Kinetic analysis of L-glutamine transport into porcine jejunal enterocyte brush-border membrane vesicles

L-Glutamine transport into porcine jejunal enterocyte brush border membrane vesicles was studied. Uptake was mediated by a Na(+)-dependent and a Na(+)-independent pathway as well as by diffusion. The initial rates of glutamine uptake over a range of concentrations is both Na(+)-gradient and Na(+)-free conditions were analyzed and kinetic parameters were obtained. Na(+)-dependent glutamine transport had a K(m) of 0.77 +/- 0.16 mM and a Jmax of 70.7 +/- 5.8 pmol mg protein-1 s-1; Na(+)-independent glutamine transport had a K(m) of 3.55 +/- 0.78 mM and a Jmax of 55.1 +/- 6.6 pmol mg protein-1 s-1. The non-saturable component measured with HgCl2-poisoned brush border membrane vesicles in the Na(+)-free condition contained passive diffusion and non-specific membrane binding and was defined to be apparent glutamine diffusion and the glutamine permeability coefficient (Kdiff) was estimated to be Kdiff = 3.78 +/- 0.06 pmol 1 mg protein-1 mmol-1 s-1. Results of inhibition experiments showed that Na(+)-dependent glutamine uptake occurred primarily through the brush border system-B degree transporters, whereas Na(+)-independent glutamine uptake occurred via the system-L transporters. Furthermore, the kinetics of L-leucine and L-cysteine inhibition of L-glutamine uptake demonstrated that neutral amino acids sharing the same brush border transporters can effectively inhibit each other in their transport.     

Dicarboxylate transport in renal basolateral and brush-border membrane vesicles.

Characteristics of succinate transport were determined in basolateral and brush-border membrane vesicles (BLMV and BBMV, respectively) isolated in parallel from rabbit renal cortex. The uptake of succinate was markedly stimulated by the imposition of an inwardly directed Na+ gradient, showing an "overshoot" phenomenon in both membrane preparations. The stimulation of succinate uptake by an inwardly directed Na+ gradient was not significantly affected by pH clamp or inhibition of Na(+)-H+ exchange. The Na(+)-dependent and -independent succinate uptakes were not stimulated by an outwardly directed pH gradient. The Na dependence of succinate uptake exhibited sigmoidal kinetics, with Hill coefficients of 2.17 and 2.38 in BLMV and BBMV, respectively. The Na(+)-dependent succinate uptake by BLMV and BBMV was stimulated by a valinomycin-induced inside-negative potential. The Na(+)-dependent succinate uptake by BLMV and BBMV followed a simple Michaelis-Menten kinetics, with an apparent Km of 22.20 +/- 4.08 and 71.52 +/- 0.14 microM and a Vmax of 39.0 +/- 3.72 and 70.20 +/- 0.96 nmol/(mg.min), respectively. The substrate specificity and the inhibitor sensitivity of the succinate transport system appeared to be very similar in both membranes. These results indicate that both the renal brush-border and basolateral membranes possess the Na(+)-dependent dicarboxylate transport system with very similar properties but with different substrate affinity and transport capacity.     

Heterogeneity of transport systems for L-glutamine in mouse mammary gland

The characteristics of the transport systems of L-glutamine in lactating mouse mammary gland have been studied. L-glutamine uptake was mediated by three Na+-dependent and one Na+-independent systems. The 2-(methylamino)isobutyric acid-sensitive component of Na+-dependent uptake exhibited the usual characteristics of system A. The other two Na+-dependent systems, which we have named BCI(-)-dependent and BCl(-)-independent, are the new systems identified. These are broad specificity systems and were discriminated on the basis of inhibition analysis, Cl- dependency and the effect of preloading mammary tissue with amino acids. While L-aspargine inhibited the uptake of L-glutamine via both these broad specificity systems, L-homoserine inhibited the uptake of L-glutamine via only BCl(-)-dependent system. The uptake of L-glutamine via the BCl(-)-independent system was upregulated by preloading mammary tissue with L-serine, while BCl(-)-dependent system was unaffected. The Na+-independent uptake of L-glutamine was inhibited by 2-aminobicyclo-(2,2,1)heptane carboxylic acid and other neutral amino acids, and identified as the system L.     

