, respectively. The first-order rate constant for Na(+)-dependent transport was about 4-times higher than that for facilitated formycin B transport. The Na(+)-dependent carrier is specific for uridine and purine nucleosides and accumulates formycin B concentratively in an unmodified form. Concentrative accumulation was inhibited by ATP depletion and gramicidin and ouabain treatment of the cells. Our data indicate a single Na(+)-binding site on the Na(+)-dependent nucleoside carrier and a Michaelis-Menten constant for Na+ of about 10 mM. This transporter was not significantly inhibited by dipyridamole and nitrobenzylthioinosine, inhibitors of the facilitated transporter. The Na(+)-independent, facilitated nucleoside transporter of spleen cells exhibits properties comparable to those of the carriers present in mammalian cells in general. The B lymphocytes remaining after depletion of spleen cell populations of T lymphocytes by incubation with a combination of T-cell specific monoclonal antibodies plus complement exhibited about the same activities of active and facilitated nucleoside transport as the original suspension.     

Na(+)-dependent transport of anionic amino acids by preimplantation mouse blastocysts.

Negatively charged amino acids, such as aspartate and glutamate, were selected as substrates by low- and high-Km components of mediated Na(+)-dependent transport in preimplantation mouse blastocysts. These and other relatively small anionic amino acids with two carbon atoms between the negatively charged groups (or up to three carbon atoms when the groups were both carboxyl groups) interacted strongly with the low-Km component of transport, whereas larger anionic amino acids interacted weakly or not at all. The low-Km system was also stereoselective except in the case of aspartate. Moreover, transport was Cl(-)-dependent and slower at pH values outside the range 5.6-7.4. L-Aspartate, D-aspartate and L-glutamate each interacted strongly with the low-Km component of transport with Km values for transport nearly equal to their Ki values for inhibition of transport of one of the other amino acids. By these criteria, the low-Km component of transport of anionic amino acids in blastocysts appears to be the same as the familiar system X-AG that is present in other types of mammalian cells. In contrast, the high-Km component of transport in blastocysts preferred L-aspartate to L-glutamate, whereas the reverse is true for fibroblasts. Therefore, transport of anionic amino acids in blastocysts may occur via at least one process that has not been described in other types of cells. Roughly half of mediated glutamate and aspartate transport in blastocysts may occur via the high-Km component of transport at the concentrations of these amino acids that may be present in uterine secretions.     

Electrophysiological study of L-lysine transport across Triturus proximal tubule: evidence for Na(+)-independent entry and Na(+)-dependent exit.

Cell membrane depolarization induced by intraluminal injection of lysine was entirely independent of the presence of Na+ in Triturus proximal tubule, confirming our previous observation. The amplitude of the depolarization conformed to Michaelis-Menten kinetics regardless of the presence or absence of Na+ in the perfusion solutions. pH of the intraluminal solution had no effect on the electrical response in its range from 5.5 to 8.5. In a Na(+)-free medium, particularly in a Tris-substituted medium, the depolarization induced by a constant concentration of lysine gradually decreased in its size when injection followed by washout of lysine was repetitively tested. The addition of Na+ to the peritubular side after extinction of the responsiveness resulted in a significant restoration of the voltage response to intraluminal lysine. In addition, influx of Na+ from the peritubular fluid into the cells was significantly greater in lysine-loaded tubules than in nonloaded tubules as indicated by a greater rate of increase in intracellular Na+ activity in the presence of ouabain. The data strongly suggest that lysine enters the cells via an electrogenic uniport mechanism and leaves the cells via Na+:amino acid exchange transport mechanism.     

Amyloid beta-peptide inhibits Na+-dependent glutamate uptake

The purpose of this review is to summarize much of the work on the inhibition of the astroglial glutamate transporter in relation to excitotoxic neurodegeneration, in particular, inhibition of uptake by the beta-amyloid peptide (A beta) found in the Alzheimer's disease (AD) brain. There is evidence for oxidative stress in the AD brain, and A beta has been found to generate reactive oxygen species (ROS), thus adding to the stress or possibly initiating it. The oxidative inhibition of the glutamate transporter protein by A beta increases the vulnerability of glutamatergic neurons, and by rendering them susceptible to the excitotoxic insult that results from impaired glutamate uptake, A beta can be directly connected to the neurodegeneration that follows.     

Kinetics of Na(+)-dependent conformational changes of rabbit kidney Na+,K(+)-ATPase.

The kinetics of Na(+)-dependent partial reactions of the Na+,K(+)-ATPase from rabbit kidney were investigated via the stopped-flow technique, using the fluorescent labels N-(4-sulfobutyl)-4-(4-(p-(dipentylamino)phenyl)butadienyl)py ridinium inner salt (RH421) and 5-iodoacetamidofluorescein (5-IAF). When covalently labeled 5-IAF enzyme is mixed with ATP, the two labels give almost identical kinetic responses. Under the chosen experimental conditions two exponential time functions are necessary to fit the data. The dominant fast phase, 1/tau 1 approximately 155 s-1 for 5-IAF-labeled enzyme and 1/tau 1 approximately 200 s-1 for native enzyme (saturating [ATP] and [Na+], pH 7.4 and 24 degrees C), is attributed to phosphorylation of the enzyme and a subsequent conformational change (E1ATP(Na+)3-->E2P(Na+)3 + ADP). The smaller amplitude slow phase, 1/tau 2 = 30-45 s-1, is attributed to the relaxation of the dephosphorylation/rephosphorylation equilibrium in the absence of K+ ions (E2P<==>E2). The Na+ concentration dependence of 1/tau 1 showed half-saturation at a Na+ concentration of 6-8 mM, with positive cooperatively involved in the occupation of the Na+ binding sites. The apparent dissociation constant of the high-affinity ATP-binding site determined from the ATP concentration dependence of 1/tau 1 was 8.0 (+/- 0.7) microM. It was found that P3-1-(2-nitrophenyl)ethyl ATP, tripropylammonium salt (NPE-caged ATP), at concentrations in the hundreds of micromolar range, significantly decreases the value of 1/tau 1, observed. This, as well as the biexponential nature of the kinetic traces, can account for previously reported discrepancies in the rates of the reactions investigated.     

