Development of system B0,+ and a broad-scope Na(+)-dependent transporter of zwitterionic amino acids in preimplantation mouse conceptuses

The nature and ontogeny of Na(+)-dependent L-alanine transport was examined in mouse eggs and preimplantation conceptuses. Mediated L-alanine uptake was not detected in fertilized or unfertilized eggs, but a small amount of Na(+)-dependent L-alanine transport was detected in 2-cell conceptuses. Na(+)-dependent alanine transport was more rapid at the 8-cell stage of development, and more than 10-fold faster in blastocysts than in 8-cell conceptuses. Analog inhibition analyses were consistent with the interpretation that L-lysine-sensitive and L-lysine-resistant components of transport were present at the 2-cell, 8-cell and blastocyst stages of development. The range of amino acids and their analogs that inhibited the most conspicuous component of alanine transport in blastocysts was consistent with the conclusion that system B0,+ is largely responsible for L-alanine uptake in these conceptuses. Moreover, system B0,+, but not other known systems in blastocysts, became susceptible to activation as these conceptuses approached the time of implantation, so this activation could be involved in implantation. Although the data are consistent with the possibility that system B0,+ is also present in 2-cell and 8-cell conceptuses, the relatively slow L-alanine transport in conceptuses at these earlier stages of development precluded more detailed study of their ability to take up alanine. Similarly, the less conspicuous L-lysine-resistant component of L-alanine transport in blastocysts also may be present in conceptuses as early as the 2-cell stage. The L-lysine-resistant component of L-alanine transport could not be attributed to residual system B0,+ activity, however, because it was inhibited more strongly by trans-OH-L-proline than L-arginine, whereas the reverse was the case for system B0,+. Similarly, L-tryptophan and L-leucine each inhibited system B0,+ more strongly than L-serine or L-cysteine, whereas all four of these amino acids inhibited the L-lysine-resistant component equally well. Moreover, a Hofstee plot for L-alanine influx was consistent with the interpretation that at least two mediated components of Na(+)-dependent L-alanine transport are present in blastocysts. The less conspicuous component of L-alanine transport in blastocysts was relatively susceptible to inhibition by L-leucine and L-tryptophan, but it resisted inhibition by the 'model' system A substrate, MeAIB, and the system ASC inhibitors, L-penicillamine and cationic amino acids.(ABSTRACT TRUNCATED AT 400 WORDS)     

Aspartate and glutamate transport in unfertilized pig oocytes and blastocysts

Amino acid transport is facilitated by specific transporters within the plasma membrane of the cell. Mediated Na⁺-independent transport of L-glutamate can be easily detected in mouse oocytes, but it is nearly undetectable in blastocyst-stage embryos. In contrast, the Na⁺-dependent transport of L-aspartate is not detectable in oocytes, but it is detectable in eight-cell embryos and reaches relatively high levels by the blastocyst stage. It is believed that the amino acid transporters responsible are systems x^?_c and X^?_AG, respectively. Here we report the detection of Na⁺-dependent L-aspartate transport, which increased as pig blastocysts developed, although Na⁺-dependent aspartate transport was not detected in pig oocytes. Mediated Na⁺-independent L-glutamate transport was not detected in pig oocytes, in contrast to the mouse, nor in early or hatched pig blastocysts. Thus, while the developmental regulation of system X^?_AG is similar in both the pig and the mouse, system x^?_c was not detectable in pig oocytes or blastocysts. Elucidation of the molecular mechanisms controlling amino acid transport and other gene expression in early embryos should contribute to an understanding of whether and even why some aspects of developmental regulation of gene expression may need to differ among species. © 1993 Wiley-Liss, Inc.     