Characterization of D-Aspartic Acid Uptake by Rat Hippocampal Slices and Effect of Ischemic Conditions

The cellular uptake of D-aspartic acid (D-Asp) as a model compound for glutamic acid transport was studied in rat hippocampal slices. D-Asp is accumulated by both Na(+)-dependent and Na(+)-independent processes in hippocampal slices, and both processes are dependent on temperature. The Na(+)-dependent uptake is assumed to be high in affinity (apparent Km = 0.17 mM), but low in capacity, whereas the Na(+)-independent uptake is much lower in affinity (Km = 2.86 mM), but higher in capacity. L-Aspartic acid, L-glutamic acid, dihydrokainic acid, and threo-3-hydroxy-DL-aspartic acid markedly inhibited the uptake of D-Asp with Na+ in the medium, whereas D-glutamic acid, glycine, and L-lysine had no significant effect. The Na(+)-dependent uptake of D-Asp was significantly reduced under "hypoglycemic," "anoxic," and "ischemic" conditions, whereas the Na(+)-independent uptake was unaffected. Metabolic inhibitors such as NaCN and ICH2COOH significantly inhibited the Na(+)-dependent uptake, but not the Na(+)-independent uptake. These results suggest that the Na(+)-dependent component of D-Asp transport in rat hippocampal cells is inactivated under ischemic conditions, whereas the Na(+)-independent component is unaffected.     

Expression of renal transport systems for inorganic phosphate and sulfate in Xenopus laevis oocytes.

As a first step within an experimental strategy (expression cloning) leading to the structural identification of the two brush-border membrane transport systems for phosphate and sulfate, we have studied the expression of Na(+)-dependent uptake of phosphate and sulfate in Xenopus laevis oocytes injected with rabbit kidney cortex poly(A)+ RNA (mRNA). Na(+)-dependent uptake of phosphate and sulfate was stimulated in a dose- and time-dependent manner up to 20-fold as compared to water-injected controls. After fractionation of the mRNA on a sucrose gradient (or by preparative gel electrophoresis), two neighboring fractions were identified to stimulate Na(+)-dependent phosphate uptake (average size: 3.4 kilobases) and Na(+)-dependent sulfate uptake (average size: 3.7 kilobases). The two transport systems can be discriminated by their inhibition by thiosulfate, which reduced sulfate uptake, but not phosphate uptake. Kinetic characterization of the expressed Na(+)-dependent transport activities results in properties similar to those described for transport activity in renal brush-border membrane vesicles.     

Nucleoside transport in L1210 murine leukemia cells. Evidence for three transporters

L1210 murine leukemia cells have two nucleoside transport activities that differ in their sensitivity to nitrobenzylmercaptopurine riboside (NBMPR). This study re-examines NBMPR-insensitive nucleoside transport in these cells and finds that it is mediated by two components, one Na(+)-dependent and the other Na(+)-independent. A mutant selected previously for loss of NBMPR-insensitive transport lacks only the Na(+)-independent activity. When NBMPR is used to block efflux via the NBMPR-sensitive transporter, uptake of formycin B (a nonmetabolized analog of inosine) is concentrative in both the parental and mutant cells, but the intracellular concentration of the nucleoside is 5-fold lower in the parental cells. Decreased accumulation of formycin B in the parental cells is due to efflux of the nucleoside via the NBMPR-insensitive, Na(+)-independent transporter that the mutant lacks. The Na(+)-dependent transporter appears to accept most purine, but not pyrimidine, nucleosides as substrates. Two exceptions are uridine, a good substrate, and 7-deazaadenosine, a poor substrate. In contrast, all of the nucleosides tested are substrates for the Na(+)-independent transporter. We conclude that L1210 cells have three distinct nucleoside transporters and that the specificity of the Na(+)-dependent transporter is similar to that of one of the two Na(+)-dependent nucleoside transporters seen in mouse intestinal epithelial cells.     