The regulation of Na(+)-dependent anionic amino acid transport by the rat mammary gland.

The regulation of anionic amino acid transport, using radiolabelled D-aspartate as a tracer, by rat mammary tissue explants has been examined. Na(+)-dependent D-aspartate uptake by mammary tissue increased between late pregnancy and early lactation and again at peak lactation but thereafter declined during late lactation. In contrast, the Na(+)-independent component of D-aspartate uptake by mammary explants did not change significantly with the physiological state of the donor animals. Premature weaning of rats during peak lactation markedly decreased Na(+)-dependent D-aspartate uptake by mammary tissue. In addition, premature weaning also reduced the effect of reversing the trans-membrane Na(+)-gradient on the fractional loss of D-aspartate from mammary tissue explants. Unilateral weaning of rats during peak lactation revealed that milk accumulation per se reduced the Na(+)-dependent moiety of D-aspartate uptake by mammary tissue suggesting that the transport of anionic amino acids is regulated to match supply with demand. Treating lactating rats with bromocryptine reduced D-aspartate uptake by mammary tissue explants suggesting that the transport of anionic amino acids by the rat mammary gland is regulated by prolactin.     

Na(+)-dependent D-mannose transport at the apical membrane of rat small intestine and kidney cortex

The presence of a Na(+)/D-mannose cotransport activity in brush-border membrane vesicles (BBMV), isolated from either rat small intestine or rat kidney cortex, is examined. In the presence of an electrochemical Na(+) gradient, but not in its absence, D-mannose was transiently accumulated by the BBMV. D-Mannose uptake into the BBMV was energized by both the electrical membrane potential and the Na(+) chemical gradient. D-Mannose transport vs. external D-mannose concentration can be described by an equation that represents a superposition of a saturable component and another component that cannot be saturated up to 50 microM D-mannose. D-Mannose uptake was inhibited by D-mannose > D-glucose>phlorizin, whereas for alpha-methyl glucopyranoside the order was D-glucose=phlorizin > D-mannose. The initial rate of D-mannose uptake increased as the extravesicular Na(+) concentration increased, with a Hill coefficient of 1, suggesting that the Na(+):D-mannose cotransport stoichiometry is 1:1. It is concluded that both rat intestinal and renal apical membrane have a concentrative, saturable, electrogenic and Na(+)-dependent D-mannose transport mechanism, which is different from SGLT1.     

Electrogenic Na(+)-dependent L-alanine transport in the lizard duodenum. Involvement of systems A and ASC

L-Alanine transport across the isolated duodenal mucosa of the lizard Gallotia galloti has been studied in Ussing chambers under short-circuit conditions. Net L-alanine fluxes, transepithelial potential difference (PD), and short-circuit current (Isc) showed concentration-dependent relationships. Na(+)-dependent L-alanine transport was substantially inhibited by the analog alpha-methyl aminoisobutyric acid (MeAIB). Likewise, MeAIB fluxes were completely inhibited by L-alanine, indicating the presence of system A for neutral amino acid transport. System A transport activity was electrogenic and exhibited hyperbolic relationships for net MeAIB fluxes, PD, and Isc, which displayed similar apparent K(m) values. Na(+)-dependent L-alanine transport, but not MeAIB transport, was partially inhibited by L-serine and L-cysteine, indicating the participation of system ASC. This transport activity represents the major pathway for L-alanine absorption and seemed to operate in an electroneutral mode with a negligible contribution to the L-alanine-induced electrogenicity. It is concluded from the present study that the active Na(+)-dependent L-alanine transport across the isolated duodenal mucosa of Gallotia galloti results from the independent activity of systems A and ASC for neutral amino acid transport.     

Na(+)- and H(+)-dependent motility in the coral pathogen Vibrio shilonii

In this work, we analyzed motility and the flagellar systems of the marine bacterium Vibrio shilonii. We show that this bacterium produces lateral flagella when seeded on soft agar plates at concentrations of 0.5% or 0.6%. However, at agar concentrations of 0.7%, cells become round and lose their flagella. The sodium channel blocker amiloride inhibits swimming of V. shilonii with the sheathed polar flagellum, but not swarming with lateral flagella. We also isolated and characterized the filament–hook–basal body of the polar flagellum. The proteins in this structure were analyzed by MS. Eight internal sequences matched with known flagellar proteins. The comparison of these sequences with the protein database from the complete genome of V. shilonii allows us to conclude that some components of the polar flagellum are encoded in two different clusters of flagellar genes, suggesting that this bacterium has a complex flagellar system, more complex possibly than other Vibrio species reported so far.     

Ca2(+)-dependent glucose transport in chicken intestine

Transport of glucose was measured in the intestine of white leghorn layers in vivo using ligated upper small intestinal segment in the presence of Ca2+ and other ions either singly or in combination. Transport of glucose across the intestine was very significantly increased with Ca2+ than Na+, K+ and Po4(3-) individually, but when Ca2+ was combined with Na+, K+ and PO4(3-), the glucose absorption increased significantly over that achieved by Na+ ions alone. These data revealed that Ca2+ ions might be exerting the major influence on glucose transport processes of the chicken intestine.