Transport and membrane binding of the glutamine analogue 6-diazo-5-oxo-L-norleucine (DON) in Xenopus laevis oocytes

Summary We have examined transport and membrane binding of 6-diazo-5-oxo-l-norleucine (DON, a photoactive diazo-analogue of glutamine) and their relationships to glutamine transport in Xenopus laevis oocytes. DON uptake was stereospecific and saturable (V _max of 0.44 pmol/oocyte · min and a K _m of 0.065 mm). DON uptake was largely Na^u+ dependent (80% at 50 m DON) and inhibited (>75%) by glutamine and arginine (substrates of the System B^0,+ transporter) at 1 mm. Glutamine and DON show mutual competitive inhibition of Na⁺-dependent transport. Preincubation of oocytes in medium containing 0.1 mm DON for 24 or 48 hr depressed the V _max for System B^0,+ transport (as measured by Na⁺-dependent glutamine uptake), this effect was highly specific (neither d-DON nor the System B^0,+ substrates glutamine and d-alanine showed any independent effect) and required Na⁺ ions. Glutamine (1 mm in preincubation medium) protected transport from inhibition by DON. The possibility that specific inactivation of System B^0,+ by DON reflects attachment of DON to the transporter was tested by examining the binding of [¹⁴C]DON to Xenopus oocyte membranes. Oocytes incubated in 100 mm NaCl in the presence of [¹⁴C]DON for up to 48 hr showed 2.4-fold higher ¹⁴C-binding to membranes than oocytes incubated in choline chloride. Na⁺-dependent DON binding (31 ± 11 fmol/g membrane protein) was suppressed by external glutamine, arginine or alanine and was largely confined to a membrane protein fraction of 48–65 kDa (as assessed by SDS-polyacrylamide gel electrophoresis). The present studies indicate that DON and glutamine uptake in oocytes are both mediated by System B^0,+ and demonstrate that DON binding to a particular membrane protein fraction is associated with inactivation of the transporter, offering the prospect of using [¹⁴C]DON as a covalent label for the transport protein in order to facilitate its isolation and subsequent biochemical characterization.This work was supported by The Wellcome Trust, Action Research for the Crippled Child, Ajinomoto GmbH, Pfrimmer GmbH, the Rank Prize Funds, the Medical Research Council and the University of Dundee. We are grateful to Dr. C.I. Pogson (Wellcome Research Laboratories) and Drs. J.C. Ellory and B. Elford (University of Oxford) for gifts of [¹⁴C]DON.     

Transport of benzenoid amino acids by system T and four broad scope systems in preimplantation mouse conceptuses

We have studied transport of L-tryptophan, L-tyrosine and L-phenylalanine as factors contributing to homeostasis of these amino acids in preimplantation mouse conceptuses. Benzenoid amino acids were transported by the Na(+)-independent systems L and b0,+ in 1-cell conceptuses, and by these systems plus the Na(+)-dependent systems B0,+ and B in blastocysts. In addition, a component of Na(+)-independent tryptophan, tyrosine and phenylalanine transport in 1-cell and 2-cell conceptuses and in blastocysts resisted inhibition by L-leucine. The latter component of transport not only preferred benzenoid amino acids and in particular tryptophan as substrates, but it also was inhibited strongly and competitively by alpha-N-methyl-L-tryptophan. The leucine-resistant component of tryptophan transport also was inhibited strongly by N-ethylmaleimide and D-tryptophan, and it appeared to be inhibited weakly by 3-amino-endo-bicyclo[3.2.1]octane-3-carboxylic acid (BCO) but not by other amino acids tested as inhibitors. By these criteria, the leucine-resistant component of transport of benzenoid amino acids resembled system T in human red blood cells and rat hepatocytes. It is not entirely clear why preimplantation blastocysts have five good systems for transport of tryptophan. It is possible, however, that tryptophan homeostasis is particularly important during preimplantation development since it has been shown elsewhere that tryptophan availability in blood increases within one day after rat eggs are fertilized.     