L-Carnitine transport in mouse renal and intestinal brush-border and basolateral membrane vesicles.

We characterized the uptake of carnitine in brush-border membrane (BBM) and basolateral membrane (BLM) vesicles, isolated from mouse kidney and intestine. In kidney, carnitine uptake was Na(+)-dependent, showed a definite overshoot and was saturable for both membranes, but for intestine, it was Na(+)-dependent only in BLM. The uptake was temperature-dependent in BLM of both kidney and intestine. The BBM transporter in kidney had a high affinity for carnitine: apparent K(m)=18.7 microM; V(max)=7.85 pmol/mg protein/s. In kidney BLM, similar characteristics were obtained: apparent K(m)=11.5 microM and V(max)=3.76 pmol/mg protein/s. The carnitine uptake by both membranes was not affected within the physiological pH 6.5-8.5. Tetraethylammonium, verapamil, valproate and pyrilamine significantly inhibited the carnitine uptake by BBM but not by BLM. By Western blot analysis, the OCTN2 (a Na(+)-dependent high-affinity carnitine transporter) was localized in the kidney BBM, and not in BLM. Strong OCTN2 expression was observed in kidney and skeletal muscle, with no expression in intestine in accordance with our functional study. We conclude that different polarized carnitine transporters exist in kidney BBM and BLM. L-Carnitine uptake by mouse renal BBM vesicles involves a carrier-mediated system that is Na(+)-dependent and is inhibited significantly by specific drugs. The BBM transporter is likely to be OCTN2 as indicated by a strong reactivity with the anti-OCTN2 polyclonal antibody.     

Distinct transport activity of tetraethylammonium from L-carnitine in rat renal brush-border membranes

We investigated the contribution of the Na(+)/L-carnitine cotransporter in the transport of tetraethylammonium (TEA) by rat renal brush-border membrane vesicles. The transient uphill transport of L-carnitine was observed in the presence of a Na(+) gradient. The uptake of L-carnitine was of high affinity (K(m)=21 microM) and pH dependent. Various compounds such as TEA, cephaloridine, and p-chloromercuribenzene sulfonate (PCMBS) had potent inhibitory effects for L-carnitine uptake. Therefore, we confirmed the Na(+)/L-carnitine cotransport activity in rat renal brush-border membranes. Levofloxacin and PCMBS showed different inhibitory effects for TEA and L-carnitine uptake. The presence of an outward H(+) gradient induced a marked stimulation of TEA uptake, whereas it induced no stimulation of L-carnitine uptake. Furthermore, unlabeled TEA preloaded in the vesicles markedly enhanced [14C]TEA uptake, but unlabeled L-carnitine did not stimulate [14C]TEA uptake. These results suggest that transport of TEA across brush-border membranes is independent of the Na(+)/L-carnitine cotransport activity, and organic cation secretion across brush-border membranes is predominantly mediated by the H(+)/organic cation antiporter.     

Glutamine uptake and metabolism to N-acetylaspartylglutamate (NAAG) by crayfish axons and glia

We have proposed that N-acetylaspartylglutamate (NAAG) or its hydrolytic product glutamate, is a chemical signaling agent between axons and periaxonal glia at non-synaptic sites in crayfish nerves, and that glutamine is a probable precursor for replenishing the releasable pool of NAAG. We report here, that crayfish central nerve fibers synthesize NAAG from exogenous glutamine. Cellular accumulation of radiolabel during in vitro incubation of desheathed cephalothoracic nerve bundles with [3H]glutamine was 74% Na(+)-independent. The Na(+)-independent transport was temperature-sensitive, linear with time for at least 4 h, saturable between 2.5 and 10 mM L-glutamine, and blocked by neutral amino acids and analogs that inhibit mammalian glutamine transport. Radiolabeled glutamine was taken up and metabolized by both axons and glia to glutamate and NAAG, and a significant fraction of these products effluxed from the cells. Both the metabolism and release of radiolabeled glutamine was influenced by extracellular Na(+). The uptake and conversion of glutamine to glutamate and NAAG by axons provides a possible mechanism for recycling and formation of the axon-to-glia signaling agent(s).     

Expression of rat liver glutamine transporters in Xenopus laevis oocytes.

As a first step in attempting to isolate the Na(+)-dependent System N transporter from rat liver we have investigated the use of prophase-arrested oocytes from Xenopus laevis for the functional expression of rat liver glutamine transporters. Individual oocytes, defolliculated by collagenase treatment, were injected with 50 nl of a 1 mg.ml-1 solution of poly(A)+ RNA (mRNA) isolated from rat liver. 50 microM L-[3H]glutamine uptake was measured 1-5 days post-injection: after 48 h, poly(A)+ RNA-injected oocytes showed a 60 +/- 12% increase in Na(+)-dependent glutamine uptake compared to controls. This increased uptake showed characteristic features of hepatic System N: that is, it tolerated Li(+)-for-Na+ substitution and was inhibited by the System N substrate L-histidine (5 mM) in Li medium, unlike endogenous Na(+)-dependent glutamine transport. In subsequent experiments rat liver poly(A)+ RNA, size-fractionated by density gradient fractionation, was injected into oocytes. Injection of poly(A)+ RNA of 1.9-2.8 kilobases (kb) in size resulted in a significant stimulation of Na(+)-dependent glutamine transport to 0.362 +/- 0.080 pmol.min-1/oocyte from 0.178 +/- 0.060 pmol.min-1/oocyte in vehicle-injected oocytes (p less than 0.01). A lighter fraction, with poly(A)+ RNA of less than 1.9 kilobases size resulted in a similar increase in Na(+)-dependent glutamine uptake which was largely Li(+)-tolerant: Li(+)-stimulated glutamine uptake in oocytes injected with this fraction increased to 0.230 +/- 0.070 pmol.min-1/oocyte from 0.098 +/- 0.029 pmol.min-1/oocyte in controls (p less than 0.05). This enhanced rate of Li(+)-stimulated glutamine uptake was inhibited 28 and 70%, respectively, by 1 and 5 mM L-histidine. Na(+)-independent uptake of glutamine rose by 72 +/- 12% in oocytes injected with poly(A)+ RNA of 2.8-3.6 kb (p less than 0.001). These results demonstrate that glutamine transporters, with characteristics associated with hepatic Systems N, L, and A (or ASC), can be expressed in X. laevis oocytes injected with specific size fractions of rat liver mRNA.     

Renal transport of taurine in luminal membrane vesicles from rabbit proximal tubule

The uptake of taurine by luminal membrane vesicles from pars convoluta and pars recta of rabbit proximal tubule was examined. In pars convoluta, the transport of taurine was characterized by two Na(+)-dependent (Km1 = 0.086 mM, Km2 = 5.41 mM) systems, and one Na(+)-independent (Km = 2.87 mM) system, which in the presence of an inwardly directed H(+)-gradient was able to drive the transport of taurine into these vesicles. By contrast, in luminal membrane vesicles from pars recta, the transport of taurine occurred via a dual transport system (Km1 = 0.012 mM, Km2 = 5.62 mM), which was strictly dependent on Na+. At acidic pH with or without a H(+)-gradient, the Na(+)-dependent flux of taurine was drastically reduced. In both kind of vesicles, competition experiments only showed inhibition of the Na(+)-dependent high-affinity taurine transporter in the presence of beta-alanine, whereas there was no significant inhibition with alpha-amino acids, indicating a beta-amino acid specific transport system. Addition of beta-alanine, L-alanine, L-proline and glycine, but not L-serine reduced the H(+)-dependent uptake of taurine to approx. 50%. Moreover, only the Na(+)-dependent high-affinity transport systems in both segments specifically required Cl-. Investigation of the stoichiometry indicated 1.8 Na+: 1 Cl-: 1 taurine (high affinity), 1 Na+: 1 taurine (low affinity) and 1 H+: 1 taurine in pars convoluta. In pars recta, the data showed 1.8 Na+: 1 Cl-: 1 taurine (high affinity) and 1 Na+: 1 taurine (low affinity).     