Parallel regulation of arginine transport and nitric oxide synthesis by angiotensin II in vascular smooth muscle cells role of protein kinase C

Summary Experiments were performed to characterize arginine transport in vascular smooth muscle cells (SMCs) and the effect of angiotensin II (Ang II) on this process. In addition, the role of arginine transport in the cytokineinduced nitric oxide (NO) production was assessed. Arginine transport takes place through Na⁺-independent (60%) and Na⁺-dependent pathways (40%). The Na⁺-independent arginine uptake appears to be mediated by system y⁺ because of its sensitivity to cationic amino acids such as lysine, ornithine and homoarginine. The transport system was relatively insensitive to acidification of the extracellular medium. By contrast, the Na⁺-dependent pathway is consistent with system B^0,+ since it was inhibited by both cationic and neutral amino acids (i.e., glutamine, phenylalanine, and asparagine), and did not accept Li⁺ as a Na⁺ replacement. Treatment of SMCs with 100nM Ang II significantly inhibited the Na⁺-dependent arginine transport without affecting systems y⁺, A, and L. This effect occurred in a dose-dependent manner (IC₅₀ of 8.9 ± 0.9nM) and is mediated by the AT-1 receptor subtype because it was blocked by DUP 753, a non-peptide antagonist of this receptor. The inhibition of system B^0,+ by Ang II is mediated by protein kinase C (PKC) because it was mimicked by phorbol esters (phorbol 12-myristate 13-acetate) and was inhibited by staurosporine. Ang II also inhibited the IL-1 induced nitrite accumulation by SMCs. This action was also inhibited by staurosporine and reproduced with phorbol esters, suggesting a coupling between arginine uptake and NO synthesis through a PKC-dependent mechanism. However, arginine supplementation in the medium (10mM) failed to prevent the inhibitory action of Ang II on NO synthesis. These findings suggest that although Ang II inhibits concomitantly arginine transport and NO synthesis in SMCs, the reduction of NO synthesis is not associated with alterations in the cellular transport of arginine.Abbreviations Arg arginine - Orn ornithine - HmR homoarginine - Lys lysine - Gln glutamine - Asn asparagine - His histidine - Phe phenylalanine - Leu leucine - Cys Cysteine - Ala alanine - Ser serine - Thr threonine - Glu glutamate - mAIB -methyl-aminoisobutyric acid - BCH bicycloaminoheptane     

Transport of glutamine inXenopus laevis oocytes: Relationship with transport of other amino acids

Summary We have investigated transport of the amino acid glutamine across the surface membranes of prophase-arrestedXenopus laevis oocytes. Glutamine accumulation was linear with time for 30 min; it was stereospecific with aK _m of 0.12±0.02mm andV _max of 0.92±0.17 pmol/oocyte · min forl-glutamine. Transport ofl-glutamine was Na⁺-dependent, the cation not being replaceable with Li⁺, K⁺, choline, tris(hydroxymethyl)-aminomethane (Tris), tetramethylammonium (TMA) or N-methyld-glucamine NMDG); external Cl^– appeared to be necessary for full activation of Na⁺-dependent glutamine transport. Two external Na⁺ may be required for the transport of one glutamine molecule.l-glutamine transport (at 50 m glutamine) was inhibited by the presence of other amino acids:l-alanine,d-alanine,l-leucine,l-asparagine andl-arginine (about 60% inhibition at 1mm);l-histidine,l-valine and glycine (25 to 40% inhibition at 1mm);l-serine,l-lysine,l-phenylalanine andl-glutamate (45 to 55% inhibition at 10mm). N-methylaminoisobutyric acid (meAIB) had no effect at 10mm, but 2-aminobicyclo[2,2,1]heptane-2-carboxylic acid (BCH) inhibited Na⁺/glutamine transport by about 50% at 10mm.l-glutamine was a competitive inhibitor of the Na⁺-dependent transport ofl-alanine,d-alanine andl-arginine; this evidence is consistent with the existence of a single system transporting all four amino acids. Glutamine uptake in oocytes appears to be catalyzed by a transport system distinct from the cotransport Systems A, ASC, N and Gly, although it resembles System B^0,+.     