1,25-Dihydroxycholecalciferol-related Na+/D-glucose transport in brush-border membrane vesicles from embryonic chick jejunum. Modulation by triiodothyronine

1,25-Dihydroxycholecalciferol, when present at and above 10 nM in an organ-culture system of embryonic chick jejunum, approximately doubled the rate of Na(+)-gradient-driven D-glucose uptake by brush-border membrane vesicles, but had no effect on Na(+)-independent D-glucose transfer. The sterol also had no effect on Na+ influx along an outside/inside Na+ gradient ([Na+]o = 100 mM; [Na+]i = 0 mM). This renders it unlikely that in embryonic intestine, calcitriol raises Na(+)-dependent D-glucose transport through changes in the electrochemical Na+ gradient. D-[U-14C]Glucose tracer exchange, measured under voltage-clamp condition at Na+/D-glucose equilibrium, revealed that addition of calcitriol to the culture medium approximately doubled the activity of the Na+/D-glucose transporter in the brush-border membrane. This was also reflected by an corresponding increase in the maximal velocity of the transfer process. Increased [3H]phlorizin binding after calcitriol treatment suggests that the steroid hormone activates Na+/D-glucose transport through increasing the number of carrier molecules in the brush-border membrane. 10 nM triiodothyronine, which by itself has no effect on Na(+)-dependent D-glucose transport, potentiated the effect of 1,25-dihydroxycholecalciferol such that in the presence of both hormones, Na+/D-glucose-carrier activity was increased fourfold above control levels.     

Effects of L-glutamate/D-aspartate and monensin on lactic acid production in retina and cultured retinal Müller cells

We have investigated the dependence of the rate of lactic acid production on the rate of Na(+) entry in cultured transformed rat Müller cells and in normal and dystrophic (RCS) rat retinas that lack photoreceptors. To modulate the rate of Na(+) entry, two approaches were employed: (i) the addition of L-glutamate (D-aspartate) to stimulate coupled uptake of Na(+) and the amino acid; and (ii) the addition of monensin to enhance Na(+) exchange. Müller cells produced lactate aerobically and anaerobically at high rates. Incubation of the cells for 2-4 h with 0.1-1 mM L-glutamate or D-aspartate did not alter the rate of production of lactate. ATP content in the cells at the end of the incubation period was unchanged by addition of L-glutamate or D-aspartate to the incubation media. Na(+)-dependent L-glutamate uptake was observed in the Müller cells, but the rate of uptake was very low relative to the rate of lactic acid production. Ouabain (1 mM) decreased the rate of lactic acid production by 30-35% in Müller cells, indicating that energy demand is enhanced by the activity of the Na(+)-K(+) pump or depressed by its inhibition. Incubation of Müller cells with 0.01 mM monensin, a Na(+) ionophore, caused a twofold increase in aerobic lactic acid production, but monensin did not alter the rate of anaerobic lactic acid production. Aerobic ATP content in cells incubated with monensin was not different from that found in control cells, but anaerobic ATP content decreased by 40%. These results show that Na(+)-dependent L-glutamate/D-aspartate uptake by cultured retinal Müller cells causes negligible changes in lactic acid production, apparently because the rates of uptake are low relative to the basal rates of lactic acid production. In contrast, the marked stimulation of aerobic lactic acid production caused by monensin opening Na(+) channels shows that glycolysis is an effective source of ATP production for the Na(+)-K(+) ATPase. A previous report suggests that coupled Na(+)-L-glutamate transport stimulates glycolysis in freshly dissociated salamander Müller cells by activation of glutamine synthetase. The Müller cell line used in this study does not express glutamine synthetase; consequently these cells could only be used to examine the linkage between Na(+) entry and the Na(+) pump. As normal and RCS retinas express glutamine synthetase, the role of this enzyme was examined by coapplication of L-glutamate and NH(4) (+) in the presence and absence of methionine sulfoximine, an inhibitor of glutamine synthetase. In normal retinas, neither the addition of L-glutamate alone or together with NH(4) (+) caused a significant change in the glycolytic rate, an effect linked to the low rate of uptake of this amino acid relative to the basal rate of retinal glycolysis. However, incubation of the RCS retinas in media containing L-glutamate and NH(4)(+) did produce a small (15%) increase in the rate of glycolysis above the rate found with L-glutamate alone and controls. It is unlikely that this increase was the result of conversion of L-glutamate to L-glutamine, as it was not suppressed by inhibition of glutamine synthetase with 5 mm methionine sulfoximine. It appears that the magnitude of Müller cell glycolysis required to sustain the coupled transport of Na(+) and L-glutamate and synthesis of L-glutamine is small relative to the basal glycolytic activity in a rat retina.     