A polarized localization of amino acid/carnitine transporter B(0,+) (ATB(0,+)) in the blood-brain barrier

Brain capillary endothelial cells control the uptake and efflux from the brain of many hydrophilic compounds due to highly specialized transporters often localized in a polarized way. Localization of Na⁺- and Cl⁻-dependent amino acid and carnitine transporter B^0,+ (ATB^0,+) was studied in a co-culture of bovine brain capillary endothelial cells (BBCEC) grown on filters above astrocytes (an in vitro blood-brain barrier model). Immunoblotting and three-dimensional immunocytochemistry analysis with anti-B^0,+antibodies demonstrated the presence of this transporter and its prevalent co-localization with P-glycoprotein i.e. at the apical side. The sensitivity of leucine uptake through the apical membrane to 2-aminobicyclo-[2.2.1]-heptane-2-carboxylic acid (BCH), d-serine as well as sodium and chloride replacement confirm the functioning of ATB^0,+ and suggests an important physiological role of ATB^0,+ in controlling the delivery of amino acids and carnitine to the brain.     

Changes in the activities of amino acid transport systems b0,+ and L during development of preimplantation mouse conceptuses

Uptake of leucine, lysine, and arginine was predominantly Na(+)-independent in mouse conceptuses through the 8-cell stage of development, and two components of saturable transport were detected for each of these amino acids. Uptake of cationic substrates from solutions near 1 microM was inhibited most strongly by bulky cationic and zwitterionic amino acids whose carbon skeletons do not branch at the alpha or beta positions. By this criterion, system b0,+ accounted for most of the Na(+)-independent arginine and lysine transport in eggs and conceptuses throughout preimplantation development. A small, leucine-resistant, cation-preferring component of amino acid transport was also detected in these cells. Leucine uptake was inhibited most strongly by bicyclic, branched-chain or benzenoid, zwitterionic amino acids in eggs and conceptuses prior to formation of blastocysts. Therefore, it appeared to be taken up mainly by system L, while system b0,+ accounted for a smaller portion of leucine uptake during this developmental period. In blastocysts, in contrast, system L was less conspicuous, and system b0,+ was primarily responsible for Na(+)-independent leucine uptake. The Vmax values for transport of amino acids by system b0,+ increased by up to 30-fold in conceptuses between the 1-cell and blastocyst stages. In contrast, the Vmax value for leucine transport via system L decreased while the Km value increased between these two developmental stages. Although several explanations for these changes are possible, we favor the hypothesis that the density of system L transport sites in plasma membranes decreases while the number of system b0,+ sites increases during development of blastocysts from 1-cell conceptuses.     

Characterisation and cloning of a Na-dependent broad-specificity neutral amino acid transporter from NBL-1 cells: a novel member of the ASC/B transporter family

Na⁺-dependent neutral amino acid transport into the bovine renal epithelial cell line NBL-1 is catalysed by a broad-specificity transporter originally termed System B⁰. This transporter is shown to differ in specificity from the B⁰ transporter cloned from JAR cells [J. Biol. Chem. 271 (1996) 18657] in that it interacts much more strongly with phenylalanine. Using probes designed to conserved transmembrane regions of the ASC/B⁰ transporter family we have isolated a cDNA encoding the NBL-1 cell System B⁰ transporter. When expressed in Xenopus oocytes the clone catalysed Na⁺-dependent alanine uptake which was inhibited by glutamine, leucine and phenylalanine. However, the clone did not catalyse Na⁺-dependent phenylalanine transport, again as in NBL-1 cells. The clone encoded a protein of 539 amino acids; the predicted transmembrane domains were almost identical in sequence to those of the other members of the B⁰/ASC transporter family. Comparison of the sequences of NBL-1 and JAR cell transporters showed some differences near the N-terminus, C-terminus and in the loop between helices 3 and 4. The NBL-1 B⁰ transporter is not the same as the renal brush border membrane transporter since it does not transport phenylalanine. Differences in specificity in this protein family arise from relatively small differences in amino acid sequence.     

Changes in alanine and glutamine transport during rat red blood cell maturation

Alanine and glutamine transport have been studied during red blood cell maturation in the rat. Kinetic parameters of Na⁺-dependent L-alanine transport were:K _m 0.43 and 1.88 mM andV _max 158 and 45 nmoles/ml ICW/min for reticulocytes and erythrocytes, respectively. During red cell maturation in the rat there is a loss of capacity and affinity of the system ASC for L-alanine transport. The values for Na⁺-dependent L-glutamine transport in reticulocytes wereK _m 0.51 mM andV _max 157 nmoles/ml ICW/min. On the other hand, a total loss of L-glutamine transport mediated by both N and ASC systems is demonstrated in mature red cells. This seems to indicate that during rat red cell maturation the system N disappears. Furthermore, the system ASC specificity in mature cells changes, and glutamine enters the red cell by non-mediated diffusion processes.     

Adaptation to phosphate deprivation in osteoblast-like cells

The rat osteosarcoma cell line UMR-106–01 has an osteoblast-like phenotype. When grown in monolyer culture these cells transport inroganic phosphate and L-alanine via Na⁺-dependent transport systems. Exposure of these cells to a low phosphate medium for 4 h produced a 60–70 per cent increase in Na⁺-dependent phosphate uptake compared to control cells maintained in medium with a normal phosphate concentration. In contrast, Na⁺-dependent alanine uptake and Na⁺-independent phosphate uptake were not changed during phosphate deprivation. The increased phosphate uptake was due, in part, to an increased V_max and was blocked completely by pretreatment with cycloheximide (70 μM). In these cells recovery of intracellular pH after acidification with NH₄Cl is due primarily to the Na⁺/H⁺ exchange system. The rate of this recovery process, monitored with a pH sensitive indicator (BCECF), was decreased by more than 50 per cent in phosphate-deprived cells compared to controls indicating that Na⁺/H⁺ exchange was inhibited during phosphate deprivation.     

Estrogen regulation and ion dependence of taurine uptake by MCF-7 human breast cancer cells

It has been reported that estrogen receptor-positive MCF-7 cells express TauT, a Na⁺-dependent taurine transporter. However, there is a paucity of information relating to the characteristics of taurine transport in this human breast cancer cell line. Therefore, we have examined the characteristics and regulation of taurine uptake by MCF-7 cells. Taurine uptake by MCF-7 cells showed an absolute dependence upon extracellular Na⁺. Although taurine uptake was reduced in Cl^- free medium a significant portion of taurine uptake persisted in the presence of NO₃ ^-. Taurine uptake by MCF-7 cells was inhibited by extracellular β-alanine but not by L-alanine or L-leucine. 17β-estadiol increased taurine uptake by MCF-7 cells: the V_max of influx was increased without affecting the K_m. The effect of 17β-estradiol on taurine uptake by MCF-7 cells was dependent upon the presence of extracellular Na⁺. In contrast, 17β-estradiol had no significant effect on the kinetic parameters of taurine uptake by estrogen receptor-negative MDA-MB-231 cells. It appears that estrogen regulates taurine uptake by MCF-7 cells via TauT. In addition, Na⁺-dependent taurine uptake may not be strictly dependent upon extracellular Cl^-.     

Endogenousd-glucose transport in oocytes ofXenopus laevis

Summary Endogenous glucose uptake by the oocytes ofXenopus laevis consists of two distinct components: one that is independent of extracellular Na⁺, and the other one that represents Na⁺-glucose cotransport. The latter shows similar characteristics as 2 Na⁺-1 glucose cotransport of epithelial cells: The similarities include the dependencies on external concentrations of Na⁺, glucose, and phlorizin, and on pH. As in epithelial cells, the glucose uptake in oocytes can also be stimulated by lanthanides. Both the electrogenic cotransport and the inhibition by phlorizin are voltage-dependent; the data are compatible with the assumption that the membrane potential acts as a driving force for the reaction cycle of the transport process. In particular, hyperpolarization seems to stimulat transport by recruitment of substrate binding sites to the outer membrane surface. The results described pertain to oocytes arrested in the prophase of the first meiotic division; maturation of the oocytes leads to a downregulation of both the Na⁺-independent and the Na⁺-dependent transport systems. The effect on the Na⁺-dependent cotransport is the consequence of a change of driving force due to membrane depolarization associated with the maturation process.     