D-mannose transport and metabolism in isolated enterocytes

D-mannose transport and metabolism has been studied in enterocytes isolated from chicken small intestine. In the presence of Na(+), the mannose taken up by the cells either remains free, is phosphorylated, is catabolized to H(2)O, or becomes part of membrane components. The mannose remaining free in the cytosol is released when the cells are transferred to an ice bath. The Na(+)-dependent D-mannose transport is electrogenic and inhibited by ouabain and dinitrophenol; its substrate specificity differs from SGLT-1 transporter. The Glut2 transporter inhibitors phloretin and cytochalasin B added following 30-min mannose uptake reduced the previously accumulated D-mannose, whereas these two agents increased the cell to external medium 3-O-methyl-glucose (3-OMG) concentration ratio. D-mannose efflux rate from preloaded D-[2-(3)H]-mannose enterocytes is Na(+)-independent. Phloretin did not affect D-mannose efflux rate, whereas it inhibited that of 3-OMG. Neither mannose uptake nor efflux rate were affected by fructose. It is concluded that part of the mannose taken up by the enterocytes is rapidly metabolized and that enterocytes have two D- mannose transport systems: one is concentrative and Na(+)-dependent and the other is Na(+)-independent and passive.     

Nucleoside transport in human colonic epithelial cell lines: evidence for two Na+-independent transport systems in T84 and Caco-2 cells.

RT-PCR of RNA isolated from monolayers of the human colonic epithelial cell lines T84 and Caco-2 demonstrated the presence of mRNA for the two cloned Na+-independent equilibrative nucleoside transporters, ENT1 and ENT2, but not for the cloned Na+-dependent concentrative nucleoside transporters, CNT1 and CNT2. Uptake of [3H]uridine by cell monolayers in balanced Na+-containing and Na+-free media confirmed the presence of only Na+-independent nucleoside transport mechanisms. This uptake was decreased by 70-75% in the presence of 1 microM nitrobenzylthioinosine, a concentration that completely inhibits ENT1, and was completely blocked by the addition of 10 microM dipyridamole, a concentration that inhibits both ENT1 and ENT2. These findings indicate the presence in T84 and Caco-2 cells of two functional Na+-independent equilibrative nucleoside transporters, ENT1 and ENT2.     

Nucleoside transport in cultured LLC-PK1 epithelia.