Transport of cationic and zwitterionic amino acids in preimplantation rat conceptuses

The ability of preimplantation rat conceptuses to take up several amino acids was examined under a variety of conditions, and the characteristics of uptake were compared to those determined previously for mouse conceptuses. Mediated leucine transport in two-cell rat conceptuses is Na(+)-independent and inhibited almost completely by 2-amino-endobicyclo[2.2.1]heptane-2-carboxylic acid (BCH), so it resembles system L which predominates in two-cell mouse conceptuses. System L becomes less conspicuous than homoarginine-sensitive, Na(+)-independent leucine transport (provisionally designated system bo,+) by the time rat conceptuses develop into blastocysts, as is also the case for mouse conceptuses. In contrast to leucine transport, system bo,+ appears to be the most conspicuous transporter of cationic amino acids throughout preimplantation development of both species. A Na(+)-independent cation-preferring amino acid transport process also appears to be present in rat as well as in mouse conceptuses. Moreover, rat conceptuses resemble mouse conceptuses because Na(+)-dependent transport system Gly activity virtually disappears from them by the time they form blastocysts. Unlike mouse conceptuses, however, Na(+)-dependent system Bo,+ activity appears to be present throughout preimplantation development of rat conceptuses, whereas it has not been detected until at least the two-cell stage in the mouse. Although system Bo,+ becomes more conspicuous in mouse than in rat conceptuses by the time they form blastocysts, system Bo,+ activity appears to increase when blastocysts of both species are removed from the uterus just prior to implantation. The latter observation is consistent with the possibility that system Bo,+ activity is controlled, in part, by the uterus near the time of implantation, although further studies are needed to verify this possibility. Similarities as well as differences in the amino acid transport processes present in conceptuses of rats and mice may eventually be understood best in relation to the environments in which they develop in vitro and in situ.     

Glycine transport in mouse eggs and preimplantation conceptuses

At least two Na+-dependent systems for glycine transport became detectable, while another became undetectable during preimplantation development of mouse conceptuses. Glycine was taken up by a process in eggs and cleavage-stage conceptuses which closely resembles system Gly. Mediated transport at these stages was more rapid at higher Cl- concentrations, sigmoidally related to the exogenous Na+ concentration, and strongly inhibited by sarcosine but not by amino acids with larger side chains. Moreover, neither Li+ nor choline could substitute for Na+ in stimulating glycine transport. System Gly was the only mediated process detected for glycine uptake in unfertilized and fertilized eggs and two-cell conceptuses, but two, less conspicuous, sarcosine-resistant, Na+-dependent components of transport also appeared to be present in eight-cell conceptuses. One of the latter components seemed to remain relatively inconspicuous when conceptuses formed blastocysts, while system Gly became undetectable. In contrast, the other less conspicuous component in eight-cell conceptuses appeared to become the most conspicuous transport process in blastocysts. The latter process, previously designated system B0,+, was shown here also to interact strongly with a broad scope of zwitterionic and cationic amino acid structures. Moreover, transport of glycine via system B0,+ was more rapid at higher Cl- concentrations, and this Na+-dependent process as well as Na+-independent leucine uptake were inhibited by choline. Furthermore, Na+-dependent amino acid transport in two-cell conceptuses and blastocysts was inhibited by 1.0 or 10 mM ouabain, but the inhibition was incomplete at both concentrations. Since Na+/K+-ATPase has not been detected in two-cell conceptuses, inhibition of amino acid transport by ouabain may not have been due solely to an effect on this enzyme. The level of system Gly activity decreased during the development of eight-cell conceptuses from eggs, and this decrease could contribute to an associated decline in intracellular glycine. Since other amino acids begin to compete strongly with glycine for transport when system B0,+ replaces system Gly in conceptuses, this qualitative change in transport activity may help account for a further decrease in the glycine content of conceptuses, reported elsewhere to occur after they form blastocysts.     