The transport of nucleosides by LLC-PK1 cells, a continuous epithelial cell line derived from pig kidney, was characterised. Uridine influx was saturable (apparent Km approximately 34 microM at 22 degrees C) and inhibited by greater than 95% by nitrobenzylthioinosine (NBMPR), dilazep and a variety of purine and pyrimidine nucleosides. In contrast to other cultured animal cells, the NBMPR-sensitive nucleoside transporter in LLC-PK1 cells exhibited both a high affinity for cytidine (apparent Ki approximately 65 microM for influx) and differential 'mobility' of the carrier (the kinetic parameters of equilibrium exchange of formycin B are greater than those for formycin B influx). An additional minor component of sodium-dependent uridine influx in LLC-PK1 cells became detectable when the NBMPR-sensitive nucleoside transporter was blocked by the presence of 10 microM NBMPR. This active transport system was inhibited by adenosine, inosine and guanosine but thymidine and cytidine were without effect, inhibition properties identical to the N1 sodium-dependent nucleoside carrier in bovine renal outer cortical brush-border membrane vesicles (Williams and Jarvis (1991) Biochem. J. 274, 27-33). Late proximal tubule brush-border membrane vesicles of porcine kidney were shown to have a much reduced Na(+)-dependent uridine uptake activity compared to early proximal tubule porcine brush-border membrane vesicles. These results, together with the recent suggestion of the late proximal tubular origin of LLC-PK1 cells, suggest that in vivo nucleoside transport across the late proximal tubule cell may proceed mainly via a facilitated-diffusion process.     

Na<Superscript>+</Superscript> gradient-dependent transport of hypoxanthine by calf intestinal brush border membrane vesicles

The properties of hypoxanthine transport were investigated in purified brush border membrane vesicles isolated from calf proximal and distal jejunum. Hypoxanthine uptake in the vesicles was stimulated by a transmembrane Na(+) gradient and an inside negative potential resulting in a transient accumulation of intravesicular hypoxanthine, especially in the proximal jejunum. Na(+)-dependent hypoxanthine uptake at this site seemed to occur by two saturable transport systems, a high affinity (K(m)=0.33 micromol/l) and a low affinity (K(m)=165 micromol/l) transporter. Guanine, hypoxanthine, thymine and uracil inhibited intravesicular hypoxanthine uptake, whereas adenine and the nucleosides inosine and thymidine were without effect. These findings represent the first demonstration of active Na(+) gradient-dependent nucleobase transport in intestinal brush border membrane vesicles.     

Functional regulation of Na+-dependent neutral amino acid transporter ASCT2 by S-nitrosothiols and nitric oxide in Caco-2 cells

We describe the regulation mechanisms of the Na(+)-dependent neutral amino acid transporter ASCT2 via nitric oxide (NO) in the human intestinal cell line, Caco-2. Exposure of Caco-2 cells to S-nitrosothiol, such as S-nitroso-N-acetyl-DL-penicillamine (SNAP) and S-nitrosoglutathione, and the NO-donor, NOC12, concentration- and time-dependently increased Na(+)-dependent alanine uptake. Kinetic analyses indicated that SNAP increases the maximal velocity (V(max)) of Na(+)-dependent alanine uptake in Caco-2 cells without affecting the Michaelis-Menten constant (K(t)). The stimulatory effect was partially eliminated by actinomycin D and cycloheximide. Increased Na(+)-dependent alanine uptake by SNAP was partially abolished by the NO scavengers, 2-(4-carboxyphenyl)-4,4,5,5-tetramethylimidazoline-1-oxyl 3-oxide sodium salt (carboxy-PTIO) and N-(dithiocarboxy)sarcosine disodium salts (DTCS), as well as the NADPH oxidase inhibitor, diphenyleneiodonium. RT-PCR revealed that Caco-2 cells expressed the Na(+)-dependent neutral amino acid transporter ASCT2, but not the other Na(+)-dependent neutral amino acid transporters ATB(0,+) and B(0)AT1. These results suggested that functional up-regulation of ASCT2 by SNAP might be partially associated with an increase in the density of transporter protein via de novo synthesis.     

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.     

Amino acid transport systems in the human hepatoma cell line Hep G2.

The human hepatoma cell line Hep G2 was used to investigate amino acid transport systems in human liver tissue. The ubiquitous transport systems responsible for the uptake of most neutral amino acids (systems A, ASC and L) were found to be present. Transport system A was predominant for proline uptake but system ASC was the major Na(+)-dependent transport system, particularly for glutamine. The specific hepatic system N was functional, but only partially mediated glutamine uptake. The study of Na(+)-independent arginine uptake demonstrated the presence of the cationic transport system Y+, reflecting the transformed nature of Hep G2 cells.