The Relation between Membrane Potential and the Transport Activity of Systems a and L in Plasma Membrane Vesicles of the Ehrlich Cell

Plasma membrane vesicles isolated from Ehrlich ascites tumor cells have been used to investigate the role of the transmembrane potential in the energetics of Systems A and L. As expected, Na⁺-dependent System A was responsive to changes in membrane potential. System L activity, as measured by transport of 2-aminonorbornane-2-carboxylic acid (BCH), was shown to be Na⁺-independent and was not altered by changes in the membrane potential. The combination of valinomycin and nigericin decreased accumulation of MeAIB but not that of BCH. The presence of nigericin alone caused a significant decrease in uptake by System A and a decrease in uptake by System L to a lesser degree. The inhibitory action of nigericin might reflect its ability to dissipate the Na⁺ gradient rather than an effect on K⁺ or H⁺ flows. The results indicate that modes of energization not produced through the transmembrane potential must account for any uphill operation of System L.     

Sodium-coupled electrogenic transport of pyroglutamate (5-oxoproline) via SLC5A8, a monocarboxylate transporter

Pyroglutamate, also known as 5-oxoproline, is a structural analog of proline. This amino acid derivative is a byproduct of glutathione metabolism, and is reabsorbed efficiently in kidney by Na⁺-coupled transport mechanisms. Previous studies have focused on potential participation of amino acid transport systems in renal reabsorption of this compound. Here we show that it is not the amino acid transport systems but instead the Na⁺-coupled monocarboxylate transporter SLC5A8 that plays a predominant role in this reabsorptive process. Expression of cloned human and mouse SLC5A8 in mammalian cells induces Na⁺-dependent transport of pyroglutamate that is inhibitable by various SLC5A8 substrates. SLC5A8-mediated transport of pyroglutamate is saturable with a Michaelis constant of 0.36 ± 0.04 mM. Na⁺-activation of the transport process exhibits sigmoidal kinetics with a Hill coefficient of 1.8 ± 0.4, indicating involvement of more than one Na⁺ in the activation process. Expression of SLC5A8 in Xenopuslaevis oocytes induces Na⁺-dependent inward currents in the presence of pyroglutamate under voltage-clamp conditions. The concentration of pyroglutamate necessary for induction of half-maximal current is 0.19 ± 0.01 mM. The Na⁺-activation kinetics is sigmoidal with a Hill coefficient of 2.3 ± 0.2. Ibuprofen, a blocker of SLC5A8, suppressed pyroglutamate-induced currents in SLC5A8-expressing oocytes; the concentration of the blocker necessary for causing half-maximal inhibition is 14 ± 1 μM. The involvement of SLC5A8 can be demonstrated in rabbit renal brush border membrane vesicles by showing that the Na⁺-dependent uptake of pyroglutamate in these vesicles is inhibitable by known substrates of SLC5A8. The Na⁺ gradient-driven pyroglutamate uptake was stimulated by an inside-negative K⁺ diffusion potential induced by valinomycin, showing that the uptake process is electrogenic.     

Valine uptake by the scleractinian coral Galaxea fascicularis: characterization and effect of light and nutritional status

The characteristics of valine uptake by isolated microcolonies of Galaxea fascicularis (Linnaeus 1758) were studied under various conditions including light, dark and feeding. The results demonstrated the presence of: (1) a linear component which might represent either a diffusional transport or a low-affinity carrier-mediated transport (apparent carrier affinity >250 mol·l^–1), and (2) a high-affinity active carrier-mediated transport (apparent carrier affinity about 5 mol·l^-1). The latter is mediated by two different systems: (i) a Na⁺-dependent carrier, stimulated by light and operative in both fed and unfed polyps, and (ii) a Na⁺-independent carrier, light insensitive and present only in unfed polyps. Competition experiments with other amino acids show that the Na⁺-dependent carrier is highly specific for neutral amino acids, as indicated by the high inhibition constants of basic and acidic amino acids. Our results suggest that the energy supplied by zooxanthellae photosynthates is necessary for the process of amino acid uptake, and that the Na⁺-dependent carrier responsible for valine uptake by G. fascicularis is similar to the B^0,+ system.Abbreviations AA amino acid(s) - AC/HC ratio autotrophic/heterotrophic carbon - ASW artificial sea water - DOM dissolved organic material - HPLC high performance liquid chromatography - K ₁ apparent inhibition constant - K _m apparent affinity of the carrier - SE standard error - V _max maximal rate of absorption     

Electrogenic transport of 5-oxoproline in rabbit renal brush-border membrane vesicles Effect of intravesicular potassium

The Na⁺-dependent transport of 5-oxoproline into rabbit renal brush-border vesicles was stimulated by a K⁺ diffusion potential (interior-negative) induced by valinomycin. Na⁺ salts of two anions of different epithelial permeabilities also affected 5-oxoproline transport. These results show that the Na⁺-dependent 5-oxoproline transport in renal brush-border vesicles is an electrogenic process which results in a net transfer of positive charge. Maximum transport of 5-oxoproline occurred at an extravesicular pH of 6.0 to 8.0 and over that pH range, 5-oxoproline exists completely as an anion with a negative charge. The simplest stoichiometry consistent with this process is, therefore, the cotransport of one 5-oxoproline anion with two sodium ions. The presence of K⁺ inside the vesicles stimulated the Na⁺-dependent transport of 5-oxoproline. This stimulatory effect was specific for K⁺ and required the presence of Na⁺. The presence of Na⁺ gradient was not mandatory for the K⁺ action. The stimulation by the intravesicular K⁺ was seen in the presence as well as in the absence of a K⁺ gradient. Therefore, the increased influx of 5-oxoproline was not coupled to the simultaneous efflux of K⁺. The presence of K⁺ in the extravesicular medium alone did not affect the Na⁺-dependent transport of 5-oxoproline, showing that the site of K⁺ action was intravesicular. Glutamate did not interact with the Na⁺-dependent 5-oxoproline transport even in the presence of an outward K⁺ gradient.     

The effects of potassium and membrane potential on sodium-dependent glutamic acid uptake

The uptake of l-glutamic acid into brush-border membrane vesicles isolated from rat renal proximal tubules is Na⁺-dependent. In contrast to Na⁺-dependent uptake of d-glucose, pre-equilibration of the vesicles with K⁺ stimulates l-glutamic acid uptake. Imposition of a K⁺ gradient ($\text{[}\text{K}{}_{\mathrm{i}}{}^{\mathrm{+}}\text{] > [}\text{K}{}_{\mathrm{o}}{}^{\mathrm{+}}\text{]}$) further enhances Na⁺-dependent l-glutamic acid uptake, but leaves K⁺-dependent glucose transport unchanged. If K⁺ is present only at the outside of the vesicles, transport is inhibited. Intravesicular Rb⁺ and, to a lesser extent, Cs⁺ can replace intravesicular K⁺ to stimulate l-glutamic acid uptake. Changes in membrane potential incurred by the imposition of an H⁺-diffusion potential or anion replacement markedly affect Na⁺-dependent glutamic acid uptake only in the presence of K⁺. Experiments with a potential-sensitive cyanine dye also indicate that, in the presence of intravesicular K⁺ a charge movement is involved in Na⁺-dependent transport of l-glutamic acid.The data indicate that Na⁺-dependent l-glutamic acid transport can be additionally energized by a K⁺ gradient. Furthermore, intravesicular K⁺ renders Na⁺-dependent l-glutamic acid transport sensitive to changes in the transmembrane electrical potential difference.